Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.
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Lot | NR-010 |
---|---|
Concentration | 1.0 µg/µl |
Species reactivity | Human, rat |
Type | Monoclonal |
Purity | Ammonium sulphate purified |
Host | Mouse |
Precautions | This product is for research use only. Not for use in diagnostic or therapeutic procedures. |
Applications | Suggested dilution | References |
---|---|---|
ChIP/ChIP-seq | 5 μg/ChIP | Fig 1, 2 |
ELISA | 0.5 μg/ml | Fig 3 |
Western Blotting | 1 μg/ml | Fig 4 |
Gel Supershift | 5 μg/ml | |
Immunochemistry | 2.5 μg/ml | Fig 5, 6 |
Flow cytometry | 0.5 μg/ml | |
Immunoprecipitation | 5 μg/IP | Fig 7 |
Figure 1. ChIP results obtained with the Diagenode monoclonal antibody directed against hGR
ChIP assays were performed using HeLa cells, the Diagenode monoclonal antibody directed against GR (Cat. No. MAb-010-050) and optimized PCR primer sets for qPCR. The cells were treated either with ethanol (EtOH, used as a negative control) or triamcinolone acetonide (TA) for 4 hours prior to cell harvesting. ChIP was performed using sheared chromatin from 3 million cells and 5 μg of antibody. QPCR was performed with primers for the human metallothionein promoter (hMTIIA) and for exon 2 of the human myoglobin gene (hmyo ex2), used as a negative control. Figure 1 shows the recovery (the relative amount of immunoprecipitated DNA compared to input DNA) and the occupancy (ratio +/- control target). These results demonstrate the occupancy of the human metallothionein IIA promoter by GR.
Figure 2. ChIP-seq results obtained with the Diagenode monoclonal antibody directed against hGR
ChIP was performed on sheared chromatin from 3.5 million HeLaB2 cells using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). The cells were treated with the synthetic GR ligand triamcinolone acetonide (TA) for 4 hours prior to harvesting. The IP’d DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer’s instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. Figure 2 shows the peak distribution along the complete sequence of chromosome 16 (figure 2A) as well as the MT2A positive control gene (figure 2B). The position of the PCR amplicon is also indicated. Figure 2C, D and E show the results for the known GR target genes PER1 on chromosome 17 and FKBP5 and TNFAIP3 on chromosome 6.
Figure 3. Sandwich ELISA
The specificity of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050) was assessed by sandwich ELISA. Figure 3A: schematic representation of the sandwich ELISA with the monoclonal antibody against hGR (clone #:m2F8). Figure 3B: ELISA results using the monoclonal antibody against hGR at a concentration of 0.5 μg/ml. The figure shows an ELISA signal which is proportionally increasing with increasing amounts of recombinant hGR.
Figure 4. Western blot analysis using the Diagenode monoclonal antibody against hGR
Figure 4A. Extracts from HeLa cells containing the indicated amounts of GR (from 30 to 240 fmol), and from 5x10e6 Raji or Molt cells were analysed by Western blot using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). Figure 4B. Western blot analysis of extracts from 300,000 HeLa cells with the Diagenode monoclonal antibody against hGR (concentration 1 μg/ml).
Figure 5. Immunohistochemistry and immunofluorescence using the Diagenode monoclonal antibody against hGR
1. Immunoreactivity of the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050) in rat CA1 neurons of hippocampus. The antibody was used at a concentration of 2.5 μg/ml.
2. COS-7 cells transiently overexpressing human GR were labeled with the antibody against hGR followed by a biotinylated secondary antibody and peroxidase-labeled avidin. The antibody was used at a concentration of 2.5 μg/ml.
Figure 6. Immunoprecipitation using the Diagenode monoclonal antibody against hGR
The glucocorticoid receptor was immunoprecipitated from HeLa cell extracts (5 million HeLa cells in 100 μl IP reaction solution) using 5 μg of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050). The IP was followed by Western blot analysis as described above
Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.
ChIP-seq (ab) Read more |
ChIP-qPCR (ab) Read more |
ELISA Enzyme-linked immunosorbent assay. Read more |
WB Western blot : The quality of antibodies used in this technique is crucial for correct and specific protein identification. Diagenode offers huge selection of highly sensitive and specific western blot-validated antibodies. Learn more about: Load... Read more |
IP Immunoprecipitation Read more |
GSA Gel Supershift Read more |
Flow Cyt Flow cyt Read more |
Antibodies you can trust POSTER Epigenetic research tools have evolved over time from endpoint PCR to qPCR to the analyses of lar... | Download |
Epigenetic Antibodies Brochure BROCHURE More than in any other immuoprecipitation assays, quality antibodies are critical tools in many e... | Download |
Datasheet hGR C15200010 DATASHEET Datasheet description | Download |
How to properly cite this product in your workDiagenode strongly recommends using this: GR monoclonal antibody (sample size) (Diagenode Cat# C15200010-10 Lot# NR-010). Click here to copy to clipboard. Using our products in your publication? Let us know! |
Coordinated glucocorticoid receptor and MAFB action inducestolerogenesis and epigenome remodeling in dendritic cells |
The Role of S-Palmitoylation of the Human Glucocorticoid Receptor (hGR) in Mediating the Nongenomic Glucocorticoid Actions |
Three Novel Heterozygous Point Mutations of NR3C1 causing Glucocorticoid Resistance |
Functional characterization of the hGRαT556I causing Chrousos syndrome |
Perinatal exposure to low-dose bisphenol A affects the neuroendocrine stress response in rats. |
Pattern of heat shock factor and heat shock protein expression in lymphocytes of bipolar patients: Increased HSP70-glucocorticoid receptor heterocomplex. |
Coactivation of GR and NFKB alters the repertoire of their binding sites and target genes. |
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ChIP results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP assays were performed using HeLa cells, the Diagenode monoclonal antibody directed against GR (Cat. No. MAb-010-050) and optimized PCR primer sets for qPCR. The cells were treated either with ethanol (EtOH, used as a negative control) or triamcinolone acetonide (TA) for 4 hours prior to cell harvesting. ChIP was performed using sheared chromatin from 3 million cells and 5 μg of antibody. QPCR was performed with primers for the human metallothionein promoter (hMTIIA) and for exon 2 of the human myoglobin gene (hmyo ex2), used as a negative control. Figure 1 shows the recovery (the relative amount of immunoprecipitated DNA compared to input DNA) and the occupancy (ratio +/- control target). These results demonstrate the occupancy of the human metallothionein IIA promoter by GR. </small></p> </div> </div> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2A.png" alt="GR Antibody ChIP-seq Grade" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2B.png" alt="GR Antibody for ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2C.png" alt="GR Antibody for ChIP-seq assay" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2D.png" alt="GR Antibody validated in ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2E.png" alt="GR Antibody ChIP-seq Grade" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 2. ChIP-seq results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP was performed on sheared chromatin from 3.5 million HeLaB2 cells using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). The cells were treated with the synthetic GR ligand triamcinolone acetonide (TA) for 4 hours prior to harvesting. The IP’d DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer’s instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. Figure 2 shows the peak distribution along the complete sequence of chromosome 16 (figure 2A) as well as the MT2A positive control gene (figure 2B). The position of the PCR amplicon is also indicated. Figure 2C, D and E show the results for the known GR target genes PER1 on chromosome 17 and FKBP5 and TNFAIP3 on chromosome 6. </small></p> </div> </div> <p></p> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig3.png" alt="GR Antibody ELISA Validation" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 3. Sandwich ELISA </strong><br />The specificity of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050) was assessed by sandwich ELISA. Figure 3A: schematic representation of the sandwich ELISA with the monoclonal antibody against hGR (clone #:m2F8). Figure 3B: ELISA results using the monoclonal antibody against hGR at a concentration of 0.5 μg/ml. The figure shows an ELISA signal which is proportionally increasing with increasing amounts of recombinant hGR. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig4.png" alt="GR Antibody validated in Western Blot" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 4. Western blot analysis using the Diagenode monoclonal antibody against hGR </strong><br />Figure 4A. Extracts from HeLa cells containing the indicated amounts of GR (from 30 to 240 fmol), and from 5x10e6 Raji or Molt cells were analysed by Western blot using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). Figure 4B. Western blot analysis of extracts from 300,000 HeLa cells with the Diagenode monoclonal antibody against hGR (concentration 1 μg/ml). </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig5.png" alt="GR Antibody validated in Immunohistochemistry" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig6.png" alt="GR Antibody validated for Immunohistochemistry" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 5. Immunohistochemistry and immunofluorescence using the Diagenode monoclonal antibody against hGR </strong><br />1. Immunoreactivity of the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050) in rat CA1 neurons of hippocampus. The antibody was used at a concentration of 2.5 μg/ml. <br />2. COS-7 cells transiently overexpressing human GR were labeled with the antibody against hGR followed by a biotinylated secondary antibody and peroxidase-labeled avidin. The antibody was used at a concentration of 2.5 μg/ml. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig7.png" alt="GR Antibody validated in Immunoprecipitation" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 6. Immunoprecipitation using the Diagenode monoclonal antibody against hGR </strong><br />The glucocorticoid receptor was immunoprecipitated from HeLa cell extracts (5 million HeLa cells in 100 μl IP reaction solution) using 5 μg of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050). The IP was followed by Western blot analysis as described above </small></p> </div> </div>', 'label2' => 'Target Description', 'info2' => '<p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.</p>', 'label3' => '', 'info3' => '', 'format' => '10 µg', 'catalog_number' => 'C15200010-10', 'old_catalog_number' => '', 'sf_code' => 'C15200010-D001-000582', 'type' => 'FRE', 'search_order' => '', 'price_EUR' => '105', 'price_USD' => '115', 'price_GBP' => '100', 'price_JPY' => '16450', 'price_CNY' => '', 'price_AUD' => '288', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => false, 'last_datasheet_update' => '', 'slug' => 'gr-monoclonal-antibody-classic-10-ug', 'meta_title' => '', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2022-01-05 14:49:33', 'created' => '2017-05-17 14:56:35', 'locale' => 'jpn' ), 'Antibody' => array( 'host' => '*****', 'id' => '326', 'name' => 'GR monoclonal antibody', 'description' => 'Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.', 'clonality' => '', 'isotype' => '', 'lot' => 'NR-010', 'concentration' => '1.0 µg/µl', 'reactivity' => 'Human, rat', 'type' => 'Monoclonal', 'purity' => 'Ammonium sulphate purified', 'classification' => 'Classic', 'application_table' => '<table> <thead> <tr> <th>Applications</th> <th>Suggested dilution</th> <th>References</th> </tr> </thead> <tbody> <tr> <td>ChIP/ChIP-seq</td> <td>5 μg/ChIP</td> <td>Fig 1, 2</td> </tr> <tr> <td>ELISA</td> <td>0.5 μg/ml</td> <td>Fig 3</td> </tr> <tr> <td>Western Blotting</td> <td>1 μg/ml</td> <td>Fig 4</td> </tr> <tr> <td>Gel Supershift</td> <td>5 μg/ml</td> <td></td> </tr> <tr> <td>Immunochemistry</td> <td>2.5 μg/ml</td> <td>Fig 5, 6</td> </tr> <tr> <td>Flow cytometry</td> <td>0.5 μg/ml</td> <td></td> </tr> <tr> <td>Immunoprecipitation</td> <td>5 μg/IP</td> <td>Fig 7</td> </tr> </tbody> </table> <p></p>', 'storage_conditions' => '', 'storage_buffer' => '', 'precautions' => 'This product is for research use only. 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ChIP results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP assays were performed using HeLa cells, the Diagenode monoclonal antibody directed against GR (Cat. No. MAb-010-050) and optimized PCR primer sets for qPCR. The cells were treated either with ethanol (EtOH, used as a negative control) or triamcinolone acetonide (TA) for 4 hours prior to cell harvesting. ChIP was performed using sheared chromatin from 3 million cells and 5 μg of antibody. QPCR was performed with primers for the human metallothionein promoter (hMTIIA) and for exon 2 of the human myoglobin gene (hmyo ex2), used as a negative control. Figure 1 shows the recovery (the relative amount of immunoprecipitated DNA compared to input DNA) and the occupancy (ratio +/- control target). These results demonstrate the occupancy of the human metallothionein IIA promoter by GR. </small></p> </div> </div> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2A.png" alt="GR Antibody ChIP-seq Grade" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2B.png" alt="GR Antibody for ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2C.png" alt="GR Antibody for ChIP-seq assay" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2D.png" alt="GR Antibody validated in ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2E.png" alt="GR Antibody ChIP-seq Grade" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 2. ChIP-seq results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP was performed on sheared chromatin from 3.5 million HeLaB2 cells using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). The cells were treated with the synthetic GR ligand triamcinolone acetonide (TA) for 4 hours prior to harvesting. The IP’d DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer’s instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. Figure 2 shows the peak distribution along the complete sequence of chromosome 16 (figure 2A) as well as the MT2A positive control gene (figure 2B). The position of the PCR amplicon is also indicated. Figure 2C, D and E show the results for the known GR target genes PER1 on chromosome 17 and FKBP5 and TNFAIP3 on chromosome 6. </small></p> </div> </div> <p></p> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig3.png" alt="GR Antibody ELISA Validation" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 3. Sandwich ELISA </strong><br />The specificity of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050) was assessed by sandwich ELISA. Figure 3A: schematic representation of the sandwich ELISA with the monoclonal antibody against hGR (clone #:m2F8). Figure 3B: ELISA results using the monoclonal antibody against hGR at a concentration of 0.5 μg/ml. The figure shows an ELISA signal which is proportionally increasing with increasing amounts of recombinant hGR. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig4.png" alt="GR Antibody validated in Western Blot" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 4. Western blot analysis using the Diagenode monoclonal antibody against hGR </strong><br />Figure 4A. Extracts from HeLa cells containing the indicated amounts of GR (from 30 to 240 fmol), and from 5x10e6 Raji or Molt cells were analysed by Western blot using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). Figure 4B. Western blot analysis of extracts from 300,000 HeLa cells with the Diagenode monoclonal antibody against hGR (concentration 1 μg/ml). </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig5.png" alt="GR Antibody validated in Immunohistochemistry" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig6.png" alt="GR Antibody validated for Immunohistochemistry" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 5. Immunohistochemistry and immunofluorescence using the Diagenode monoclonal antibody against hGR </strong><br />1. Immunoreactivity of the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050) in rat CA1 neurons of hippocampus. The antibody was used at a concentration of 2.5 μg/ml. <br />2. COS-7 cells transiently overexpressing human GR were labeled with the antibody against hGR followed by a biotinylated secondary antibody and peroxidase-labeled avidin. The antibody was used at a concentration of 2.5 μg/ml. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig7.png" alt="GR Antibody validated in Immunoprecipitation" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 6. Immunoprecipitation using the Diagenode monoclonal antibody against hGR </strong><br />The glucocorticoid receptor was immunoprecipitated from HeLa cell extracts (5 million HeLa cells in 100 μl IP reaction solution) using 5 μg of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050). The IP was followed by Western blot analysis as described above </small></p> </div> </div>', 'label2' => 'Target Description', 'info2' => '<p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.</p>', 'label3' => '', 'info3' => '', 'format' => '50 µg', 'catalog_number' => 'C15200010', 'old_catalog_number' => 'MAb-010-050', 'sf_code' => 'C15200010-D001-000581', 'type' => 'FRE', 'search_order' => '03-Antibody', 'price_EUR' => '380', 'price_USD' => '380', 'price_GBP' => '340', 'price_JPY' => '59525', 'price_CNY' => '', 'price_AUD' => '950', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => true, 'last_datasheet_update' => '0000-00-00', 'slug' => 'gr-monoclonal-antibody-classic-50-ug-50-ul', 'meta_title' => 'GR Antibody - ChIP-seq Grade (C15200010) | Diagenode', 'meta_keywords' => '', 'meta_description' => 'GR (Glucocorticoid receptor) Monoclonal Antibody validated in ChIP-seq, ChIP-qPCR, WB, Flow Cyt, IP and ELISA. Batch-specific data available on the website. Alternative names: NR3C1, GCCR, GCR, GRL. Sample size avaialble.', 'modified' => '2024-11-19 16:56:51', 'created' => '2015-06-29 14:08:20' ), 'Product' => array( (int) 0 => array( [maximum depth reached] ) ) ), 'Related' => array(), 'Application' => array( (int) 0 => array( 'id' => '42', 'position' => '10', 'parent_id' => '40', 'name' => 'ChIP-seq (ab)', 'description' => '', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'chip-seq-antibodies', 'meta_keywords' => 'Chromatin Immunoprecipitation Sequencing,ChIP-Seq,ChIP-seq grade antibodies,DNA purification,qPCR,Shearing of chromatin', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for ChIP Sequencing applications', 'meta_title' => 'ChIP Sequencing Antibodies (ChIP-Seq) | Diagenode', 'modified' => '2016-01-20 11:06:19', 'created' => '2015-10-20 11:44:45', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '43', 'position' => '10', 'parent_id' => '40', 'name' => 'ChIP-qPCR (ab)', 'description' => '', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'chip-qpcr-antibodies', 'meta_keywords' => 'Chromatin Immunoprecipitation Sequencing,ChIP-Seq,ChIP-seq grade antibodies,DNA purification,qPCR,Shearing of chromatin', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for ChIP-qPCR applications', 'meta_title' => 'ChIP Quantitative PCR Antibodies (ChIP-qPCR) | Diagenode', 'modified' => '2016-01-20 11:30:24', 'created' => '2015-10-20 11:45:36', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '20', 'position' => '10', 'parent_id' => '40', 'name' => 'ELISA', 'description' => '<div class="row"> <div class="small-12 medium-12 large-12 columns">Enzyme-linked immunosorbent assay.</div> </div>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'elisa-antibodies', 'meta_keywords' => ' ELISA Antibodies,Monoclonal antibody, Polyclonal antibody', 'meta_description' => 'Diagenode offers Monoclonal & Polyclonal antibodies for ELISA applications', 'meta_title' => 'ELISA Antibodies - Monoclonal & Polyclonal antibody | Diagenode', 'modified' => '2016-01-13 12:21:41', 'created' => '2014-07-08 08:13:28', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '19', 'position' => '10', 'parent_id' => '40', 'name' => 'WB', 'description' => '<p><strong>Western blot</strong> : The quality of antibodies used in this technique is crucial for correct and specific protein identification. Diagenode offers huge selection of highly sensitive and specific western blot-validated antibodies.</p> <p>Learn more about: <a href="https://www.diagenode.com/applications/western-blot">Loading control, MW marker visualization</a><em>. <br /></em></p> <p><em></em>Check our selection of antibodies validated in Western blot.</p>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'western-blot-antibodies', 'meta_keywords' => ' Western Blot Antibodies ,western blot protocol,Western Blotting Products,Polyclonal antibodies ,monoclonal antibodies ', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for western blot applications', 'meta_title' => ' Western Blot - Monoclonal antibody - Polyclonal antibody | Diagenode', 'modified' => '2016-04-26 12:44:51', 'created' => '2015-01-07 09:20:00', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '30', 'position' => '10', 'parent_id' => '40', 'name' => 'IP', 'description' => '<p>Immunoprecipitation</p>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'immunoprecipitation', 'meta_keywords' => 'Immunoprecipitation,Monoclonal antibody,Polyclonal antibody', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for Immunoprecipitation applications', 'meta_title' => 'Immunoprecipitation - Monoclonal antibody - Polyclonal antibody | Diagenode', 'modified' => '2016-01-13 12:23:07', 'created' => '2015-07-08 13:46:50', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '33', 'position' => '10', 'parent_id' => '40', 'name' => 'GSA', 'description' => '<p><span>Gel Supershift</span></p>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'gel-supershift-assays', 'meta_keywords' => 'GSA,Gel Super Shift Assays,Gel Shift', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for Gel Supershift applications', 'meta_title' => 'Gel Shift/Gel Super Shift Assays - Monoclonal antibody | Diagenode', 'modified' => '2016-01-13 12:24:19', 'created' => '2015-07-08 13:51:58', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '34', 'position' => '10', 'parent_id' => '40', 'name' => 'Flow Cyt', 'description' => '<p>Flow cyt</p>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'flow-cytometry', 'meta_keywords' => 'Flow cytometry,Flow cyt,Monoclonal antibody,GR monoclonal antibody ', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for Flow cytometry applications', 'meta_title' => 'Flow cytometry - Monoclonal antibody | Diagenode', 'modified' => '2016-01-13 12:24:36', 'created' => '2015-07-08 13:53:00', 'ProductsApplication' => array( [maximum depth reached] ) ) ), 'Category' => array( (int) 0 => array( 'id' => '127', 'position' => '10', 'parent_id' => '4', 'name' => 'ChIP-grade antibodies', 'description' => '<div class="row"> <div class="small-12 columns"><center></center> <p><br />Chromatin immunoprecipitation (<b>ChIP</b>) is a technique to study the associations of proteins with the specific genomic regions in intact cells. One of the most important steps of this protocol is the immunoprecipitation of targeted protein using the antibody specifically recognizing it. The quality of antibodies used in ChIP is essential for the success of the experiment. Diagenode offers extensively validated ChIP-grade antibodies, confirmed for their specificity, and high level of performance in ChIP. Each batch is validated, and batch-specific data are available on the website.</p> <p></p> </div> </div> <p><strong>ChIP results</strong> obtained with the antibody directed against H3K4me3 (Cat. No. <a href="../p/h3k4me3-polyclonal-antibody-premium-50-ug-50-ul">C15410003</a>). </p> <div class="row"> <div class="small-12 medium-6 large-6 columns"><img src="https://www.diagenode.com/img/product/antibodies/C15410003-fig1-ChIP.jpg" alt="" width="400" height="315" /> </div> <div class="small-12 medium-6 large-6 columns"> <p></p> <p></p> <p></p> </div> </div> <p></p> <p>Our aim at Diagenode is to offer the largest collection of highly specific <strong>ChIP-grade antibodies</strong>. We add new antibodies monthly. Find your ChIP-grade antibody in the list below and check more information about tested applications, extensive validation data, and product information.</p>', 'no_promo' => false, 'in_menu' => true, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => false, 'is_antibody' => true, 'slug' => 'chip-grade-antibodies', 'cookies_tag_id' => null, 'meta_keywords' => 'ChIP-grade antibodies, polyclonal antibody, monoclonal antibody, Diagenode', 'meta_description' => 'Diagenode Offers Extensively Validated ChIP-Grade Antibodies, Confirmed for their Specificity, and high level of Performance in Chromatin Immunoprecipitation ChIP', 'meta_title' => 'Chromatin immunoprecipitation ChIP-grade antibodies | Diagenode', 'modified' => '2024-11-19 17:27:07', 'created' => '2017-02-14 11:16:04', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ), (int) 1 => array( 'id' => '17', 'position' => '10', 'parent_id' => '4', 'name' => 'ChIP-seq grade antibodies', 'description' => '<p><b>Unparalleled ChIP-Seq results with the most rigorously validated antibodies</b></p> <p><span style="font-weight: 400;">Diagenode provides leading solutions for epigenetic research. Because ChIP-seq is a widely-used technique, we validate our antibodies in ChIP and ChIP-seq experiments (in addition to conventional methods like Western blot, Dot blot, ELISA, and immunofluorescence) to provide the highest quality antibody. We standardize our validation and production to guarantee high product quality without technical bias. Diagenode guarantees ChIP-seq grade antibody performance under our suggested conditions.</span></p> <div class="row"> <div class="small-12 medium-9 large-9 columns"> <p><strong>ChIP-seq profile</strong> of active (H3K4me3 and H3K36me3) and inactive (H3K27me3) marks using Diagenode antibodies.</p> <img src="https://www.diagenode.com/img/categories/antibodies/chip-seq-grade-antibodies.png" /></div> <div class="small-12 medium-3 large-3 columns"> <p><small> ChIP was performed on sheared chromatin from 100,000 K562 cells using iDeal ChIP-seq kit for Histones (cat. No. C01010051) with 1 µg of the Diagenode antibodies against H3K27me3 (cat. No. C15410195) and H3K4me3 (cat. No. C15410003), and 0.5 µg of the antibody against H3K36me3 (cat. No. C15410192). The IP'd DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer's instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. The figure shows the signal distribution along the complete sequence of human chromosome 3, a zoomin to a 10 Mb region and a further zoomin to a 1.5 Mb region. </small></p> </div> </div> <p>Diagenode’s highly validated antibodies:</p> <ul> <li>Highly sensitive and specific</li> <li>Cost-effective (requires less antibody per reaction)</li> <li>Batch-specific data is available on the website</li> <li>Expert technical support</li> <li>Sample sizes available</li> <li>100% satisfaction guarantee</li> </ul>', 'no_promo' => false, 'in_menu' => true, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => false, 'is_antibody' => true, 'slug' => 'chip-seq-grade-antibodies', 'cookies_tag_id' => null, 'meta_keywords' => 'ChIP-seq grade antibodies,polyclonal antibody,WB, ELISA, ChIP-seq (ab), ChIP-qPCR (ab)', 'meta_description' => 'Diagenode Offers Wide Range of Validated ChIP-Seq Grade Antibodies for Unparalleled ChIP-Seq Results', 'meta_title' => 'Chromatin Immunoprecipitation ChIP-Seq Grade Antibodies | Diagenode', 'modified' => '2019-07-03 10:57:22', 'created' => '2015-02-16 02:24:01', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ), (int) 2 => array( 'id' => '103', 'position' => '0', 'parent_id' => '4', 'name' => 'All antibodies', 'description' => '<p><span style="font-weight: 400;">All Diagenode’s antibodies are listed below. Please, use our Quick search field to find the antibody of interest by target name, application, purity.</span></p> <p><span style="font-weight: 400;">Diagenode’s highly validated antibodies:</span></p> <ul> <li>Highly sensitive and specific</li> <li>Cost-effective (requires less antibody per reaction)</li> <li>Batch-specific data is available on the website</li> <li>Expert technical support</li> <li>Sample sizes available</li> <li>100% satisfaction guarantee</li> </ul>', 'no_promo' => false, 'in_menu' => true, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => false, 'is_antibody' => true, 'slug' => 'all-antibodies', 'cookies_tag_id' => null, 'meta_keywords' => 'Antibodies,Premium Antibodies,Classic,Pioneer', 'meta_description' => 'Diagenode Offers Strict quality standards with Rigorous QC and validated Antibodies. Classified based on level of validation for flexibility of Application. Comprehensive selection of histone and non-histone Antibodies', 'meta_title' => 'Diagenode's selection of Antibodies is exclusively dedicated for Epigenetic Research | Diagenode', 'modified' => '2019-07-03 10:55:44', 'created' => '2015-11-02 14:49:22', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ), (int) 3 => array( 'id' => '102', 'position' => '1', 'parent_id' => '4', 'name' => 'Sample size antibodies', 'description' => '<h1><strong>Validated epigenetics antibodies</strong> – care for a sample?<br /> </h1> <p>Diagenode has partnered with leading epigenetics experts and numerous epigenetics consortiums to bring to you a validated and comprehensive collection of epigenetic antibodies. As an expert in epigenetics, we are committed to offering highly-specific antibodies validated for ChIP/ChIP-seq and many other applications. All batch-specific validation data is available on our website.<br /><a href="../categories/antibodies">Read about our expertise in antibody production</a>.</p> <ul> <li><strong>Focused</strong> - Diagenode's selection of antibodies is exclusively dedicated for epigenetic research. <a title="See the full collection." href="../categories/all-antibodies">See the full collection.</a></li> <li><strong>Strict quality standards</strong> with rigorous QC and validation</li> <li><strong>Classified</strong> based on level of validation for flexibility of application</li> </ul> <p>Existing sample sizes are listed below. We will soon expand our collection. Are you looking for a sample size of another antibody? Just <a href="mailto:agnieszka.zelisko@diagenode.com?Subject=Sample%20Size%20Request" target="_top">Contact us</a>.</p>', 'no_promo' => false, 'in_menu' => true, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => true, 'is_antibody' => true, 'slug' => 'sample-size-antibodies', 'cookies_tag_id' => null, 'meta_keywords' => '5-hmC monoclonal antibody,CRISPR/Cas9 polyclonal antibody ,H3K36me3 polyclonal antibody,diagenode', 'meta_description' => 'Diagenode offers sample volume on selected antibodies for researchers to test, validate and provide confidence and flexibility in choosing from our wide range of antibodies ', 'meta_title' => 'Sample-size Antibodies | Diagenode', 'modified' => '2019-07-03 10:57:05', 'created' => '2015-10-27 12:13:34', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ), (int) 4 => array( 'id' => '30', 'position' => '50', 'parent_id' => '4', 'name' => 'Transcription', 'description' => '<p><span style="font-weight: 400;">The list of Diagenode’s highly specific antibodies for transcription studies includes the antibodies against many transcription factors and nuclear receptors. Check the list below to see our targets.</span></p> <p><span style="font-weight: 400;">Diagenode’s highly validated antibodies:</span></p> <ul> <li><span style="font-weight: 400;"> Highly sensitive and specific</span></li> <li><span style="font-weight: 400;"> Cost-effective (requires less antibody per reaction)</span></li> <li><span style="font-weight: 400;"> Batch-specific data is available on the website</span></li> <li><span style="font-weight: 400;"> Expert technical support</span></li> <li><span style="font-weight: 400;"> Sample sizes available</span></li> <li><span style="font-weight: 400;"> 100% satisfaction guarantee</span></li> </ul>', 'no_promo' => false, 'in_menu' => false, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => false, 'is_antibody' => true, 'slug' => 'transcription-factor', 'cookies_tag_id' => null, 'meta_keywords' => ' Transcription factor antibodies,monoclonal antibodies,polyclonal antibodies', 'meta_description' => 'Diagenode offers polyclonal and monoclonal antibodies for Transcription studie', 'meta_title' => 'Transcription factor Antibodies | Diagenode', 'modified' => '2020-07-06 12:59:19', 'created' => '2015-03-12 10:20:08', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ) ), 'Document' => array( (int) 0 => array( 'id' => '11', 'name' => 'Antibodies you can trust', 'description' => '<p style="text-align: justify;"><span>Epigenetic research tools have evolved over time from endpoint PCR to qPCR to the analyses of large sets of genome-wide sequencing data. ChIP sequencing (ChIP-seq) has now become the gold standard method for chromatin studies, given the accuracy and coverage scale of the approach over other methods. Successful ChIP-seq, however, requires a higher level of experimental accuracy and consistency in all steps of ChIP than ever before. Particularly crucial is the quality of ChIP antibodies. </span></p>', 'image_id' => null, 'type' => 'Poster', 'url' => 'files/posters/Antibodies_you_can_trust_Poster.pdf', 'slug' => 'antibodies-you-can-trust-poster', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2015-10-01 20:18:31', 'created' => '2015-07-03 16:05:15', 'ProductsDocument' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '38', 'name' => 'Epigenetic Antibodies Brochure', 'description' => '<p>More than in any other immuoprecipitation assays, quality antibodies are critical tools in many epigenetics experiments. Since 10 years, Diagenode has developed the most stringent quality production available on the market for antibodies exclusively focused on epigenetic uses. All our antibodies have been qualified to work in epigenetic applications.</p>', 'image_id' => null, 'type' => 'Brochure', 'url' => 'files/brochures/Epigenetic_Antibodies_Brochure.pdf', 'slug' => 'epigenetic-antibodies-brochure', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2016-06-15 11:24:06', 'created' => '2015-07-03 16:05:27', 'ProductsDocument' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '440', 'name' => 'Datasheet hGR C15200010', 'description' => '<p>Datasheet description</p>', 'image_id' => null, 'type' => 'Datasheet', 'url' => 'files/products/antibodies/Datasheet_hGR_C15200010.pdf', 'slug' => 'datasheet-hgr-C15200010', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2015-11-20 17:16:18', 'created' => '2015-07-07 11:47:44', 'ProductsDocument' => array( [maximum depth reached] ) ) ), 'Feature' => array(), 'Image' => array( (int) 0 => array( 'id' => '1783', 'name' => 'product/antibodies/chipseq-grade-ab-icon.png', 'alt' => 'ChIP-seq Grade', 'modified' => '2020-11-27 07:04:40', 'created' => '2018-03-15 15:54:09', 'ProductsImage' => array( [maximum depth reached] ) ) ), 'Promotion' => array(), 'Protocol' => array(), 'Publication' => array( (int) 0 => array( 'id' => '4253', 'name' => 'Coordinated glucocorticoid receptor and MAFB action inducestolerogenesis and epigenome remodeling in dendritic cells', 'authors' => 'Morante-Palacios Octavio et al.', 'description' => '<p>Abstract Glucocorticoids (GCs) exert potent anti-inflammatory effects in immune cells through the glucocorticoid receptor (GR). Dendritic cells (DCs), central actors for coordinating immune responses, acquire tolerogenic properties in response to GCs. Tolerogenic DCs (tolDCs) have emerged as a potential treatment for various inflammatory diseases. To date, the underlying cell type-specific regulatory mechanisms orchestrating GC-mediated acquisition of immunosuppressive properties remain poorly understood. In this study, we investigated the transcriptomic and epigenomic remodeling associated with differentiation to DCs in the presence of GCs. Our analysis demonstrates a major role of MAFB in this process, in synergy with GR. GR and MAFB both interact with methylcytosine dioxygenase TET2 and bind to genomic loci that undergo specific demethylation in tolDCs. We also show that the role of MAFB is more extensive, binding to thousands of genomic loci in tolDCs. Finally, MAFB knockdown erases the tolerogenic properties of tolDCs and reverts the specific DNA demethylation and gene upregulation. The preeminent role of MAFB is also demonstrated in vivo for myeloid cells from synovium in rheumatoid arthritis following GC treatment. Our results imply that, once directly activated by GR, MAFB plays a critical role in orchestrating the epigenomic and transcriptomic remodeling that define the tolerogenic phenotype.</p>', 'date' => '2022-01-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/34893889', 'doi' => '10.1093/nar/gkab1182', 'modified' => '2022-05-20 09:44:29', 'created' => '2022-05-19 10:41:50', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '3208', 'name' => 'The Role of S-Palmitoylation of the Human Glucocorticoid Receptor (hGR) in Mediating the Nongenomic Glucocorticoid Actions', 'authors' => 'Nicolaides N. et al.', 'description' => '<p>Background: Many rapid nongenomic glucocorticoid actions are mediated by membrane-bound glucocorticoid receptors (GRs). S-palmitoylation is a lipid post-translational modification that mediates the membrane localization of some steroid receptors. A highly homologous amino acid sequence (663YLCM KTLLL671) is present in the ligand-binding domain of hGRα, suggesting that hGRα might also undergo S-palmitoylation.</p> <p>Aim: To investigate the role of the motif 663YLCMKTLLL671 in membrane localization of the hGRα and in mediating rapid nongenomic glucocorticoid signaling.</p> <p>Methods and Results: We showed that the mutant receptors hGRαY663A, hGRαC665A and hGRαLL670/671AA, and the addition of the palmitoylation inhibitor 2-bromopalmitate did not prevent membrane localization of hGRα and co-localization with caveolin-1, and did not influence the biphasic activation of mitogen-activated protein kinase (MAPK) signaling pathway in the early time points. Finally, the hGRα was not shown to undergo S-palmitoylation.</p> <p>Conclusions: The motif 663YLCMKTLLL671 does not play a role in membrane localization of hGRα and does not mediate the nongenomic glucocorticoid actions.</p>', 'date' => '2017-04-15', 'pmid' => 'http://www.jmolbiochem.com/index.php/JmolBiochem/article/view/199', 'doi' => '', 'modified' => '2017-07-07 16:21:23', 'created' => '2017-07-07 16:21:23', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '2923', 'name' => 'Three Novel Heterozygous Point Mutations of NR3C1 causing Glucocorticoid Resistance', 'authors' => 'Vitellius G et al.', 'description' => '<p>Generalized glucocorticoid resistance is associated with glucocorticoid receptor (GR, NR3C1) mutations. Three novel heterozygous missense NR3C1 mutations (R477S, Y478C and L672P) were identified in patients presenting with adrenal incidentalomas, glucocorticoid excess without Cushing syndrome. Dexamethasone (DXM) binding studies demonstrated that the affinity of GR<sub>R477S</sub> and GR<sub>Y478C</sub> mutants, located in the DNA-binding domain of GR, was similar to wild-type GR (Kd = 2-3 nM). In contrast, GR<sub>L672P</sub> mutant, located in the ligand-binding domain of GR, was unable to bind glucocorticoids and was more sensitive to protein degradation. GR subcellular distribution revealed a marked decrease in DXM-induced nuclear translocation of GR<sub>R477S</sub> and GR<sub>Y478C</sub> mutants, whereas GR<sub>L672P</sub> remained exclusively cytoplasmic. Chromatin immunoprecipitation demonstrated impaired recruitment of DBD mutants onto the regulatory sequence of FKBP5. Transactivation assays disclosed the lack of transcriptional activity of GR<sub>R477S</sub> and GR<sub>L672P</sub> while GR<sub>Y478C</sub> had a reduced transactivation capacity. Three-D modeling indicated that R477S lost two essential hydrogen bonds with DNA, Y478C resulted in altered interaction with surrounding amino-acids, destabilizing DBD, while L672P altered the H8 helix folding, leading to unstructured LBD. This study identifies novel NR3C1 mutations with their molecular consequences on altered GR signaling and suggests that genetic screening of NR3C1 should be conducted in patients with subclinical hypercorticism.</p>', 'date' => '2016-04-27', 'pmid' => 'http://www.ncbi.nlm.nih.gov/pubmed/27120390', 'doi' => '10.1002/humu.23008', 'modified' => '2016-05-13 17:32:26', 'created' => '2016-05-13 17:32:26', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '2967', 'name' => 'Functional characterization of the hGRαT556I causing Chrousos syndrome', 'authors' => 'Nicolaides NC et al.', 'description' => '<h4>BACKGROUND:</h4> <p><abstracttext label="BACKGROUND" nlmcategory="BACKGROUND">Chrousos syndrome is a rare pathologic condition characterized by generalized, partial resistance of target tissues to glucocorticoids and caused by inactivating mutations of the human glucocorticoid receptor (hGR) gene. A novel case of Chrousos syndrome has been reported in a patient with adrenal incidentaloma, who harboured a heterozygous point mutation in the hGR gene, which resulted in threonine (T) to isoleucine (I) substitution at amino acid position 556 in the ligand-binding domain of the receptor.</abstracttext></p> <h4>OBJECTIVE:</h4> <p><abstracttext label="OBJECTIVE" nlmcategory="OBJECTIVE">To delineate the molecular mechanisms through which the mutant receptor hGRαT556I causes Chrousos syndrome.</abstracttext></p> <h4>DESIGN AND RESULTS:</h4> <p><abstracttext label="DESIGN AND RESULTS" nlmcategory="RESULTS">Compared with the wild-type receptor, the mutant receptor hGRαT556I demonstrated 50% reduction in its ability to transactivate glucocorticoid-responsive genes and in the affinity for the ligand, 30% increase in the ability to transrepress the nuclear factor-κB-target genes and a 3,4-fold delay in the cytoplasmic-to-nuclear translocation. The mutant receptor hGRαT556I did not exert a dominant negative effect upon the hGRα-mediated transcriptional activity; it preserved its ability to bind to DNA and interacted with the glucocorticoid receptor-interacting protein 1 coactivator mostly through its activation function-1 domain. Structural biology studies revealed that the T556I mutation caused disruption of the hydrogen bond formed by the T556 with the =O group of P637 backbone, which resulted in a significant relocation of the P637-bearing loop. This conformational alteration affected the local 3D arrangement of the receptor and hence the electrostatic surface of the region.</abstracttext></p> <h4>CONCLUSIONS:</h4> <p><abstracttext label="CONCLUSIONS" nlmcategory="CONCLUSIONS">The hGRαT556I causes Chrousos syndrome by impairing multiple steps of the glucocorticoid signal transduction pathway.</abstracttext></p>', 'date' => '2016-01-01', 'pmid' => 'http://www.ncbi.nlm.nih.gov/pubmed/26541474', 'doi' => ' 10.1111/eci.12563', 'modified' => '2016-06-29 09:41:42', 'created' => '2016-06-29 09:41:42', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '1776', 'name' => 'Perinatal exposure to low-dose bisphenol A affects the neuroendocrine stress response in rats.', 'authors' => 'Panagiotidou E, Zerva S, Mitsiou DJ, Alexis MN, Kitraki E', 'description' => 'Bisphenol A (BPA) is an estrogen-mimicking endocrine disruptor. Early-life exposures to low doses of BPA exert long-lasting effects on animals' reproductive and brain physiology. However, little is known about the effects of BPA on the stress-response system. Given the interaction of sex and stress hormones, we examined the effect of a low perinatal BPA exposure on the function of the hypothalamic-pituitary-adrenal (HPA) axis at rest and upon application of acute stress. Throughout pregnancy and lactation rats received daily 40 μg BPA/kg body weight orally via cornflakes. We studied the effect of this low but chronic exposure to BPA in the male and female offspring at puberty. BPA exposure led to abnormal adrenal histology including reduced zona reticularis especially in male offspring, hyperplasia of zona fasciculata in both sexes, and increased adrenal weight in female offspring. BPA-treated females had increased basal corticosterone and reduced hypothalamic glucocorticoid receptors (GR) levels. Stressed BPA-exposed females exhibited anxiety-like behavioral coping, a less rigorous corticosterone response, and did not downregulate GR in the hypothalamus, compared with control females. BPA-exposed males exhibited a heightened corticosterone stress response compared with females; they also displayed increased pro-opiomelanocortin mRNA levels and retained the prestress levels of pituitary corticotropin-releasing hormone-receptor 1, compared with control males. We found that perinatal chronic exposure to a low dose of BPA perturbs the basal and stress-induced activity of the HPA axis in a sexually dimorphic manner at adolescence. Exposure to BPA might contribute to increased susceptibility to stress-related disorders in later life.', 'date' => '2014-03-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/24323913', 'doi' => '', 'modified' => '2015-07-24 15:39:01', 'created' => '2015-07-24 15:39:01', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '1557', 'name' => 'Pattern of heat shock factor and heat shock protein expression in lymphocytes of bipolar patients: Increased HSP70-glucocorticoid receptor heterocomplex.', 'authors' => 'Bei ES, Salpeas V, Alevizos B, Anagnostara C, Pappa D, Moutsatsou P', 'description' => 'Bipolar disorder (BD), a stress-related disease, is characterized by altered glucocorticoid receptor (GR) signalling. Stress response includes activation of heat shock factor (HSF) and subsequent heat shock protein (HSP) synthesis which regulate GR folding and function. The objective of this study was to investigate the possible role of HSFs, HSPs and their interaction with GR in BD. We applied immunoprecipitation, SDS-PAGE/Western blot analysis and electrophoretic mobility shift assay (EMSA) in lymphocytes (whole cell or nuclear extracts) from BD patients and healthy subjects and determined the HSPs (HSP90 and HSP70), the heterocomplexes HSP90-GR and HSP70-GR, the HSFs (HSF1 and HSF4) as well as the HSF-DNA binding. The HSP70-GR heterocomplex was elevated (p < 0.05) in BD patients vs healthy subjects, and nuclear HSP70 was reduced (p ≤ 0.01) in bipolar manic patients. Protein levels of HSF1, HSF4, HSP90, HSP90-GR heterocomplex, and HSF-DNA binding remained unaltered in BD patients vs healthy subjects. The corresponding effect sizes (ES) indicated a large ES for HSP70-GR, HSP70, HSF-DNA binding and HSF4, and a medium ES for HSP90, HSF1 and HSP90-GR between healthy subjects and bipolar patients. Significant correlations among HSFs, HSPs, GR and HSP70-GR heterocomplex were observed in healthy subjects, which were abrogated in bipolar patients. The higher interaction between GR and HSP70 and the disturbances in the relations among heat shock response parameters and GR as observed in our BD patients may provide novel insights into the contribution of these factors in BD aetiopathogenesis.', 'date' => '2013-11-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/23938235', 'doi' => '', 'modified' => '2015-07-24 15:39:00', 'created' => '2015-07-24 15:39:00', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '253', 'name' => 'Coactivation of GR and NFKB alters the repertoire of their binding sites and target genes.', 'authors' => 'Rao NA, McCalman MT, Moulos P, Francoijs KJ, Chatziioannou A, Kolisis FN, Alexis MN, Mitsiou DJ, Stunnenberg HG', 'description' => 'Glucocorticoid receptor (GR) exerts anti-inflammatory action in part by antagonizing proinflammatory transcription factors such as the nuclear factor kappa-b (NFKB). Here, we assess the crosstalk of activated GR and RELA (p65, major NFKB component) by global identification of their binding sites and target genes. We show that coactivation of GR and p65 alters the repertoire of regulated genes and results in their association with novel sites in a mutually dependent manner. These novel sites predominantly cluster with p65 target genes that are antagonized by activated GR and vice versa. Our data show that coactivation of GR and NFKB alters signaling pathways that are regulated by each factor separately and provide insight into the networks underlying the GR and NFKB crosstalk.', 'date' => '2011-09-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/21750107', 'doi' => '', 'modified' => '2015-07-24 15:38:57', 'created' => '2015-07-24 15:38:57', 'ProductsPublication' => array( [maximum depth reached] ) ) ), 'Testimonial' => array(), 'Area' => array(), 'SafetySheet' => array( (int) 0 => array( 'id' => '568', 'name' => 'GR antibody SDS US en', 'language' => 'en', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-US-en-GHS_2_0.pdf', 'countries' => 'US', 'modified' => '2020-07-01 14:51:26', 'created' => '2020-07-01 14:51:26', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '566', 'name' => 'GR antibody SDS GB en', 'language' => 'en', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-GB-en-GHS_2_0.pdf', 'countries' => 'GB', 'modified' => '2020-07-01 14:50:36', 'created' => '2020-07-01 14:50:36', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '561', 'name' => 'GR antibody SDS BE fr', 'language' => 'fr', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-BE-fr-GHS_2_0.pdf', 'countries' => 'BE', 'modified' => '2020-07-01 14:47:08', 'created' => '2020-07-01 14:47:08', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '565', 'name' => 'GR antibody SDS FR fr', 'language' => 'fr', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-FR-fr-GHS_2_0.pdf', 'countries' => 'FR', 'modified' => '2020-07-01 14:49:58', 'created' => '2020-07-01 14:49:58', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '564', 'name' => 'GR antibody SDS ES es', 'language' => 'es', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-ES-es-GHS_2_0.pdf', 'countries' => 'ES', 'modified' => '2020-07-01 14:49:11', 'created' => '2020-07-01 14:49:11', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '563', 'name' => 'GR antibody SDS DE de', 'language' => 'de', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-DE-de-GHS_2_0.pdf', 'countries' => 'DE', 'modified' => '2020-07-01 14:48:31', 'created' => '2020-07-01 14:48:31', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '567', 'name' => 'GR antibody SDS JP ja', 'language' => 'ja', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-JP-ja-GHS_2_0.pdf', 'countries' => 'JP', 'modified' => '2020-07-01 14:51:01', 'created' => '2020-07-01 14:51:01', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 7 => array( 'id' => '562', 'name' => 'GR antibody SDS BE nl', 'language' => 'nl', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-BE-nl-GHS_2_0.pdf', 'countries' => 'BE', 'modified' => '2020-07-01 14:47:51', 'created' => '2020-07-01 14:47:51', 'ProductsSafetySheet' => array( [maximum depth reached] ) ) ) ) $meta_canonical = 'https://www.diagenode.com/jp/p/gr-monoclonal-antibody-classic-50-ug-50-ul' $country = 'US' $countries_allowed = array( (int) 0 => 'CA', (int) 1 => 'US', (int) 2 => 'IE', (int) 3 => 'GB', (int) 4 => 'DK', (int) 5 => 'NO', (int) 6 => 'SE', (int) 7 => 'FI', (int) 8 => 'NL', (int) 9 => 'BE', (int) 10 => 'LU', (int) 11 => 'FR', (int) 12 => 'DE', (int) 13 => 'CH', (int) 14 => 'AT', (int) 15 => 'ES', (int) 16 => 'IT', (int) 17 => 'PT' ) $outsource = true $other_formats = array( (int) 0 => array( 'id' => '1970', 'antibody_id' => '326', 'name' => 'GR Antibody', 'description' => '<p>Alternative names: <strong>NR3C1</strong>,<strong> GCCR</strong>, <strong>GCR</strong>, <strong>GRL</strong></p> <p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human <strong>GR (glucocorticoid receptor)</strong>, using a chimeric protein.</p>', 'label1' => 'Validation Data', 'info1' => '<div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig1.png" alt="GR Antibody ChIP Grade" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 1. ChIP results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP assays were performed using HeLa cells, the Diagenode monoclonal antibody directed against GR (Cat. No. MAb-010-050) and optimized PCR primer sets for qPCR. The cells were treated either with ethanol (EtOH, used as a negative control) or triamcinolone acetonide (TA) for 4 hours prior to cell harvesting. ChIP was performed using sheared chromatin from 3 million cells and 5 μg of antibody. QPCR was performed with primers for the human metallothionein promoter (hMTIIA) and for exon 2 of the human myoglobin gene (hmyo ex2), used as a negative control. Figure 1 shows the recovery (the relative amount of immunoprecipitated DNA compared to input DNA) and the occupancy (ratio +/- control target). These results demonstrate the occupancy of the human metallothionein IIA promoter by GR. </small></p> </div> </div> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2A.png" alt="GR Antibody ChIP-seq Grade" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2B.png" alt="GR Antibody for ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2C.png" alt="GR Antibody for ChIP-seq assay" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2D.png" alt="GR Antibody validated in ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2E.png" alt="GR Antibody ChIP-seq Grade" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 2. ChIP-seq results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP was performed on sheared chromatin from 3.5 million HeLaB2 cells using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). The cells were treated with the synthetic GR ligand triamcinolone acetonide (TA) for 4 hours prior to harvesting. The IP’d DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer’s instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. Figure 2 shows the peak distribution along the complete sequence of chromosome 16 (figure 2A) as well as the MT2A positive control gene (figure 2B). The position of the PCR amplicon is also indicated. Figure 2C, D and E show the results for the known GR target genes PER1 on chromosome 17 and FKBP5 and TNFAIP3 on chromosome 6. </small></p> </div> </div> <p></p> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig3.png" alt="GR Antibody ELISA Validation" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 3. Sandwich ELISA </strong><br />The specificity of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050) was assessed by sandwich ELISA. Figure 3A: schematic representation of the sandwich ELISA with the monoclonal antibody against hGR (clone #:m2F8). Figure 3B: ELISA results using the monoclonal antibody against hGR at a concentration of 0.5 μg/ml. The figure shows an ELISA signal which is proportionally increasing with increasing amounts of recombinant hGR. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig4.png" alt="GR Antibody validated in Western Blot" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 4. Western blot analysis using the Diagenode monoclonal antibody against hGR </strong><br />Figure 4A. Extracts from HeLa cells containing the indicated amounts of GR (from 30 to 240 fmol), and from 5x10e6 Raji or Molt cells were analysed by Western blot using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). Figure 4B. Western blot analysis of extracts from 300,000 HeLa cells with the Diagenode monoclonal antibody against hGR (concentration 1 μg/ml). </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig5.png" alt="GR Antibody validated in Immunohistochemistry" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig6.png" alt="GR Antibody validated for Immunohistochemistry" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 5. Immunohistochemistry and immunofluorescence using the Diagenode monoclonal antibody against hGR </strong><br />1. Immunoreactivity of the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050) in rat CA1 neurons of hippocampus. The antibody was used at a concentration of 2.5 μg/ml. <br />2. COS-7 cells transiently overexpressing human GR were labeled with the antibody against hGR followed by a biotinylated secondary antibody and peroxidase-labeled avidin. The antibody was used at a concentration of 2.5 μg/ml. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig7.png" alt="GR Antibody validated in Immunoprecipitation" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 6. Immunoprecipitation using the Diagenode monoclonal antibody against hGR </strong><br />The glucocorticoid receptor was immunoprecipitated from HeLa cell extracts (5 million HeLa cells in 100 μl IP reaction solution) using 5 μg of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050). The IP was followed by Western blot analysis as described above </small></p> </div> </div>', 'label2' => 'Target Description', 'info2' => '<p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.</p>', 'label3' => '', 'info3' => '', 'format' => '50 µg', 'catalog_number' => 'C15200010', 'old_catalog_number' => 'MAb-010-050', 'sf_code' => 'C15200010-D001-000581', 'type' => 'FRE', 'search_order' => '03-Antibody', 'price_EUR' => '380', 'price_USD' => '380', 'price_GBP' => '340', 'price_JPY' => '59525', 'price_CNY' => '', 'price_AUD' => '950', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => true, 'last_datasheet_update' => '0000-00-00', 'slug' => 'gr-monoclonal-antibody-classic-50-ug-50-ul', 'meta_title' => 'GR Antibody - ChIP-seq Grade (C15200010) | Diagenode', 'meta_keywords' => '', 'meta_description' => 'GR (Glucocorticoid receptor) Monoclonal Antibody validated in ChIP-seq, ChIP-qPCR, WB, Flow Cyt, IP and ELISA. Batch-specific data available on the website. Alternative names: NR3C1, GCCR, GCR, GRL. Sample size avaialble.', 'modified' => '2024-11-19 16:56:51', 'created' => '2015-06-29 14:08:20' ) ) $pro = array( 'id' => '2893', 'antibody_id' => '326', 'name' => 'GR Antibody (sample size)', 'description' => '<p>Alternative names: <strong>NR3C1, GCCR, GCR, GRL </strong></p> <p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human <strong>GR (glucocorticoid receptor),</strong> using a chimeric protein.</p>', 'label1' => 'Validation data', 'info1' => '', 'label2' => '', 'info2' => '', 'label3' => '', 'info3' => '', 'format' => '10 µg', 'catalog_number' => 'C15200010-10', 'old_catalog_number' => '', 'sf_code' => 'C15200010-D001-000582', 'type' => 'FRE', 'search_order' => '', 'price_EUR' => '105', 'price_USD' => '115', 'price_GBP' => '100', 'price_JPY' => '16450', 'price_CNY' => '', 'price_AUD' => '288', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => false, 'last_datasheet_update' => '', 'slug' => 'gr-monoclonal-antibody-classic-10-ug', 'meta_title' => 'GR Antibody - ChIP-seq Grade (C15200010) | Diagenode', 'meta_keywords' => '', 'meta_description' => 'GR (Glucocorticoid receptor) Monoclonal Antibody validated in ChIP-seq, ChIP-qPCR, WB, IP, and ELISA. Batch-specific data available on the website. Alternative names: NR3C1, GCCR, GCR, GRL. Sample size available.', 'modified' => '2022-01-05 14:49:33', 'created' => '2017-05-17 14:56:35', 'ProductsGroup' => array( 'id' => '234', 'product_id' => '2893', 'group_id' => '209' ) ) $edit = '' $testimonials = '' $featured_testimonials = '' $related_products = '' $rrbs_service = array( (int) 0 => (int) 1894, (int) 1 => (int) 1895 ) $chipseq_service = array( (int) 0 => (int) 2683, (int) 1 => (int) 1835, (int) 2 => (int) 1836, (int) 3 => (int) 2684, (int) 4 => (int) 1838, (int) 5 => (int) 1839, (int) 6 => (int) 1856 ) $labelize = object(Closure) { } $old_catalog_number = ' <span style="color:#CCC">(MAb-010-050)</span>' $country_code = 'US' $other_format = array( 'id' => '1970', 'antibody_id' => '326', 'name' => 'GR Antibody', 'description' => '<p>Alternative names: <strong>NR3C1</strong>,<strong> GCCR</strong>, <strong>GCR</strong>, <strong>GRL</strong></p> <p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human <strong>GR (glucocorticoid receptor)</strong>, using a chimeric protein.</p>', 'label1' => 'Validation Data', 'info1' => '<div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig1.png" alt="GR Antibody ChIP Grade" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 1. ChIP results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP assays were performed using HeLa cells, the Diagenode monoclonal antibody directed against GR (Cat. No. MAb-010-050) and optimized PCR primer sets for qPCR. The cells were treated either with ethanol (EtOH, used as a negative control) or triamcinolone acetonide (TA) for 4 hours prior to cell harvesting. ChIP was performed using sheared chromatin from 3 million cells and 5 μg of antibody. QPCR was performed with primers for the human metallothionein promoter (hMTIIA) and for exon 2 of the human myoglobin gene (hmyo ex2), used as a negative control. Figure 1 shows the recovery (the relative amount of immunoprecipitated DNA compared to input DNA) and the occupancy (ratio +/- control target). These results demonstrate the occupancy of the human metallothionein IIA promoter by GR. </small></p> </div> </div> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2A.png" alt="GR Antibody ChIP-seq Grade" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2B.png" alt="GR Antibody for ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2C.png" alt="GR Antibody for ChIP-seq assay" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2D.png" alt="GR Antibody validated in ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2E.png" alt="GR Antibody ChIP-seq Grade" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 2. ChIP-seq results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP was performed on sheared chromatin from 3.5 million HeLaB2 cells using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). The cells were treated with the synthetic GR ligand triamcinolone acetonide (TA) for 4 hours prior to harvesting. The IP’d DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer’s instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. Figure 2 shows the peak distribution along the complete sequence of chromosome 16 (figure 2A) as well as the MT2A positive control gene (figure 2B). The position of the PCR amplicon is also indicated. Figure 2C, D and E show the results for the known GR target genes PER1 on chromosome 17 and FKBP5 and TNFAIP3 on chromosome 6. </small></p> </div> </div> <p></p> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig3.png" alt="GR Antibody ELISA Validation" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 3. Sandwich ELISA </strong><br />The specificity of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050) was assessed by sandwich ELISA. Figure 3A: schematic representation of the sandwich ELISA with the monoclonal antibody against hGR (clone #:m2F8). Figure 3B: ELISA results using the monoclonal antibody against hGR at a concentration of 0.5 μg/ml. The figure shows an ELISA signal which is proportionally increasing with increasing amounts of recombinant hGR. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig4.png" alt="GR Antibody validated in Western Blot" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 4. Western blot analysis using the Diagenode monoclonal antibody against hGR </strong><br />Figure 4A. Extracts from HeLa cells containing the indicated amounts of GR (from 30 to 240 fmol), and from 5x10e6 Raji or Molt cells were analysed by Western blot using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). Figure 4B. Western blot analysis of extracts from 300,000 HeLa cells with the Diagenode monoclonal antibody against hGR (concentration 1 μg/ml). </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig5.png" alt="GR Antibody validated in Immunohistochemistry" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig6.png" alt="GR Antibody validated for Immunohistochemistry" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 5. Immunohistochemistry and immunofluorescence using the Diagenode monoclonal antibody against hGR </strong><br />1. Immunoreactivity of the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050) in rat CA1 neurons of hippocampus. The antibody was used at a concentration of 2.5 μg/ml. <br />2. COS-7 cells transiently overexpressing human GR were labeled with the antibody against hGR followed by a biotinylated secondary antibody and peroxidase-labeled avidin. The antibody was used at a concentration of 2.5 μg/ml. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig7.png" alt="GR Antibody validated in Immunoprecipitation" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 6. Immunoprecipitation using the Diagenode monoclonal antibody against hGR </strong><br />The glucocorticoid receptor was immunoprecipitated from HeLa cell extracts (5 million HeLa cells in 100 μl IP reaction solution) using 5 μg of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050). 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Here, we assess the crosstalk of activated GR and RELA (p65, major NFKB component) by global identification of their binding sites and target genes. We show that coactivation of GR and p65 alters the repertoire of regulated genes and results in their association with novel sites in a mutually dependent manner. These novel sites predominantly cluster with p65 target genes that are antagonized by activated GR and vice versa. Our data show that coactivation of GR and NFKB alters signaling pathways that are regulated by each factor separately and provide insight into the networks underlying the GR and NFKB crosstalk.', 'date' => '2011-09-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/21750107', 'doi' => '', 'modified' => '2015-07-24 15:38:57', 'created' => '2015-07-24 15:38:57', 'ProductsPublication' => array( 'id' => '2027', 'product_id' => '2893', 'publication_id' => '253' ) ) $externalLink = ' <a href="https://www.ncbi.nlm.nih.gov/pubmed/21750107" target="_blank"><i class="fa fa-external-link"></i></a>'include - APP/View/Products/view.ctp, line 755 View::_evaluate() - CORE/Cake/View/View.php, line 971 View::_render() - CORE/Cake/View/View.php, line 933 View::render() - CORE/Cake/View/View.php, line 473 Controller::render() - CORE/Cake/Controller/Controller.php, line 963 ProductsController::slug() - APP/Controller/ProductsController.php, line 1052 ReflectionMethod::invokeArgs() - [internal], line ?? 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ChIP results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP assays were performed using HeLa cells, the Diagenode monoclonal antibody directed against GR (Cat. No. MAb-010-050) and optimized PCR primer sets for qPCR. The cells were treated either with ethanol (EtOH, used as a negative control) or triamcinolone acetonide (TA) for 4 hours prior to cell harvesting. ChIP was performed using sheared chromatin from 3 million cells and 5 μg of antibody. QPCR was performed with primers for the human metallothionein promoter (hMTIIA) and for exon 2 of the human myoglobin gene (hmyo ex2), used as a negative control. Figure 1 shows the recovery (the relative amount of immunoprecipitated DNA compared to input DNA) and the occupancy (ratio +/- control target). These results demonstrate the occupancy of the human metallothionein IIA promoter by GR. </small></p> </div> </div> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2A.png" alt="GR Antibody ChIP-seq Grade" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2B.png" alt="GR Antibody for ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2C.png" alt="GR Antibody for ChIP-seq assay" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2D.png" alt="GR Antibody validated in ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2E.png" alt="GR Antibody ChIP-seq Grade" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 2. ChIP-seq results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP was performed on sheared chromatin from 3.5 million HeLaB2 cells using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). The cells were treated with the synthetic GR ligand triamcinolone acetonide (TA) for 4 hours prior to harvesting. The IP’d DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer’s instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. Figure 2 shows the peak distribution along the complete sequence of chromosome 16 (figure 2A) as well as the MT2A positive control gene (figure 2B). The position of the PCR amplicon is also indicated. Figure 2C, D and E show the results for the known GR target genes PER1 on chromosome 17 and FKBP5 and TNFAIP3 on chromosome 6. </small></p> </div> </div> <p></p> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig3.png" alt="GR Antibody ELISA Validation" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 3. Sandwich ELISA </strong><br />The specificity of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050) was assessed by sandwich ELISA. Figure 3A: schematic representation of the sandwich ELISA with the monoclonal antibody against hGR (clone #:m2F8). Figure 3B: ELISA results using the monoclonal antibody against hGR at a concentration of 0.5 μg/ml. The figure shows an ELISA signal which is proportionally increasing with increasing amounts of recombinant hGR. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig4.png" alt="GR Antibody validated in Western Blot" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 4. Western blot analysis using the Diagenode monoclonal antibody against hGR </strong><br />Figure 4A. Extracts from HeLa cells containing the indicated amounts of GR (from 30 to 240 fmol), and from 5x10e6 Raji or Molt cells were analysed by Western blot using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). Figure 4B. Western blot analysis of extracts from 300,000 HeLa cells with the Diagenode monoclonal antibody against hGR (concentration 1 μg/ml). </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig5.png" alt="GR Antibody validated in Immunohistochemistry" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig6.png" alt="GR Antibody validated for Immunohistochemistry" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 5. Immunohistochemistry and immunofluorescence using the Diagenode monoclonal antibody against hGR </strong><br />1. Immunoreactivity of the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050) in rat CA1 neurons of hippocampus. The antibody was used at a concentration of 2.5 μg/ml. <br />2. COS-7 cells transiently overexpressing human GR were labeled with the antibody against hGR followed by a biotinylated secondary antibody and peroxidase-labeled avidin. The antibody was used at a concentration of 2.5 μg/ml. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig7.png" alt="GR Antibody validated in Immunoprecipitation" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 6. Immunoprecipitation using the Diagenode monoclonal antibody against hGR </strong><br />The glucocorticoid receptor was immunoprecipitated from HeLa cell extracts (5 million HeLa cells in 100 μl IP reaction solution) using 5 μg of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050). The IP was followed by Western blot analysis as described above </small></p> </div> </div>', 'label2' => 'Target Description', 'info2' => '<p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.</p>', 'label3' => '', 'info3' => '', 'format' => '10 µg', 'catalog_number' => 'C15200010-10', 'old_catalog_number' => '', 'sf_code' => 'C15200010-D001-000582', 'type' => 'FRE', 'search_order' => '', 'price_EUR' => '105', 'price_USD' => '115', 'price_GBP' => '100', 'price_JPY' => '16450', 'price_CNY' => '', 'price_AUD' => '288', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => false, 'last_datasheet_update' => '', 'slug' => 'gr-monoclonal-antibody-classic-10-ug', 'meta_title' => '', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2022-01-05 14:49:33', 'created' => '2017-05-17 14:56:35', 'locale' => 'jpn' ), 'Antibody' => array( 'host' => '*****', 'id' => '326', 'name' => 'GR monoclonal antibody', 'description' => 'Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.', 'clonality' => '', 'isotype' => '', 'lot' => 'NR-010', 'concentration' => '1.0 µg/µl', 'reactivity' => 'Human, rat', 'type' => 'Monoclonal', 'purity' => 'Ammonium sulphate purified', 'classification' => 'Classic', 'application_table' => '<table> <thead> <tr> <th>Applications</th> <th>Suggested dilution</th> <th>References</th> </tr> </thead> <tbody> <tr> <td>ChIP/ChIP-seq</td> <td>5 μg/ChIP</td> <td>Fig 1, 2</td> </tr> <tr> <td>ELISA</td> <td>0.5 μg/ml</td> <td>Fig 3</td> </tr> <tr> <td>Western Blotting</td> <td>1 μg/ml</td> <td>Fig 4</td> </tr> <tr> <td>Gel Supershift</td> <td>5 μg/ml</td> <td></td> </tr> <tr> <td>Immunochemistry</td> <td>2.5 μg/ml</td> <td>Fig 5, 6</td> </tr> <tr> <td>Flow cytometry</td> <td>0.5 μg/ml</td> <td></td> </tr> <tr> <td>Immunoprecipitation</td> <td>5 μg/IP</td> <td>Fig 7</td> </tr> </tbody> </table> <p></p>', 'storage_conditions' => '', 'storage_buffer' => '', 'precautions' => 'This product is for research use only. Not for use in diagnostic or therapeutic procedures.', 'uniprot_acc' => '', 'slug' => '', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2020-09-18 16:34:22', 'created' => '0000-00-00 00:00:00', 'select_label' => '326 - GR monoclonal antibody (NR-010 - 1.0 µg/µl - Human, rat - Ammonium sulphate purified - Mouse)' ), 'Slave' => array(), 'Group' => array( 'Group' => array( 'id' => '209', 'name' => 'C15200010', 'product_id' => '1970', 'modified' => '2017-05-17 14:57:11', 'created' => '2017-05-17 14:57:11' ), 'Master' => array( 'id' => '1970', 'antibody_id' => '326', 'name' => 'GR Antibody', 'description' => '<p>Alternative names: <strong>NR3C1</strong>,<strong> GCCR</strong>, <strong>GCR</strong>, <strong>GRL</strong></p> <p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human <strong>GR (glucocorticoid receptor)</strong>, using a chimeric protein.</p>', 'label1' => 'Validation Data', 'info1' => '<div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig1.png" alt="GR Antibody ChIP Grade" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 1. ChIP results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP assays were performed using HeLa cells, the Diagenode monoclonal antibody directed against GR (Cat. No. MAb-010-050) and optimized PCR primer sets for qPCR. The cells were treated either with ethanol (EtOH, used as a negative control) or triamcinolone acetonide (TA) for 4 hours prior to cell harvesting. ChIP was performed using sheared chromatin from 3 million cells and 5 μg of antibody. QPCR was performed with primers for the human metallothionein promoter (hMTIIA) and for exon 2 of the human myoglobin gene (hmyo ex2), used as a negative control. Figure 1 shows the recovery (the relative amount of immunoprecipitated DNA compared to input DNA) and the occupancy (ratio +/- control target). These results demonstrate the occupancy of the human metallothionein IIA promoter by GR. </small></p> </div> </div> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2A.png" alt="GR Antibody ChIP-seq Grade" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2B.png" alt="GR Antibody for ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2C.png" alt="GR Antibody for ChIP-seq assay" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2D.png" alt="GR Antibody validated in ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2E.png" alt="GR Antibody ChIP-seq Grade" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 2. ChIP-seq results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP was performed on sheared chromatin from 3.5 million HeLaB2 cells using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). The cells were treated with the synthetic GR ligand triamcinolone acetonide (TA) for 4 hours prior to harvesting. The IP’d DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer’s instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. Figure 2 shows the peak distribution along the complete sequence of chromosome 16 (figure 2A) as well as the MT2A positive control gene (figure 2B). The position of the PCR amplicon is also indicated. Figure 2C, D and E show the results for the known GR target genes PER1 on chromosome 17 and FKBP5 and TNFAIP3 on chromosome 6. </small></p> </div> </div> <p></p> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig3.png" alt="GR Antibody ELISA Validation" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 3. Sandwich ELISA </strong><br />The specificity of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050) was assessed by sandwich ELISA. Figure 3A: schematic representation of the sandwich ELISA with the monoclonal antibody against hGR (clone #:m2F8). Figure 3B: ELISA results using the monoclonal antibody against hGR at a concentration of 0.5 μg/ml. The figure shows an ELISA signal which is proportionally increasing with increasing amounts of recombinant hGR. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig4.png" alt="GR Antibody validated in Western Blot" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 4. Western blot analysis using the Diagenode monoclonal antibody against hGR </strong><br />Figure 4A. Extracts from HeLa cells containing the indicated amounts of GR (from 30 to 240 fmol), and from 5x10e6 Raji or Molt cells were analysed by Western blot using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). Figure 4B. Western blot analysis of extracts from 300,000 HeLa cells with the Diagenode monoclonal antibody against hGR (concentration 1 μg/ml). </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig5.png" alt="GR Antibody validated in Immunohistochemistry" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig6.png" alt="GR Antibody validated for Immunohistochemistry" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 5. Immunohistochemistry and immunofluorescence using the Diagenode monoclonal antibody against hGR </strong><br />1. Immunoreactivity of the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050) in rat CA1 neurons of hippocampus. The antibody was used at a concentration of 2.5 μg/ml. <br />2. COS-7 cells transiently overexpressing human GR were labeled with the antibody against hGR followed by a biotinylated secondary antibody and peroxidase-labeled avidin. The antibody was used at a concentration of 2.5 μg/ml. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig7.png" alt="GR Antibody validated in Immunoprecipitation" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 6. Immunoprecipitation using the Diagenode monoclonal antibody against hGR </strong><br />The glucocorticoid receptor was immunoprecipitated from HeLa cell extracts (5 million HeLa cells in 100 μl IP reaction solution) using 5 μg of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050). The IP was followed by Western blot analysis as described above </small></p> </div> </div>', 'label2' => 'Target Description', 'info2' => '<p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.</p>', 'label3' => '', 'info3' => '', 'format' => '50 µg', 'catalog_number' => 'C15200010', 'old_catalog_number' => 'MAb-010-050', 'sf_code' => 'C15200010-D001-000581', 'type' => 'FRE', 'search_order' => '03-Antibody', 'price_EUR' => '380', 'price_USD' => '380', 'price_GBP' => '340', 'price_JPY' => '59525', 'price_CNY' => '', 'price_AUD' => '950', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => true, 'last_datasheet_update' => '0000-00-00', 'slug' => 'gr-monoclonal-antibody-classic-50-ug-50-ul', 'meta_title' => 'GR Antibody - ChIP-seq Grade (C15200010) | Diagenode', 'meta_keywords' => '', 'meta_description' => 'GR (Glucocorticoid receptor) Monoclonal Antibody validated in ChIP-seq, ChIP-qPCR, WB, Flow Cyt, IP and ELISA. Batch-specific data available on the website. Alternative names: NR3C1, GCCR, GCR, GRL. Sample size avaialble.', 'modified' => '2024-11-19 16:56:51', 'created' => '2015-06-29 14:08:20' ), 'Product' => array( (int) 0 => array( [maximum depth reached] ) ) ), 'Related' => array(), 'Application' => array( (int) 0 => array( 'id' => '42', 'position' => '10', 'parent_id' => '40', 'name' => 'ChIP-seq (ab)', 'description' => '', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'chip-seq-antibodies', 'meta_keywords' => 'Chromatin Immunoprecipitation Sequencing,ChIP-Seq,ChIP-seq grade antibodies,DNA purification,qPCR,Shearing of chromatin', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for ChIP Sequencing applications', 'meta_title' => 'ChIP Sequencing Antibodies (ChIP-Seq) | Diagenode', 'modified' => '2016-01-20 11:06:19', 'created' => '2015-10-20 11:44:45', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '43', 'position' => '10', 'parent_id' => '40', 'name' => 'ChIP-qPCR (ab)', 'description' => '', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'chip-qpcr-antibodies', 'meta_keywords' => 'Chromatin Immunoprecipitation Sequencing,ChIP-Seq,ChIP-seq grade antibodies,DNA purification,qPCR,Shearing of chromatin', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for ChIP-qPCR applications', 'meta_title' => 'ChIP Quantitative PCR Antibodies (ChIP-qPCR) | Diagenode', 'modified' => '2016-01-20 11:30:24', 'created' => '2015-10-20 11:45:36', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '20', 'position' => '10', 'parent_id' => '40', 'name' => 'ELISA', 'description' => '<div class="row"> <div class="small-12 medium-12 large-12 columns">Enzyme-linked immunosorbent assay.</div> </div>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'elisa-antibodies', 'meta_keywords' => ' ELISA Antibodies,Monoclonal antibody, Polyclonal antibody', 'meta_description' => 'Diagenode offers Monoclonal & Polyclonal antibodies for ELISA applications', 'meta_title' => 'ELISA Antibodies - Monoclonal & Polyclonal antibody | Diagenode', 'modified' => '2016-01-13 12:21:41', 'created' => '2014-07-08 08:13:28', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '19', 'position' => '10', 'parent_id' => '40', 'name' => 'WB', 'description' => '<p><strong>Western blot</strong> : The quality of antibodies used in this technique is crucial for correct and specific protein identification. Diagenode offers huge selection of highly sensitive and specific western blot-validated antibodies.</p> <p>Learn more about: <a href="https://www.diagenode.com/applications/western-blot">Loading control, MW marker visualization</a><em>. <br /></em></p> <p><em></em>Check our selection of antibodies validated in Western blot.</p>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'western-blot-antibodies', 'meta_keywords' => ' Western Blot Antibodies ,western blot protocol,Western Blotting Products,Polyclonal antibodies ,monoclonal antibodies ', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for western blot applications', 'meta_title' => ' Western Blot - Monoclonal antibody - Polyclonal antibody | Diagenode', 'modified' => '2016-04-26 12:44:51', 'created' => '2015-01-07 09:20:00', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '30', 'position' => '10', 'parent_id' => '40', 'name' => 'IP', 'description' => '<p>Immunoprecipitation</p>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'immunoprecipitation', 'meta_keywords' => 'Immunoprecipitation,Monoclonal antibody,Polyclonal antibody', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for Immunoprecipitation applications', 'meta_title' => 'Immunoprecipitation - Monoclonal antibody - Polyclonal antibody | Diagenode', 'modified' => '2016-01-13 12:23:07', 'created' => '2015-07-08 13:46:50', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '33', 'position' => '10', 'parent_id' => '40', 'name' => 'GSA', 'description' => '<p><span>Gel Supershift</span></p>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'gel-supershift-assays', 'meta_keywords' => 'GSA,Gel Super Shift Assays,Gel Shift', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for Gel Supershift applications', 'meta_title' => 'Gel Shift/Gel Super Shift Assays - Monoclonal antibody | Diagenode', 'modified' => '2016-01-13 12:24:19', 'created' => '2015-07-08 13:51:58', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '34', 'position' => '10', 'parent_id' => '40', 'name' => 'Flow Cyt', 'description' => '<p>Flow cyt</p>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'flow-cytometry', 'meta_keywords' => 'Flow cytometry,Flow cyt,Monoclonal antibody,GR monoclonal antibody ', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for Flow cytometry applications', 'meta_title' => 'Flow cytometry - Monoclonal antibody | Diagenode', 'modified' => '2016-01-13 12:24:36', 'created' => '2015-07-08 13:53:00', 'ProductsApplication' => array( [maximum depth reached] ) ) ), 'Category' => array( (int) 0 => array( 'id' => '127', 'position' => '10', 'parent_id' => '4', 'name' => 'ChIP-grade antibodies', 'description' => '<div class="row"> <div class="small-12 columns"><center></center> <p><br />Chromatin immunoprecipitation (<b>ChIP</b>) is a technique to study the associations of proteins with the specific genomic regions in intact cells. One of the most important steps of this protocol is the immunoprecipitation of targeted protein using the antibody specifically recognizing it. The quality of antibodies used in ChIP is essential for the success of the experiment. Diagenode offers extensively validated ChIP-grade antibodies, confirmed for their specificity, and high level of performance in ChIP. Each batch is validated, and batch-specific data are available on the website.</p> <p></p> </div> </div> <p><strong>ChIP results</strong> obtained with the antibody directed against H3K4me3 (Cat. No. <a href="../p/h3k4me3-polyclonal-antibody-premium-50-ug-50-ul">C15410003</a>). </p> <div class="row"> <div class="small-12 medium-6 large-6 columns"><img src="https://www.diagenode.com/img/product/antibodies/C15410003-fig1-ChIP.jpg" alt="" width="400" height="315" /> </div> <div class="small-12 medium-6 large-6 columns"> <p></p> <p></p> <p></p> </div> </div> <p></p> <p>Our aim at Diagenode is to offer the largest collection of highly specific <strong>ChIP-grade antibodies</strong>. We add new antibodies monthly. Find your ChIP-grade antibody in the list below and check more information about tested applications, extensive validation data, and product information.</p>', 'no_promo' => false, 'in_menu' => true, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => false, 'is_antibody' => true, 'slug' => 'chip-grade-antibodies', 'cookies_tag_id' => null, 'meta_keywords' => 'ChIP-grade antibodies, polyclonal antibody, monoclonal antibody, Diagenode', 'meta_description' => 'Diagenode Offers Extensively Validated ChIP-Grade Antibodies, Confirmed for their Specificity, and high level of Performance in Chromatin Immunoprecipitation ChIP', 'meta_title' => 'Chromatin immunoprecipitation ChIP-grade antibodies | Diagenode', 'modified' => '2024-11-19 17:27:07', 'created' => '2017-02-14 11:16:04', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ), (int) 1 => array( 'id' => '17', 'position' => '10', 'parent_id' => '4', 'name' => 'ChIP-seq grade antibodies', 'description' => '<p><b>Unparalleled ChIP-Seq results with the most rigorously validated antibodies</b></p> <p><span style="font-weight: 400;">Diagenode provides leading solutions for epigenetic research. Because ChIP-seq is a widely-used technique, we validate our antibodies in ChIP and ChIP-seq experiments (in addition to conventional methods like Western blot, Dot blot, ELISA, and immunofluorescence) to provide the highest quality antibody. We standardize our validation and production to guarantee high product quality without technical bias. Diagenode guarantees ChIP-seq grade antibody performance under our suggested conditions.</span></p> <div class="row"> <div class="small-12 medium-9 large-9 columns"> <p><strong>ChIP-seq profile</strong> of active (H3K4me3 and H3K36me3) and inactive (H3K27me3) marks using Diagenode antibodies.</p> <img src="https://www.diagenode.com/img/categories/antibodies/chip-seq-grade-antibodies.png" /></div> <div class="small-12 medium-3 large-3 columns"> <p><small> ChIP was performed on sheared chromatin from 100,000 K562 cells using iDeal ChIP-seq kit for Histones (cat. No. C01010051) with 1 µg of the Diagenode antibodies against H3K27me3 (cat. No. C15410195) and H3K4me3 (cat. No. C15410003), and 0.5 µg of the antibody against H3K36me3 (cat. No. C15410192). The IP'd DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer's instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. The figure shows the signal distribution along the complete sequence of human chromosome 3, a zoomin to a 10 Mb region and a further zoomin to a 1.5 Mb region. </small></p> </div> </div> <p>Diagenode’s highly validated antibodies:</p> <ul> <li>Highly sensitive and specific</li> <li>Cost-effective (requires less antibody per reaction)</li> <li>Batch-specific data is available on the website</li> <li>Expert technical support</li> <li>Sample sizes available</li> <li>100% satisfaction guarantee</li> </ul>', 'no_promo' => false, 'in_menu' => true, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => false, 'is_antibody' => true, 'slug' => 'chip-seq-grade-antibodies', 'cookies_tag_id' => null, 'meta_keywords' => 'ChIP-seq grade antibodies,polyclonal antibody,WB, ELISA, ChIP-seq (ab), ChIP-qPCR (ab)', 'meta_description' => 'Diagenode Offers Wide Range of Validated ChIP-Seq Grade Antibodies for Unparalleled ChIP-Seq Results', 'meta_title' => 'Chromatin Immunoprecipitation ChIP-Seq Grade Antibodies | Diagenode', 'modified' => '2019-07-03 10:57:22', 'created' => '2015-02-16 02:24:01', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ), (int) 2 => array( 'id' => '103', 'position' => '0', 'parent_id' => '4', 'name' => 'All antibodies', 'description' => '<p><span style="font-weight: 400;">All Diagenode’s antibodies are listed below. Please, use our Quick search field to find the antibody of interest by target name, application, purity.</span></p> <p><span style="font-weight: 400;">Diagenode’s highly validated antibodies:</span></p> <ul> <li>Highly sensitive and specific</li> <li>Cost-effective (requires less antibody per reaction)</li> <li>Batch-specific data is available on the website</li> <li>Expert technical support</li> <li>Sample sizes available</li> <li>100% satisfaction guarantee</li> </ul>', 'no_promo' => false, 'in_menu' => true, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => false, 'is_antibody' => true, 'slug' => 'all-antibodies', 'cookies_tag_id' => null, 'meta_keywords' => 'Antibodies,Premium Antibodies,Classic,Pioneer', 'meta_description' => 'Diagenode Offers Strict quality standards with Rigorous QC and validated Antibodies. Classified based on level of validation for flexibility of Application. Comprehensive selection of histone and non-histone Antibodies', 'meta_title' => 'Diagenode's selection of Antibodies is exclusively dedicated for Epigenetic Research | Diagenode', 'modified' => '2019-07-03 10:55:44', 'created' => '2015-11-02 14:49:22', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ), (int) 3 => array( 'id' => '102', 'position' => '1', 'parent_id' => '4', 'name' => 'Sample size antibodies', 'description' => '<h1><strong>Validated epigenetics antibodies</strong> – care for a sample?<br /> </h1> <p>Diagenode has partnered with leading epigenetics experts and numerous epigenetics consortiums to bring to you a validated and comprehensive collection of epigenetic antibodies. As an expert in epigenetics, we are committed to offering highly-specific antibodies validated for ChIP/ChIP-seq and many other applications. All batch-specific validation data is available on our website.<br /><a href="../categories/antibodies">Read about our expertise in antibody production</a>.</p> <ul> <li><strong>Focused</strong> - Diagenode's selection of antibodies is exclusively dedicated for epigenetic research. <a title="See the full collection." href="../categories/all-antibodies">See the full collection.</a></li> <li><strong>Strict quality standards</strong> with rigorous QC and validation</li> <li><strong>Classified</strong> based on level of validation for flexibility of application</li> </ul> <p>Existing sample sizes are listed below. We will soon expand our collection. Are you looking for a sample size of another antibody? Just <a href="mailto:agnieszka.zelisko@diagenode.com?Subject=Sample%20Size%20Request" target="_top">Contact us</a>.</p>', 'no_promo' => false, 'in_menu' => true, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => true, 'is_antibody' => true, 'slug' => 'sample-size-antibodies', 'cookies_tag_id' => null, 'meta_keywords' => '5-hmC monoclonal antibody,CRISPR/Cas9 polyclonal antibody ,H3K36me3 polyclonal antibody,diagenode', 'meta_description' => 'Diagenode offers sample volume on selected antibodies for researchers to test, validate and provide confidence and flexibility in choosing from our wide range of antibodies ', 'meta_title' => 'Sample-size Antibodies | Diagenode', 'modified' => '2019-07-03 10:57:05', 'created' => '2015-10-27 12:13:34', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ), (int) 4 => array( 'id' => '30', 'position' => '50', 'parent_id' => '4', 'name' => 'Transcription', 'description' => '<p><span style="font-weight: 400;">The list of Diagenode’s highly specific antibodies for transcription studies includes the antibodies against many transcription factors and nuclear receptors. Check the list below to see our targets.</span></p> <p><span style="font-weight: 400;">Diagenode’s highly validated antibodies:</span></p> <ul> <li><span style="font-weight: 400;"> Highly sensitive and specific</span></li> <li><span style="font-weight: 400;"> Cost-effective (requires less antibody per reaction)</span></li> <li><span style="font-weight: 400;"> Batch-specific data is available on the website</span></li> <li><span style="font-weight: 400;"> Expert technical support</span></li> <li><span style="font-weight: 400;"> Sample sizes available</span></li> <li><span style="font-weight: 400;"> 100% satisfaction guarantee</span></li> </ul>', 'no_promo' => false, 'in_menu' => false, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => false, 'is_antibody' => true, 'slug' => 'transcription-factor', 'cookies_tag_id' => null, 'meta_keywords' => ' Transcription factor antibodies,monoclonal antibodies,polyclonal antibodies', 'meta_description' => 'Diagenode offers polyclonal and monoclonal antibodies for Transcription studie', 'meta_title' => 'Transcription factor Antibodies | Diagenode', 'modified' => '2020-07-06 12:59:19', 'created' => '2015-03-12 10:20:08', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ) ), 'Document' => array( (int) 0 => array( 'id' => '11', 'name' => 'Antibodies you can trust', 'description' => '<p style="text-align: justify;"><span>Epigenetic research tools have evolved over time from endpoint PCR to qPCR to the analyses of large sets of genome-wide sequencing data. ChIP sequencing (ChIP-seq) has now become the gold standard method for chromatin studies, given the accuracy and coverage scale of the approach over other methods. Successful ChIP-seq, however, requires a higher level of experimental accuracy and consistency in all steps of ChIP than ever before. Particularly crucial is the quality of ChIP antibodies. </span></p>', 'image_id' => null, 'type' => 'Poster', 'url' => 'files/posters/Antibodies_you_can_trust_Poster.pdf', 'slug' => 'antibodies-you-can-trust-poster', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2015-10-01 20:18:31', 'created' => '2015-07-03 16:05:15', 'ProductsDocument' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '38', 'name' => 'Epigenetic Antibodies Brochure', 'description' => '<p>More than in any other immuoprecipitation assays, quality antibodies are critical tools in many epigenetics experiments. Since 10 years, Diagenode has developed the most stringent quality production available on the market for antibodies exclusively focused on epigenetic uses. All our antibodies have been qualified to work in epigenetic applications.</p>', 'image_id' => null, 'type' => 'Brochure', 'url' => 'files/brochures/Epigenetic_Antibodies_Brochure.pdf', 'slug' => 'epigenetic-antibodies-brochure', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2016-06-15 11:24:06', 'created' => '2015-07-03 16:05:27', 'ProductsDocument' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '440', 'name' => 'Datasheet hGR C15200010', 'description' => '<p>Datasheet description</p>', 'image_id' => null, 'type' => 'Datasheet', 'url' => 'files/products/antibodies/Datasheet_hGR_C15200010.pdf', 'slug' => 'datasheet-hgr-C15200010', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2015-11-20 17:16:18', 'created' => '2015-07-07 11:47:44', 'ProductsDocument' => array( [maximum depth reached] ) ) ), 'Feature' => array(), 'Image' => array( (int) 0 => array( 'id' => '1783', 'name' => 'product/antibodies/chipseq-grade-ab-icon.png', 'alt' => 'ChIP-seq Grade', 'modified' => '2020-11-27 07:04:40', 'created' => '2018-03-15 15:54:09', 'ProductsImage' => array( [maximum depth reached] ) ) ), 'Promotion' => array(), 'Protocol' => array(), 'Publication' => array( (int) 0 => array( 'id' => '4253', 'name' => 'Coordinated glucocorticoid receptor and MAFB action inducestolerogenesis and epigenome remodeling in dendritic cells', 'authors' => 'Morante-Palacios Octavio et al.', 'description' => '<p>Abstract Glucocorticoids (GCs) exert potent anti-inflammatory effects in immune cells through the glucocorticoid receptor (GR). Dendritic cells (DCs), central actors for coordinating immune responses, acquire tolerogenic properties in response to GCs. Tolerogenic DCs (tolDCs) have emerged as a potential treatment for various inflammatory diseases. To date, the underlying cell type-specific regulatory mechanisms orchestrating GC-mediated acquisition of immunosuppressive properties remain poorly understood. In this study, we investigated the transcriptomic and epigenomic remodeling associated with differentiation to DCs in the presence of GCs. Our analysis demonstrates a major role of MAFB in this process, in synergy with GR. GR and MAFB both interact with methylcytosine dioxygenase TET2 and bind to genomic loci that undergo specific demethylation in tolDCs. We also show that the role of MAFB is more extensive, binding to thousands of genomic loci in tolDCs. Finally, MAFB knockdown erases the tolerogenic properties of tolDCs and reverts the specific DNA demethylation and gene upregulation. The preeminent role of MAFB is also demonstrated in vivo for myeloid cells from synovium in rheumatoid arthritis following GC treatment. Our results imply that, once directly activated by GR, MAFB plays a critical role in orchestrating the epigenomic and transcriptomic remodeling that define the tolerogenic phenotype.</p>', 'date' => '2022-01-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/34893889', 'doi' => '10.1093/nar/gkab1182', 'modified' => '2022-05-20 09:44:29', 'created' => '2022-05-19 10:41:50', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '3208', 'name' => 'The Role of S-Palmitoylation of the Human Glucocorticoid Receptor (hGR) in Mediating the Nongenomic Glucocorticoid Actions', 'authors' => 'Nicolaides N. et al.', 'description' => '<p>Background: Many rapid nongenomic glucocorticoid actions are mediated by membrane-bound glucocorticoid receptors (GRs). S-palmitoylation is a lipid post-translational modification that mediates the membrane localization of some steroid receptors. A highly homologous amino acid sequence (663YLCM KTLLL671) is present in the ligand-binding domain of hGRα, suggesting that hGRα might also undergo S-palmitoylation.</p> <p>Aim: To investigate the role of the motif 663YLCMKTLLL671 in membrane localization of the hGRα and in mediating rapid nongenomic glucocorticoid signaling.</p> <p>Methods and Results: We showed that the mutant receptors hGRαY663A, hGRαC665A and hGRαLL670/671AA, and the addition of the palmitoylation inhibitor 2-bromopalmitate did not prevent membrane localization of hGRα and co-localization with caveolin-1, and did not influence the biphasic activation of mitogen-activated protein kinase (MAPK) signaling pathway in the early time points. Finally, the hGRα was not shown to undergo S-palmitoylation.</p> <p>Conclusions: The motif 663YLCMKTLLL671 does not play a role in membrane localization of hGRα and does not mediate the nongenomic glucocorticoid actions.</p>', 'date' => '2017-04-15', 'pmid' => 'http://www.jmolbiochem.com/index.php/JmolBiochem/article/view/199', 'doi' => '', 'modified' => '2017-07-07 16:21:23', 'created' => '2017-07-07 16:21:23', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '2923', 'name' => 'Three Novel Heterozygous Point Mutations of NR3C1 causing Glucocorticoid Resistance', 'authors' => 'Vitellius G et al.', 'description' => '<p>Generalized glucocorticoid resistance is associated with glucocorticoid receptor (GR, NR3C1) mutations. Three novel heterozygous missense NR3C1 mutations (R477S, Y478C and L672P) were identified in patients presenting with adrenal incidentalomas, glucocorticoid excess without Cushing syndrome. Dexamethasone (DXM) binding studies demonstrated that the affinity of GR<sub>R477S</sub> and GR<sub>Y478C</sub> mutants, located in the DNA-binding domain of GR, was similar to wild-type GR (Kd = 2-3 nM). In contrast, GR<sub>L672P</sub> mutant, located in the ligand-binding domain of GR, was unable to bind glucocorticoids and was more sensitive to protein degradation. GR subcellular distribution revealed a marked decrease in DXM-induced nuclear translocation of GR<sub>R477S</sub> and GR<sub>Y478C</sub> mutants, whereas GR<sub>L672P</sub> remained exclusively cytoplasmic. Chromatin immunoprecipitation demonstrated impaired recruitment of DBD mutants onto the regulatory sequence of FKBP5. Transactivation assays disclosed the lack of transcriptional activity of GR<sub>R477S</sub> and GR<sub>L672P</sub> while GR<sub>Y478C</sub> had a reduced transactivation capacity. Three-D modeling indicated that R477S lost two essential hydrogen bonds with DNA, Y478C resulted in altered interaction with surrounding amino-acids, destabilizing DBD, while L672P altered the H8 helix folding, leading to unstructured LBD. This study identifies novel NR3C1 mutations with their molecular consequences on altered GR signaling and suggests that genetic screening of NR3C1 should be conducted in patients with subclinical hypercorticism.</p>', 'date' => '2016-04-27', 'pmid' => 'http://www.ncbi.nlm.nih.gov/pubmed/27120390', 'doi' => '10.1002/humu.23008', 'modified' => '2016-05-13 17:32:26', 'created' => '2016-05-13 17:32:26', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '2967', 'name' => 'Functional characterization of the hGRαT556I causing Chrousos syndrome', 'authors' => 'Nicolaides NC et al.', 'description' => '<h4>BACKGROUND:</h4> <p><abstracttext label="BACKGROUND" nlmcategory="BACKGROUND">Chrousos syndrome is a rare pathologic condition characterized by generalized, partial resistance of target tissues to glucocorticoids and caused by inactivating mutations of the human glucocorticoid receptor (hGR) gene. A novel case of Chrousos syndrome has been reported in a patient with adrenal incidentaloma, who harboured a heterozygous point mutation in the hGR gene, which resulted in threonine (T) to isoleucine (I) substitution at amino acid position 556 in the ligand-binding domain of the receptor.</abstracttext></p> <h4>OBJECTIVE:</h4> <p><abstracttext label="OBJECTIVE" nlmcategory="OBJECTIVE">To delineate the molecular mechanisms through which the mutant receptor hGRαT556I causes Chrousos syndrome.</abstracttext></p> <h4>DESIGN AND RESULTS:</h4> <p><abstracttext label="DESIGN AND RESULTS" nlmcategory="RESULTS">Compared with the wild-type receptor, the mutant receptor hGRαT556I demonstrated 50% reduction in its ability to transactivate glucocorticoid-responsive genes and in the affinity for the ligand, 30% increase in the ability to transrepress the nuclear factor-κB-target genes and a 3,4-fold delay in the cytoplasmic-to-nuclear translocation. The mutant receptor hGRαT556I did not exert a dominant negative effect upon the hGRα-mediated transcriptional activity; it preserved its ability to bind to DNA and interacted with the glucocorticoid receptor-interacting protein 1 coactivator mostly through its activation function-1 domain. Structural biology studies revealed that the T556I mutation caused disruption of the hydrogen bond formed by the T556 with the =O group of P637 backbone, which resulted in a significant relocation of the P637-bearing loop. This conformational alteration affected the local 3D arrangement of the receptor and hence the electrostatic surface of the region.</abstracttext></p> <h4>CONCLUSIONS:</h4> <p><abstracttext label="CONCLUSIONS" nlmcategory="CONCLUSIONS">The hGRαT556I causes Chrousos syndrome by impairing multiple steps of the glucocorticoid signal transduction pathway.</abstracttext></p>', 'date' => '2016-01-01', 'pmid' => 'http://www.ncbi.nlm.nih.gov/pubmed/26541474', 'doi' => ' 10.1111/eci.12563', 'modified' => '2016-06-29 09:41:42', 'created' => '2016-06-29 09:41:42', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '1776', 'name' => 'Perinatal exposure to low-dose bisphenol A affects the neuroendocrine stress response in rats.', 'authors' => 'Panagiotidou E, Zerva S, Mitsiou DJ, Alexis MN, Kitraki E', 'description' => 'Bisphenol A (BPA) is an estrogen-mimicking endocrine disruptor. Early-life exposures to low doses of BPA exert long-lasting effects on animals' reproductive and brain physiology. However, little is known about the effects of BPA on the stress-response system. Given the interaction of sex and stress hormones, we examined the effect of a low perinatal BPA exposure on the function of the hypothalamic-pituitary-adrenal (HPA) axis at rest and upon application of acute stress. Throughout pregnancy and lactation rats received daily 40 μg BPA/kg body weight orally via cornflakes. We studied the effect of this low but chronic exposure to BPA in the male and female offspring at puberty. BPA exposure led to abnormal adrenal histology including reduced zona reticularis especially in male offspring, hyperplasia of zona fasciculata in both sexes, and increased adrenal weight in female offspring. BPA-treated females had increased basal corticosterone and reduced hypothalamic glucocorticoid receptors (GR) levels. Stressed BPA-exposed females exhibited anxiety-like behavioral coping, a less rigorous corticosterone response, and did not downregulate GR in the hypothalamus, compared with control females. BPA-exposed males exhibited a heightened corticosterone stress response compared with females; they also displayed increased pro-opiomelanocortin mRNA levels and retained the prestress levels of pituitary corticotropin-releasing hormone-receptor 1, compared with control males. We found that perinatal chronic exposure to a low dose of BPA perturbs the basal and stress-induced activity of the HPA axis in a sexually dimorphic manner at adolescence. Exposure to BPA might contribute to increased susceptibility to stress-related disorders in later life.', 'date' => '2014-03-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/24323913', 'doi' => '', 'modified' => '2015-07-24 15:39:01', 'created' => '2015-07-24 15:39:01', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '1557', 'name' => 'Pattern of heat shock factor and heat shock protein expression in lymphocytes of bipolar patients: Increased HSP70-glucocorticoid receptor heterocomplex.', 'authors' => 'Bei ES, Salpeas V, Alevizos B, Anagnostara C, Pappa D, Moutsatsou P', 'description' => 'Bipolar disorder (BD), a stress-related disease, is characterized by altered glucocorticoid receptor (GR) signalling. Stress response includes activation of heat shock factor (HSF) and subsequent heat shock protein (HSP) synthesis which regulate GR folding and function. The objective of this study was to investigate the possible role of HSFs, HSPs and their interaction with GR in BD. We applied immunoprecipitation, SDS-PAGE/Western blot analysis and electrophoretic mobility shift assay (EMSA) in lymphocytes (whole cell or nuclear extracts) from BD patients and healthy subjects and determined the HSPs (HSP90 and HSP70), the heterocomplexes HSP90-GR and HSP70-GR, the HSFs (HSF1 and HSF4) as well as the HSF-DNA binding. The HSP70-GR heterocomplex was elevated (p < 0.05) in BD patients vs healthy subjects, and nuclear HSP70 was reduced (p ≤ 0.01) in bipolar manic patients. Protein levels of HSF1, HSF4, HSP90, HSP90-GR heterocomplex, and HSF-DNA binding remained unaltered in BD patients vs healthy subjects. The corresponding effect sizes (ES) indicated a large ES for HSP70-GR, HSP70, HSF-DNA binding and HSF4, and a medium ES for HSP90, HSF1 and HSP90-GR between healthy subjects and bipolar patients. Significant correlations among HSFs, HSPs, GR and HSP70-GR heterocomplex were observed in healthy subjects, which were abrogated in bipolar patients. The higher interaction between GR and HSP70 and the disturbances in the relations among heat shock response parameters and GR as observed in our BD patients may provide novel insights into the contribution of these factors in BD aetiopathogenesis.', 'date' => '2013-11-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/23938235', 'doi' => '', 'modified' => '2015-07-24 15:39:00', 'created' => '2015-07-24 15:39:00', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '253', 'name' => 'Coactivation of GR and NFKB alters the repertoire of their binding sites and target genes.', 'authors' => 'Rao NA, McCalman MT, Moulos P, Francoijs KJ, Chatziioannou A, Kolisis FN, Alexis MN, Mitsiou DJ, Stunnenberg HG', 'description' => 'Glucocorticoid receptor (GR) exerts anti-inflammatory action in part by antagonizing proinflammatory transcription factors such as the nuclear factor kappa-b (NFKB). Here, we assess the crosstalk of activated GR and RELA (p65, major NFKB component) by global identification of their binding sites and target genes. We show that coactivation of GR and p65 alters the repertoire of regulated genes and results in their association with novel sites in a mutually dependent manner. These novel sites predominantly cluster with p65 target genes that are antagonized by activated GR and vice versa. Our data show that coactivation of GR and NFKB alters signaling pathways that are regulated by each factor separately and provide insight into the networks underlying the GR and NFKB crosstalk.', 'date' => '2011-09-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/21750107', 'doi' => '', 'modified' => '2015-07-24 15:38:57', 'created' => '2015-07-24 15:38:57', 'ProductsPublication' => array( [maximum depth reached] ) ) ), 'Testimonial' => array(), 'Area' => array(), 'SafetySheet' => array( (int) 0 => array( 'id' => '568', 'name' => 'GR antibody SDS US en', 'language' => 'en', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-US-en-GHS_2_0.pdf', 'countries' => 'US', 'modified' => '2020-07-01 14:51:26', 'created' => '2020-07-01 14:51:26', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '566', 'name' => 'GR antibody SDS GB en', 'language' => 'en', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-GB-en-GHS_2_0.pdf', 'countries' => 'GB', 'modified' => '2020-07-01 14:50:36', 'created' => '2020-07-01 14:50:36', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '561', 'name' => 'GR antibody SDS BE fr', 'language' => 'fr', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-BE-fr-GHS_2_0.pdf', 'countries' => 'BE', 'modified' => '2020-07-01 14:47:08', 'created' => '2020-07-01 14:47:08', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '565', 'name' => 'GR antibody SDS FR fr', 'language' => 'fr', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-FR-fr-GHS_2_0.pdf', 'countries' => 'FR', 'modified' => '2020-07-01 14:49:58', 'created' => '2020-07-01 14:49:58', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '564', 'name' => 'GR antibody SDS ES es', 'language' => 'es', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-ES-es-GHS_2_0.pdf', 'countries' => 'ES', 'modified' => '2020-07-01 14:49:11', 'created' => '2020-07-01 14:49:11', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '563', 'name' => 'GR antibody SDS DE de', 'language' => 'de', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-DE-de-GHS_2_0.pdf', 'countries' => 'DE', 'modified' => '2020-07-01 14:48:31', 'created' => '2020-07-01 14:48:31', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '567', 'name' => 'GR antibody SDS JP ja', 'language' => 'ja', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-JP-ja-GHS_2_0.pdf', 'countries' => 'JP', 'modified' => '2020-07-01 14:51:01', 'created' => '2020-07-01 14:51:01', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 7 => array( 'id' => '562', 'name' => 'GR antibody SDS BE nl', 'language' => 'nl', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-BE-nl-GHS_2_0.pdf', 'countries' => 'BE', 'modified' => '2020-07-01 14:47:51', 'created' => '2020-07-01 14:47:51', 'ProductsSafetySheet' => array( [maximum depth reached] ) ) ) ) $meta_canonical = 'https://www.diagenode.com/jp/p/gr-monoclonal-antibody-classic-50-ug-50-ul' $country = 'US' $countries_allowed = array( (int) 0 => 'CA', (int) 1 => 'US', (int) 2 => 'IE', (int) 3 => 'GB', (int) 4 => 'DK', (int) 5 => 'NO', (int) 6 => 'SE', (int) 7 => 'FI', (int) 8 => 'NL', (int) 9 => 'BE', (int) 10 => 'LU', (int) 11 => 'FR', (int) 12 => 'DE', (int) 13 => 'CH', (int) 14 => 'AT', (int) 15 => 'ES', (int) 16 => 'IT', (int) 17 => 'PT' ) $outsource = true $other_formats = array( (int) 0 => array( 'id' => '1970', 'antibody_id' => '326', 'name' => 'GR Antibody', 'description' => '<p>Alternative names: <strong>NR3C1</strong>,<strong> GCCR</strong>, <strong>GCR</strong>, <strong>GRL</strong></p> <p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human <strong>GR (glucocorticoid receptor)</strong>, using a chimeric protein.</p>', 'label1' => 'Validation Data', 'info1' => '<div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig1.png" alt="GR Antibody ChIP Grade" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 1. ChIP results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP assays were performed using HeLa cells, the Diagenode monoclonal antibody directed against GR (Cat. No. MAb-010-050) and optimized PCR primer sets for qPCR. The cells were treated either with ethanol (EtOH, used as a negative control) or triamcinolone acetonide (TA) for 4 hours prior to cell harvesting. ChIP was performed using sheared chromatin from 3 million cells and 5 μg of antibody. QPCR was performed with primers for the human metallothionein promoter (hMTIIA) and for exon 2 of the human myoglobin gene (hmyo ex2), used as a negative control. Figure 1 shows the recovery (the relative amount of immunoprecipitated DNA compared to input DNA) and the occupancy (ratio +/- control target). These results demonstrate the occupancy of the human metallothionein IIA promoter by GR. </small></p> </div> </div> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2A.png" alt="GR Antibody ChIP-seq Grade" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2B.png" alt="GR Antibody for ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2C.png" alt="GR Antibody for ChIP-seq assay" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2D.png" alt="GR Antibody validated in ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2E.png" alt="GR Antibody ChIP-seq Grade" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 2. ChIP-seq results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP was performed on sheared chromatin from 3.5 million HeLaB2 cells using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). The cells were treated with the synthetic GR ligand triamcinolone acetonide (TA) for 4 hours prior to harvesting. The IP’d DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer’s instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. Figure 2 shows the peak distribution along the complete sequence of chromosome 16 (figure 2A) as well as the MT2A positive control gene (figure 2B). The position of the PCR amplicon is also indicated. Figure 2C, D and E show the results for the known GR target genes PER1 on chromosome 17 and FKBP5 and TNFAIP3 on chromosome 6. </small></p> </div> </div> <p></p> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig3.png" alt="GR Antibody ELISA Validation" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 3. Sandwich ELISA </strong><br />The specificity of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050) was assessed by sandwich ELISA. Figure 3A: schematic representation of the sandwich ELISA with the monoclonal antibody against hGR (clone #:m2F8). Figure 3B: ELISA results using the monoclonal antibody against hGR at a concentration of 0.5 μg/ml. The figure shows an ELISA signal which is proportionally increasing with increasing amounts of recombinant hGR. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig4.png" alt="GR Antibody validated in Western Blot" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 4. Western blot analysis using the Diagenode monoclonal antibody against hGR </strong><br />Figure 4A. Extracts from HeLa cells containing the indicated amounts of GR (from 30 to 240 fmol), and from 5x10e6 Raji or Molt cells were analysed by Western blot using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). Figure 4B. Western blot analysis of extracts from 300,000 HeLa cells with the Diagenode monoclonal antibody against hGR (concentration 1 μg/ml). </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig5.png" alt="GR Antibody validated in Immunohistochemistry" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig6.png" alt="GR Antibody validated for Immunohistochemistry" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 5. Immunohistochemistry and immunofluorescence using the Diagenode monoclonal antibody against hGR </strong><br />1. Immunoreactivity of the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050) in rat CA1 neurons of hippocampus. The antibody was used at a concentration of 2.5 μg/ml. <br />2. COS-7 cells transiently overexpressing human GR were labeled with the antibody against hGR followed by a biotinylated secondary antibody and peroxidase-labeled avidin. The antibody was used at a concentration of 2.5 μg/ml. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig7.png" alt="GR Antibody validated in Immunoprecipitation" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 6. Immunoprecipitation using the Diagenode monoclonal antibody against hGR </strong><br />The glucocorticoid receptor was immunoprecipitated from HeLa cell extracts (5 million HeLa cells in 100 μl IP reaction solution) using 5 μg of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050). The IP was followed by Western blot analysis as described above </small></p> </div> </div>', 'label2' => 'Target Description', 'info2' => '<p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.</p>', 'label3' => '', 'info3' => '', 'format' => '50 µg', 'catalog_number' => 'C15200010', 'old_catalog_number' => 'MAb-010-050', 'sf_code' => 'C15200010-D001-000581', 'type' => 'FRE', 'search_order' => '03-Antibody', 'price_EUR' => '380', 'price_USD' => '380', 'price_GBP' => '340', 'price_JPY' => '59525', 'price_CNY' => '', 'price_AUD' => '950', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => true, 'last_datasheet_update' => '0000-00-00', 'slug' => 'gr-monoclonal-antibody-classic-50-ug-50-ul', 'meta_title' => 'GR Antibody - ChIP-seq Grade (C15200010) | Diagenode', 'meta_keywords' => '', 'meta_description' => 'GR (Glucocorticoid receptor) Monoclonal Antibody validated in ChIP-seq, ChIP-qPCR, WB, Flow Cyt, IP and ELISA. Batch-specific data available on the website. Alternative names: NR3C1, GCCR, GCR, GRL. Sample size avaialble.', 'modified' => '2024-11-19 16:56:51', 'created' => '2015-06-29 14:08:20' ) ) $pro = array( 'id' => '2893', 'antibody_id' => '326', 'name' => 'GR Antibody (sample size)', 'description' => '<p>Alternative names: <strong>NR3C1, GCCR, GCR, GRL </strong></p> <p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human <strong>GR (glucocorticoid receptor),</strong> using a chimeric protein.</p>', 'label1' => 'Validation data', 'info1' => '', 'label2' => '', 'info2' => '', 'label3' => '', 'info3' => '', 'format' => '10 µg', 'catalog_number' => 'C15200010-10', 'old_catalog_number' => '', 'sf_code' => 'C15200010-D001-000582', 'type' => 'FRE', 'search_order' => '', 'price_EUR' => '105', 'price_USD' => '115', 'price_GBP' => '100', 'price_JPY' => '16450', 'price_CNY' => '', 'price_AUD' => '288', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => false, 'last_datasheet_update' => '', 'slug' => 'gr-monoclonal-antibody-classic-10-ug', 'meta_title' => 'GR Antibody - ChIP-seq Grade (C15200010) | Diagenode', 'meta_keywords' => '', 'meta_description' => 'GR (Glucocorticoid receptor) Monoclonal Antibody validated in ChIP-seq, ChIP-qPCR, WB, IP, and ELISA. Batch-specific data available on the website. Alternative names: NR3C1, GCCR, GCR, GRL. Sample size available.', 'modified' => '2022-01-05 14:49:33', 'created' => '2017-05-17 14:56:35', 'ProductsGroup' => array( 'id' => '234', 'product_id' => '2893', 'group_id' => '209' ) ) $edit = '' $testimonials = '' $featured_testimonials = '' $related_products = '' $rrbs_service = array( (int) 0 => (int) 1894, (int) 1 => (int) 1895 ) $chipseq_service = array( (int) 0 => (int) 2683, (int) 1 => (int) 1835, (int) 2 => (int) 1836, (int) 3 => (int) 2684, (int) 4 => (int) 1838, (int) 5 => (int) 1839, (int) 6 => (int) 1856 ) $labelize = object(Closure) { } $old_catalog_number = ' <span style="color:#CCC">(MAb-010-050)</span>' $country_code = 'US' $other_format = array( 'id' => '1970', 'antibody_id' => '326', 'name' => 'GR Antibody', 'description' => '<p>Alternative names: <strong>NR3C1</strong>,<strong> GCCR</strong>, <strong>GCR</strong>, <strong>GRL</strong></p> <p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human <strong>GR (glucocorticoid receptor)</strong>, using a chimeric protein.</p>', 'label1' => 'Validation Data', 'info1' => '<div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig1.png" alt="GR Antibody ChIP Grade" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 1. ChIP results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP assays were performed using HeLa cells, the Diagenode monoclonal antibody directed against GR (Cat. No. MAb-010-050) and optimized PCR primer sets for qPCR. The cells were treated either with ethanol (EtOH, used as a negative control) or triamcinolone acetonide (TA) for 4 hours prior to cell harvesting. ChIP was performed using sheared chromatin from 3 million cells and 5 μg of antibody. QPCR was performed with primers for the human metallothionein promoter (hMTIIA) and for exon 2 of the human myoglobin gene (hmyo ex2), used as a negative control. Figure 1 shows the recovery (the relative amount of immunoprecipitated DNA compared to input DNA) and the occupancy (ratio +/- control target). These results demonstrate the occupancy of the human metallothionein IIA promoter by GR. </small></p> </div> </div> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2A.png" alt="GR Antibody ChIP-seq Grade" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2B.png" alt="GR Antibody for ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2C.png" alt="GR Antibody for ChIP-seq assay" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2D.png" alt="GR Antibody validated in ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2E.png" alt="GR Antibody ChIP-seq Grade" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 2. ChIP-seq results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP was performed on sheared chromatin from 3.5 million HeLaB2 cells using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). The cells were treated with the synthetic GR ligand triamcinolone acetonide (TA) for 4 hours prior to harvesting. The IP’d DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer’s instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. Figure 2 shows the peak distribution along the complete sequence of chromosome 16 (figure 2A) as well as the MT2A positive control gene (figure 2B). The position of the PCR amplicon is also indicated. Figure 2C, D and E show the results for the known GR target genes PER1 on chromosome 17 and FKBP5 and TNFAIP3 on chromosome 6. </small></p> </div> </div> <p></p> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig3.png" alt="GR Antibody ELISA Validation" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 3. Sandwich ELISA </strong><br />The specificity of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050) was assessed by sandwich ELISA. Figure 3A: schematic representation of the sandwich ELISA with the monoclonal antibody against hGR (clone #:m2F8). Figure 3B: ELISA results using the monoclonal antibody against hGR at a concentration of 0.5 μg/ml. The figure shows an ELISA signal which is proportionally increasing with increasing amounts of recombinant hGR. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig4.png" alt="GR Antibody validated in Western Blot" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 4. Western blot analysis using the Diagenode monoclonal antibody against hGR </strong><br />Figure 4A. Extracts from HeLa cells containing the indicated amounts of GR (from 30 to 240 fmol), and from 5x10e6 Raji or Molt cells were analysed by Western blot using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). Figure 4B. Western blot analysis of extracts from 300,000 HeLa cells with the Diagenode monoclonal antibody against hGR (concentration 1 μg/ml). </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig5.png" alt="GR Antibody validated in Immunohistochemistry" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig6.png" alt="GR Antibody validated for Immunohistochemistry" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 5. Immunohistochemistry and immunofluorescence using the Diagenode monoclonal antibody against hGR </strong><br />1. Immunoreactivity of the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050) in rat CA1 neurons of hippocampus. The antibody was used at a concentration of 2.5 μg/ml. <br />2. 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Here, we assess the crosstalk of activated GR and RELA (p65, major NFKB component) by global identification of their binding sites and target genes. We show that coactivation of GR and p65 alters the repertoire of regulated genes and results in their association with novel sites in a mutually dependent manner. These novel sites predominantly cluster with p65 target genes that are antagonized by activated GR and vice versa. 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ChIP results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP assays were performed using HeLa cells, the Diagenode monoclonal antibody directed against GR (Cat. No. MAb-010-050) and optimized PCR primer sets for qPCR. The cells were treated either with ethanol (EtOH, used as a negative control) or triamcinolone acetonide (TA) for 4 hours prior to cell harvesting. ChIP was performed using sheared chromatin from 3 million cells and 5 μg of antibody. QPCR was performed with primers for the human metallothionein promoter (hMTIIA) and for exon 2 of the human myoglobin gene (hmyo ex2), used as a negative control. Figure 1 shows the recovery (the relative amount of immunoprecipitated DNA compared to input DNA) and the occupancy (ratio +/- control target). These results demonstrate the occupancy of the human metallothionein IIA promoter by GR. </small></p> </div> </div> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2A.png" alt="GR Antibody ChIP-seq Grade" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2B.png" alt="GR Antibody for ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2C.png" alt="GR Antibody for ChIP-seq assay" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2D.png" alt="GR Antibody validated in ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2E.png" alt="GR Antibody ChIP-seq Grade" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 2. ChIP-seq results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP was performed on sheared chromatin from 3.5 million HeLaB2 cells using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). The cells were treated with the synthetic GR ligand triamcinolone acetonide (TA) for 4 hours prior to harvesting. The IP’d DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer’s instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. Figure 2 shows the peak distribution along the complete sequence of chromosome 16 (figure 2A) as well as the MT2A positive control gene (figure 2B). The position of the PCR amplicon is also indicated. Figure 2C, D and E show the results for the known GR target genes PER1 on chromosome 17 and FKBP5 and TNFAIP3 on chromosome 6. </small></p> </div> </div> <p></p> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig3.png" alt="GR Antibody ELISA Validation" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 3. Sandwich ELISA </strong><br />The specificity of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050) was assessed by sandwich ELISA. Figure 3A: schematic representation of the sandwich ELISA with the monoclonal antibody against hGR (clone #:m2F8). Figure 3B: ELISA results using the monoclonal antibody against hGR at a concentration of 0.5 μg/ml. The figure shows an ELISA signal which is proportionally increasing with increasing amounts of recombinant hGR. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig4.png" alt="GR Antibody validated in Western Blot" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 4. Western blot analysis using the Diagenode monoclonal antibody against hGR </strong><br />Figure 4A. Extracts from HeLa cells containing the indicated amounts of GR (from 30 to 240 fmol), and from 5x10e6 Raji or Molt cells were analysed by Western blot using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). Figure 4B. Western blot analysis of extracts from 300,000 HeLa cells with the Diagenode monoclonal antibody against hGR (concentration 1 μg/ml). </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig5.png" alt="GR Antibody validated in Immunohistochemistry" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig6.png" alt="GR Antibody validated for Immunohistochemistry" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 5. Immunohistochemistry and immunofluorescence using the Diagenode monoclonal antibody against hGR </strong><br />1. Immunoreactivity of the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050) in rat CA1 neurons of hippocampus. The antibody was used at a concentration of 2.5 μg/ml. <br />2. 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The IP was followed by Western blot analysis as described above </small></p> </div> </div>', 'label2' => 'Target Description', 'info2' => '<p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.</p>', 'label3' => '', 'info3' => '', 'format' => '10 µg', 'catalog_number' => 'C15200010-10', 'old_catalog_number' => '', 'sf_code' => 'C15200010-D001-000582', 'type' => 'FRE', 'search_order' => '', 'price_EUR' => '105', 'price_USD' => '115', 'price_GBP' => '100', 'price_JPY' => '16450', 'price_CNY' => '', 'price_AUD' => '288', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => false, 'last_datasheet_update' => '', 'slug' => 'gr-monoclonal-antibody-classic-10-ug', 'meta_title' => '', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2022-01-05 14:49:33', 'created' => '2017-05-17 14:56:35', 'locale' => 'jpn' ), 'Antibody' => array( 'host' => '*****', 'id' => '326', 'name' => 'GR monoclonal antibody', 'description' => 'Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.', 'clonality' => '', 'isotype' => '', 'lot' => 'NR-010', 'concentration' => '1.0 µg/µl', 'reactivity' => 'Human, rat', 'type' => 'Monoclonal', 'purity' => 'Ammonium sulphate purified', 'classification' => 'Classic', 'application_table' => '<table> <thead> <tr> <th>Applications</th> <th>Suggested dilution</th> <th>References</th> </tr> </thead> <tbody> <tr> <td>ChIP/ChIP-seq</td> <td>5 μg/ChIP</td> <td>Fig 1, 2</td> </tr> <tr> <td>ELISA</td> <td>0.5 μg/ml</td> <td>Fig 3</td> </tr> <tr> <td>Western Blotting</td> <td>1 μg/ml</td> <td>Fig 4</td> </tr> <tr> <td>Gel Supershift</td> <td>5 μg/ml</td> <td></td> </tr> <tr> <td>Immunochemistry</td> <td>2.5 μg/ml</td> <td>Fig 5, 6</td> </tr> <tr> <td>Flow cytometry</td> <td>0.5 μg/ml</td> <td></td> </tr> <tr> <td>Immunoprecipitation</td> <td>5 μg/IP</td> <td>Fig 7</td> </tr> </tbody> </table> <p></p>', 'storage_conditions' => '', 'storage_buffer' => '', 'precautions' => 'This product is for research use only. Not for use in diagnostic or therapeutic procedures.', 'uniprot_acc' => '', 'slug' => '', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2020-09-18 16:34:22', 'created' => '0000-00-00 00:00:00', 'select_label' => '326 - GR monoclonal antibody (NR-010 - 1.0 µg/µl - Human, rat - Ammonium sulphate purified - Mouse)' ), 'Slave' => array(), 'Group' => array( 'Group' => array( 'id' => '209', 'name' => 'C15200010', 'product_id' => '1970', 'modified' => '2017-05-17 14:57:11', 'created' => '2017-05-17 14:57:11' ), 'Master' => array( 'id' => '1970', 'antibody_id' => '326', 'name' => 'GR Antibody', 'description' => '<p>Alternative names: <strong>NR3C1</strong>,<strong> GCCR</strong>, <strong>GCR</strong>, <strong>GRL</strong></p> <p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human <strong>GR (glucocorticoid receptor)</strong>, using a chimeric protein.</p>', 'label1' => 'Validation Data', 'info1' => '<div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig1.png" alt="GR Antibody ChIP Grade" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 1. ChIP results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP assays were performed using HeLa cells, the Diagenode monoclonal antibody directed against GR (Cat. No. MAb-010-050) and optimized PCR primer sets for qPCR. The cells were treated either with ethanol (EtOH, used as a negative control) or triamcinolone acetonide (TA) for 4 hours prior to cell harvesting. ChIP was performed using sheared chromatin from 3 million cells and 5 μg of antibody. QPCR was performed with primers for the human metallothionein promoter (hMTIIA) and for exon 2 of the human myoglobin gene (hmyo ex2), used as a negative control. Figure 1 shows the recovery (the relative amount of immunoprecipitated DNA compared to input DNA) and the occupancy (ratio +/- control target). These results demonstrate the occupancy of the human metallothionein IIA promoter by GR. </small></p> </div> </div> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2A.png" alt="GR Antibody ChIP-seq Grade" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2B.png" alt="GR Antibody for ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2C.png" alt="GR Antibody for ChIP-seq assay" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2D.png" alt="GR Antibody validated in ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2E.png" alt="GR Antibody ChIP-seq Grade" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 2. ChIP-seq results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP was performed on sheared chromatin from 3.5 million HeLaB2 cells using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). The cells were treated with the synthetic GR ligand triamcinolone acetonide (TA) for 4 hours prior to harvesting. The IP’d DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer’s instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. Figure 2 shows the peak distribution along the complete sequence of chromosome 16 (figure 2A) as well as the MT2A positive control gene (figure 2B). The position of the PCR amplicon is also indicated. Figure 2C, D and E show the results for the known GR target genes PER1 on chromosome 17 and FKBP5 and TNFAIP3 on chromosome 6. </small></p> </div> </div> <p></p> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig3.png" alt="GR Antibody ELISA Validation" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 3. Sandwich ELISA </strong><br />The specificity of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050) was assessed by sandwich ELISA. Figure 3A: schematic representation of the sandwich ELISA with the monoclonal antibody against hGR (clone #:m2F8). Figure 3B: ELISA results using the monoclonal antibody against hGR at a concentration of 0.5 μg/ml. The figure shows an ELISA signal which is proportionally increasing with increasing amounts of recombinant hGR. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig4.png" alt="GR Antibody validated in Western Blot" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 4. Western blot analysis using the Diagenode monoclonal antibody against hGR </strong><br />Figure 4A. Extracts from HeLa cells containing the indicated amounts of GR (from 30 to 240 fmol), and from 5x10e6 Raji or Molt cells were analysed by Western blot using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). Figure 4B. Western blot analysis of extracts from 300,000 HeLa cells with the Diagenode monoclonal antibody against hGR (concentration 1 μg/ml). </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig5.png" alt="GR Antibody validated in Immunohistochemistry" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig6.png" alt="GR Antibody validated for Immunohistochemistry" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 5. Immunohistochemistry and immunofluorescence using the Diagenode monoclonal antibody against hGR </strong><br />1. Immunoreactivity of the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050) in rat CA1 neurons of hippocampus. The antibody was used at a concentration of 2.5 μg/ml. <br />2. COS-7 cells transiently overexpressing human GR were labeled with the antibody against hGR followed by a biotinylated secondary antibody and peroxidase-labeled avidin. The antibody was used at a concentration of 2.5 μg/ml. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig7.png" alt="GR Antibody validated in Immunoprecipitation" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 6. Immunoprecipitation using the Diagenode monoclonal antibody against hGR </strong><br />The glucocorticoid receptor was immunoprecipitated from HeLa cell extracts (5 million HeLa cells in 100 μl IP reaction solution) using 5 μg of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050). The IP was followed by Western blot analysis as described above </small></p> </div> </div>', 'label2' => 'Target Description', 'info2' => '<p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.</p>', 'label3' => '', 'info3' => '', 'format' => '50 µg', 'catalog_number' => 'C15200010', 'old_catalog_number' => 'MAb-010-050', 'sf_code' => 'C15200010-D001-000581', 'type' => 'FRE', 'search_order' => '03-Antibody', 'price_EUR' => '380', 'price_USD' => '380', 'price_GBP' => '340', 'price_JPY' => '59525', 'price_CNY' => '', 'price_AUD' => '950', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => true, 'last_datasheet_update' => '0000-00-00', 'slug' => 'gr-monoclonal-antibody-classic-50-ug-50-ul', 'meta_title' => 'GR Antibody - ChIP-seq Grade (C15200010) | Diagenode', 'meta_keywords' => '', 'meta_description' => 'GR (Glucocorticoid receptor) Monoclonal Antibody validated in ChIP-seq, ChIP-qPCR, WB, Flow Cyt, IP and ELISA. Batch-specific data available on the website. Alternative names: NR3C1, GCCR, GCR, GRL. Sample size avaialble.', 'modified' => '2024-11-19 16:56:51', 'created' => '2015-06-29 14:08:20' ), 'Product' => array( (int) 0 => array( [maximum depth reached] ) ) ), 'Related' => array(), 'Application' => array( (int) 0 => array( 'id' => '42', 'position' => '10', 'parent_id' => '40', 'name' => 'ChIP-seq (ab)', 'description' => '', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'chip-seq-antibodies', 'meta_keywords' => 'Chromatin Immunoprecipitation Sequencing,ChIP-Seq,ChIP-seq grade antibodies,DNA purification,qPCR,Shearing of chromatin', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for ChIP Sequencing applications', 'meta_title' => 'ChIP Sequencing Antibodies (ChIP-Seq) | Diagenode', 'modified' => '2016-01-20 11:06:19', 'created' => '2015-10-20 11:44:45', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '43', 'position' => '10', 'parent_id' => '40', 'name' => 'ChIP-qPCR (ab)', 'description' => '', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'chip-qpcr-antibodies', 'meta_keywords' => 'Chromatin Immunoprecipitation Sequencing,ChIP-Seq,ChIP-seq grade antibodies,DNA purification,qPCR,Shearing of chromatin', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for ChIP-qPCR applications', 'meta_title' => 'ChIP Quantitative PCR Antibodies (ChIP-qPCR) | Diagenode', 'modified' => '2016-01-20 11:30:24', 'created' => '2015-10-20 11:45:36', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '20', 'position' => '10', 'parent_id' => '40', 'name' => 'ELISA', 'description' => '<div class="row"> <div class="small-12 medium-12 large-12 columns">Enzyme-linked immunosorbent assay.</div> </div>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'elisa-antibodies', 'meta_keywords' => ' ELISA Antibodies,Monoclonal antibody, Polyclonal antibody', 'meta_description' => 'Diagenode offers Monoclonal & Polyclonal antibodies for ELISA applications', 'meta_title' => 'ELISA Antibodies - Monoclonal & Polyclonal antibody | Diagenode', 'modified' => '2016-01-13 12:21:41', 'created' => '2014-07-08 08:13:28', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '19', 'position' => '10', 'parent_id' => '40', 'name' => 'WB', 'description' => '<p><strong>Western blot</strong> : The quality of antibodies used in this technique is crucial for correct and specific protein identification. Diagenode offers huge selection of highly sensitive and specific western blot-validated antibodies.</p> <p>Learn more about: <a href="https://www.diagenode.com/applications/western-blot">Loading control, MW marker visualization</a><em>. <br /></em></p> <p><em></em>Check our selection of antibodies validated in Western blot.</p>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'western-blot-antibodies', 'meta_keywords' => ' Western Blot Antibodies ,western blot protocol,Western Blotting Products,Polyclonal antibodies ,monoclonal antibodies ', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for western blot applications', 'meta_title' => ' Western Blot - Monoclonal antibody - Polyclonal antibody | Diagenode', 'modified' => '2016-04-26 12:44:51', 'created' => '2015-01-07 09:20:00', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '30', 'position' => '10', 'parent_id' => '40', 'name' => 'IP', 'description' => '<p>Immunoprecipitation</p>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'immunoprecipitation', 'meta_keywords' => 'Immunoprecipitation,Monoclonal antibody,Polyclonal antibody', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for Immunoprecipitation applications', 'meta_title' => 'Immunoprecipitation - Monoclonal antibody - Polyclonal antibody | Diagenode', 'modified' => '2016-01-13 12:23:07', 'created' => '2015-07-08 13:46:50', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '33', 'position' => '10', 'parent_id' => '40', 'name' => 'GSA', 'description' => '<p><span>Gel Supershift</span></p>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'gel-supershift-assays', 'meta_keywords' => 'GSA,Gel Super Shift Assays,Gel Shift', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for Gel Supershift applications', 'meta_title' => 'Gel Shift/Gel Super Shift Assays - Monoclonal antibody | Diagenode', 'modified' => '2016-01-13 12:24:19', 'created' => '2015-07-08 13:51:58', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '34', 'position' => '10', 'parent_id' => '40', 'name' => 'Flow Cyt', 'description' => '<p>Flow cyt</p>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'flow-cytometry', 'meta_keywords' => 'Flow cytometry,Flow cyt,Monoclonal antibody,GR monoclonal antibody ', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for Flow cytometry applications', 'meta_title' => 'Flow cytometry - Monoclonal antibody | Diagenode', 'modified' => '2016-01-13 12:24:36', 'created' => '2015-07-08 13:53:00', 'ProductsApplication' => array( [maximum depth reached] ) ) ), 'Category' => array( (int) 0 => array( 'id' => '127', 'position' => '10', 'parent_id' => '4', 'name' => 'ChIP-grade antibodies', 'description' => '<div class="row"> <div class="small-12 columns"><center></center> <p><br />Chromatin immunoprecipitation (<b>ChIP</b>) is a technique to study the associations of proteins with the specific genomic regions in intact cells. One of the most important steps of this protocol is the immunoprecipitation of targeted protein using the antibody specifically recognizing it. The quality of antibodies used in ChIP is essential for the success of the experiment. Diagenode offers extensively validated ChIP-grade antibodies, confirmed for their specificity, and high level of performance in ChIP. Each batch is validated, and batch-specific data are available on the website.</p> <p></p> </div> </div> <p><strong>ChIP results</strong> obtained with the antibody directed against H3K4me3 (Cat. No. <a href="../p/h3k4me3-polyclonal-antibody-premium-50-ug-50-ul">C15410003</a>). </p> <div class="row"> <div class="small-12 medium-6 large-6 columns"><img src="https://www.diagenode.com/img/product/antibodies/C15410003-fig1-ChIP.jpg" alt="" width="400" height="315" /> </div> <div class="small-12 medium-6 large-6 columns"> <p></p> <p></p> <p></p> </div> </div> <p></p> <p>Our aim at Diagenode is to offer the largest collection of highly specific <strong>ChIP-grade antibodies</strong>. We add new antibodies monthly. Find your ChIP-grade antibody in the list below and check more information about tested applications, extensive validation data, and product information.</p>', 'no_promo' => false, 'in_menu' => true, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => false, 'is_antibody' => true, 'slug' => 'chip-grade-antibodies', 'cookies_tag_id' => null, 'meta_keywords' => 'ChIP-grade antibodies, polyclonal antibody, monoclonal antibody, Diagenode', 'meta_description' => 'Diagenode Offers Extensively Validated ChIP-Grade Antibodies, Confirmed for their Specificity, and high level of Performance in Chromatin Immunoprecipitation ChIP', 'meta_title' => 'Chromatin immunoprecipitation ChIP-grade antibodies | Diagenode', 'modified' => '2024-11-19 17:27:07', 'created' => '2017-02-14 11:16:04', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ), (int) 1 => array( 'id' => '17', 'position' => '10', 'parent_id' => '4', 'name' => 'ChIP-seq grade antibodies', 'description' => '<p><b>Unparalleled ChIP-Seq results with the most rigorously validated antibodies</b></p> <p><span style="font-weight: 400;">Diagenode provides leading solutions for epigenetic research. Because ChIP-seq is a widely-used technique, we validate our antibodies in ChIP and ChIP-seq experiments (in addition to conventional methods like Western blot, Dot blot, ELISA, and immunofluorescence) to provide the highest quality antibody. We standardize our validation and production to guarantee high product quality without technical bias. Diagenode guarantees ChIP-seq grade antibody performance under our suggested conditions.</span></p> <div class="row"> <div class="small-12 medium-9 large-9 columns"> <p><strong>ChIP-seq profile</strong> of active (H3K4me3 and H3K36me3) and inactive (H3K27me3) marks using Diagenode antibodies.</p> <img src="https://www.diagenode.com/img/categories/antibodies/chip-seq-grade-antibodies.png" /></div> <div class="small-12 medium-3 large-3 columns"> <p><small> ChIP was performed on sheared chromatin from 100,000 K562 cells using iDeal ChIP-seq kit for Histones (cat. No. C01010051) with 1 µg of the Diagenode antibodies against H3K27me3 (cat. No. C15410195) and H3K4me3 (cat. No. C15410003), and 0.5 µg of the antibody against H3K36me3 (cat. No. C15410192). The IP'd DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer's instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. The figure shows the signal distribution along the complete sequence of human chromosome 3, a zoomin to a 10 Mb region and a further zoomin to a 1.5 Mb region. </small></p> </div> </div> <p>Diagenode’s highly validated antibodies:</p> <ul> <li>Highly sensitive and specific</li> <li>Cost-effective (requires less antibody per reaction)</li> <li>Batch-specific data is available on the website</li> <li>Expert technical support</li> <li>Sample sizes available</li> <li>100% satisfaction guarantee</li> </ul>', 'no_promo' => false, 'in_menu' => true, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => false, 'is_antibody' => true, 'slug' => 'chip-seq-grade-antibodies', 'cookies_tag_id' => null, 'meta_keywords' => 'ChIP-seq grade antibodies,polyclonal antibody,WB, ELISA, ChIP-seq (ab), ChIP-qPCR (ab)', 'meta_description' => 'Diagenode Offers Wide Range of Validated ChIP-Seq Grade Antibodies for Unparalleled ChIP-Seq Results', 'meta_title' => 'Chromatin Immunoprecipitation ChIP-Seq Grade Antibodies | Diagenode', 'modified' => '2019-07-03 10:57:22', 'created' => '2015-02-16 02:24:01', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ), (int) 2 => array( 'id' => '103', 'position' => '0', 'parent_id' => '4', 'name' => 'All antibodies', 'description' => '<p><span style="font-weight: 400;">All Diagenode’s antibodies are listed below. Please, use our Quick search field to find the antibody of interest by target name, application, purity.</span></p> <p><span style="font-weight: 400;">Diagenode’s highly validated antibodies:</span></p> <ul> <li>Highly sensitive and specific</li> <li>Cost-effective (requires less antibody per reaction)</li> <li>Batch-specific data is available on the website</li> <li>Expert technical support</li> <li>Sample sizes available</li> <li>100% satisfaction guarantee</li> </ul>', 'no_promo' => false, 'in_menu' => true, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => false, 'is_antibody' => true, 'slug' => 'all-antibodies', 'cookies_tag_id' => null, 'meta_keywords' => 'Antibodies,Premium Antibodies,Classic,Pioneer', 'meta_description' => 'Diagenode Offers Strict quality standards with Rigorous QC and validated Antibodies. Classified based on level of validation for flexibility of Application. Comprehensive selection of histone and non-histone Antibodies', 'meta_title' => 'Diagenode's selection of Antibodies is exclusively dedicated for Epigenetic Research | Diagenode', 'modified' => '2019-07-03 10:55:44', 'created' => '2015-11-02 14:49:22', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ), (int) 3 => array( 'id' => '102', 'position' => '1', 'parent_id' => '4', 'name' => 'Sample size antibodies', 'description' => '<h1><strong>Validated epigenetics antibodies</strong> – care for a sample?<br /> </h1> <p>Diagenode has partnered with leading epigenetics experts and numerous epigenetics consortiums to bring to you a validated and comprehensive collection of epigenetic antibodies. As an expert in epigenetics, we are committed to offering highly-specific antibodies validated for ChIP/ChIP-seq and many other applications. All batch-specific validation data is available on our website.<br /><a href="../categories/antibodies">Read about our expertise in antibody production</a>.</p> <ul> <li><strong>Focused</strong> - Diagenode's selection of antibodies is exclusively dedicated for epigenetic research. <a title="See the full collection." href="../categories/all-antibodies">See the full collection.</a></li> <li><strong>Strict quality standards</strong> with rigorous QC and validation</li> <li><strong>Classified</strong> based on level of validation for flexibility of application</li> </ul> <p>Existing sample sizes are listed below. We will soon expand our collection. Are you looking for a sample size of another antibody? Just <a href="mailto:agnieszka.zelisko@diagenode.com?Subject=Sample%20Size%20Request" target="_top">Contact us</a>.</p>', 'no_promo' => false, 'in_menu' => true, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => true, 'is_antibody' => true, 'slug' => 'sample-size-antibodies', 'cookies_tag_id' => null, 'meta_keywords' => '5-hmC monoclonal antibody,CRISPR/Cas9 polyclonal antibody ,H3K36me3 polyclonal antibody,diagenode', 'meta_description' => 'Diagenode offers sample volume on selected antibodies for researchers to test, validate and provide confidence and flexibility in choosing from our wide range of antibodies ', 'meta_title' => 'Sample-size Antibodies | Diagenode', 'modified' => '2019-07-03 10:57:05', 'created' => '2015-10-27 12:13:34', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ), (int) 4 => array( 'id' => '30', 'position' => '50', 'parent_id' => '4', 'name' => 'Transcription', 'description' => '<p><span style="font-weight: 400;">The list of Diagenode’s highly specific antibodies for transcription studies includes the antibodies against many transcription factors and nuclear receptors. Check the list below to see our targets.</span></p> <p><span style="font-weight: 400;">Diagenode’s highly validated antibodies:</span></p> <ul> <li><span style="font-weight: 400;"> Highly sensitive and specific</span></li> <li><span style="font-weight: 400;"> Cost-effective (requires less antibody per reaction)</span></li> <li><span style="font-weight: 400;"> Batch-specific data is available on the website</span></li> <li><span style="font-weight: 400;"> Expert technical support</span></li> <li><span style="font-weight: 400;"> Sample sizes available</span></li> <li><span style="font-weight: 400;"> 100% satisfaction guarantee</span></li> </ul>', 'no_promo' => false, 'in_menu' => false, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => false, 'is_antibody' => true, 'slug' => 'transcription-factor', 'cookies_tag_id' => null, 'meta_keywords' => ' Transcription factor antibodies,monoclonal antibodies,polyclonal antibodies', 'meta_description' => 'Diagenode offers polyclonal and monoclonal antibodies for Transcription studie', 'meta_title' => 'Transcription factor Antibodies | Diagenode', 'modified' => '2020-07-06 12:59:19', 'created' => '2015-03-12 10:20:08', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ) ), 'Document' => array( (int) 0 => array( 'id' => '11', 'name' => 'Antibodies you can trust', 'description' => '<p style="text-align: justify;"><span>Epigenetic research tools have evolved over time from endpoint PCR to qPCR to the analyses of large sets of genome-wide sequencing data. ChIP sequencing (ChIP-seq) has now become the gold standard method for chromatin studies, given the accuracy and coverage scale of the approach over other methods. Successful ChIP-seq, however, requires a higher level of experimental accuracy and consistency in all steps of ChIP than ever before. Particularly crucial is the quality of ChIP antibodies. </span></p>', 'image_id' => null, 'type' => 'Poster', 'url' => 'files/posters/Antibodies_you_can_trust_Poster.pdf', 'slug' => 'antibodies-you-can-trust-poster', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2015-10-01 20:18:31', 'created' => '2015-07-03 16:05:15', 'ProductsDocument' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '38', 'name' => 'Epigenetic Antibodies Brochure', 'description' => '<p>More than in any other immuoprecipitation assays, quality antibodies are critical tools in many epigenetics experiments. Since 10 years, Diagenode has developed the most stringent quality production available on the market for antibodies exclusively focused on epigenetic uses. All our antibodies have been qualified to work in epigenetic applications.</p>', 'image_id' => null, 'type' => 'Brochure', 'url' => 'files/brochures/Epigenetic_Antibodies_Brochure.pdf', 'slug' => 'epigenetic-antibodies-brochure', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2016-06-15 11:24:06', 'created' => '2015-07-03 16:05:27', 'ProductsDocument' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '440', 'name' => 'Datasheet hGR C15200010', 'description' => '<p>Datasheet description</p>', 'image_id' => null, 'type' => 'Datasheet', 'url' => 'files/products/antibodies/Datasheet_hGR_C15200010.pdf', 'slug' => 'datasheet-hgr-C15200010', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2015-11-20 17:16:18', 'created' => '2015-07-07 11:47:44', 'ProductsDocument' => array( [maximum depth reached] ) ) ), 'Feature' => array(), 'Image' => array( (int) 0 => array( 'id' => '1783', 'name' => 'product/antibodies/chipseq-grade-ab-icon.png', 'alt' => 'ChIP-seq Grade', 'modified' => '2020-11-27 07:04:40', 'created' => '2018-03-15 15:54:09', 'ProductsImage' => array( [maximum depth reached] ) ) ), 'Promotion' => array(), 'Protocol' => array(), 'Publication' => array( (int) 0 => array( 'id' => '4253', 'name' => 'Coordinated glucocorticoid receptor and MAFB action inducestolerogenesis and epigenome remodeling in dendritic cells', 'authors' => 'Morante-Palacios Octavio et al.', 'description' => '<p>Abstract Glucocorticoids (GCs) exert potent anti-inflammatory effects in immune cells through the glucocorticoid receptor (GR). Dendritic cells (DCs), central actors for coordinating immune responses, acquire tolerogenic properties in response to GCs. Tolerogenic DCs (tolDCs) have emerged as a potential treatment for various inflammatory diseases. To date, the underlying cell type-specific regulatory mechanisms orchestrating GC-mediated acquisition of immunosuppressive properties remain poorly understood. In this study, we investigated the transcriptomic and epigenomic remodeling associated with differentiation to DCs in the presence of GCs. Our analysis demonstrates a major role of MAFB in this process, in synergy with GR. GR and MAFB both interact with methylcytosine dioxygenase TET2 and bind to genomic loci that undergo specific demethylation in tolDCs. We also show that the role of MAFB is more extensive, binding to thousands of genomic loci in tolDCs. Finally, MAFB knockdown erases the tolerogenic properties of tolDCs and reverts the specific DNA demethylation and gene upregulation. The preeminent role of MAFB is also demonstrated in vivo for myeloid cells from synovium in rheumatoid arthritis following GC treatment. Our results imply that, once directly activated by GR, MAFB plays a critical role in orchestrating the epigenomic and transcriptomic remodeling that define the tolerogenic phenotype.</p>', 'date' => '2022-01-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/34893889', 'doi' => '10.1093/nar/gkab1182', 'modified' => '2022-05-20 09:44:29', 'created' => '2022-05-19 10:41:50', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '3208', 'name' => 'The Role of S-Palmitoylation of the Human Glucocorticoid Receptor (hGR) in Mediating the Nongenomic Glucocorticoid Actions', 'authors' => 'Nicolaides N. et al.', 'description' => '<p>Background: Many rapid nongenomic glucocorticoid actions are mediated by membrane-bound glucocorticoid receptors (GRs). S-palmitoylation is a lipid post-translational modification that mediates the membrane localization of some steroid receptors. A highly homologous amino acid sequence (663YLCM KTLLL671) is present in the ligand-binding domain of hGRα, suggesting that hGRα might also undergo S-palmitoylation.</p> <p>Aim: To investigate the role of the motif 663YLCMKTLLL671 in membrane localization of the hGRα and in mediating rapid nongenomic glucocorticoid signaling.</p> <p>Methods and Results: We showed that the mutant receptors hGRαY663A, hGRαC665A and hGRαLL670/671AA, and the addition of the palmitoylation inhibitor 2-bromopalmitate did not prevent membrane localization of hGRα and co-localization with caveolin-1, and did not influence the biphasic activation of mitogen-activated protein kinase (MAPK) signaling pathway in the early time points. Finally, the hGRα was not shown to undergo S-palmitoylation.</p> <p>Conclusions: The motif 663YLCMKTLLL671 does not play a role in membrane localization of hGRα and does not mediate the nongenomic glucocorticoid actions.</p>', 'date' => '2017-04-15', 'pmid' => 'http://www.jmolbiochem.com/index.php/JmolBiochem/article/view/199', 'doi' => '', 'modified' => '2017-07-07 16:21:23', 'created' => '2017-07-07 16:21:23', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '2923', 'name' => 'Three Novel Heterozygous Point Mutations of NR3C1 causing Glucocorticoid Resistance', 'authors' => 'Vitellius G et al.', 'description' => '<p>Generalized glucocorticoid resistance is associated with glucocorticoid receptor (GR, NR3C1) mutations. Three novel heterozygous missense NR3C1 mutations (R477S, Y478C and L672P) were identified in patients presenting with adrenal incidentalomas, glucocorticoid excess without Cushing syndrome. Dexamethasone (DXM) binding studies demonstrated that the affinity of GR<sub>R477S</sub> and GR<sub>Y478C</sub> mutants, located in the DNA-binding domain of GR, was similar to wild-type GR (Kd = 2-3 nM). In contrast, GR<sub>L672P</sub> mutant, located in the ligand-binding domain of GR, was unable to bind glucocorticoids and was more sensitive to protein degradation. GR subcellular distribution revealed a marked decrease in DXM-induced nuclear translocation of GR<sub>R477S</sub> and GR<sub>Y478C</sub> mutants, whereas GR<sub>L672P</sub> remained exclusively cytoplasmic. Chromatin immunoprecipitation demonstrated impaired recruitment of DBD mutants onto the regulatory sequence of FKBP5. Transactivation assays disclosed the lack of transcriptional activity of GR<sub>R477S</sub> and GR<sub>L672P</sub> while GR<sub>Y478C</sub> had a reduced transactivation capacity. Three-D modeling indicated that R477S lost two essential hydrogen bonds with DNA, Y478C resulted in altered interaction with surrounding amino-acids, destabilizing DBD, while L672P altered the H8 helix folding, leading to unstructured LBD. This study identifies novel NR3C1 mutations with their molecular consequences on altered GR signaling and suggests that genetic screening of NR3C1 should be conducted in patients with subclinical hypercorticism.</p>', 'date' => '2016-04-27', 'pmid' => 'http://www.ncbi.nlm.nih.gov/pubmed/27120390', 'doi' => '10.1002/humu.23008', 'modified' => '2016-05-13 17:32:26', 'created' => '2016-05-13 17:32:26', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '2967', 'name' => 'Functional characterization of the hGRαT556I causing Chrousos syndrome', 'authors' => 'Nicolaides NC et al.', 'description' => '<h4>BACKGROUND:</h4> <p><abstracttext label="BACKGROUND" nlmcategory="BACKGROUND">Chrousos syndrome is a rare pathologic condition characterized by generalized, partial resistance of target tissues to glucocorticoids and caused by inactivating mutations of the human glucocorticoid receptor (hGR) gene. A novel case of Chrousos syndrome has been reported in a patient with adrenal incidentaloma, who harboured a heterozygous point mutation in the hGR gene, which resulted in threonine (T) to isoleucine (I) substitution at amino acid position 556 in the ligand-binding domain of the receptor.</abstracttext></p> <h4>OBJECTIVE:</h4> <p><abstracttext label="OBJECTIVE" nlmcategory="OBJECTIVE">To delineate the molecular mechanisms through which the mutant receptor hGRαT556I causes Chrousos syndrome.</abstracttext></p> <h4>DESIGN AND RESULTS:</h4> <p><abstracttext label="DESIGN AND RESULTS" nlmcategory="RESULTS">Compared with the wild-type receptor, the mutant receptor hGRαT556I demonstrated 50% reduction in its ability to transactivate glucocorticoid-responsive genes and in the affinity for the ligand, 30% increase in the ability to transrepress the nuclear factor-κB-target genes and a 3,4-fold delay in the cytoplasmic-to-nuclear translocation. The mutant receptor hGRαT556I did not exert a dominant negative effect upon the hGRα-mediated transcriptional activity; it preserved its ability to bind to DNA and interacted with the glucocorticoid receptor-interacting protein 1 coactivator mostly through its activation function-1 domain. Structural biology studies revealed that the T556I mutation caused disruption of the hydrogen bond formed by the T556 with the =O group of P637 backbone, which resulted in a significant relocation of the P637-bearing loop. This conformational alteration affected the local 3D arrangement of the receptor and hence the electrostatic surface of the region.</abstracttext></p> <h4>CONCLUSIONS:</h4> <p><abstracttext label="CONCLUSIONS" nlmcategory="CONCLUSIONS">The hGRαT556I causes Chrousos syndrome by impairing multiple steps of the glucocorticoid signal transduction pathway.</abstracttext></p>', 'date' => '2016-01-01', 'pmid' => 'http://www.ncbi.nlm.nih.gov/pubmed/26541474', 'doi' => ' 10.1111/eci.12563', 'modified' => '2016-06-29 09:41:42', 'created' => '2016-06-29 09:41:42', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '1776', 'name' => 'Perinatal exposure to low-dose bisphenol A affects the neuroendocrine stress response in rats.', 'authors' => 'Panagiotidou E, Zerva S, Mitsiou DJ, Alexis MN, Kitraki E', 'description' => 'Bisphenol A (BPA) is an estrogen-mimicking endocrine disruptor. Early-life exposures to low doses of BPA exert long-lasting effects on animals' reproductive and brain physiology. However, little is known about the effects of BPA on the stress-response system. Given the interaction of sex and stress hormones, we examined the effect of a low perinatal BPA exposure on the function of the hypothalamic-pituitary-adrenal (HPA) axis at rest and upon application of acute stress. Throughout pregnancy and lactation rats received daily 40 μg BPA/kg body weight orally via cornflakes. We studied the effect of this low but chronic exposure to BPA in the male and female offspring at puberty. BPA exposure led to abnormal adrenal histology including reduced zona reticularis especially in male offspring, hyperplasia of zona fasciculata in both sexes, and increased adrenal weight in female offspring. BPA-treated females had increased basal corticosterone and reduced hypothalamic glucocorticoid receptors (GR) levels. Stressed BPA-exposed females exhibited anxiety-like behavioral coping, a less rigorous corticosterone response, and did not downregulate GR in the hypothalamus, compared with control females. BPA-exposed males exhibited a heightened corticosterone stress response compared with females; they also displayed increased pro-opiomelanocortin mRNA levels and retained the prestress levels of pituitary corticotropin-releasing hormone-receptor 1, compared with control males. We found that perinatal chronic exposure to a low dose of BPA perturbs the basal and stress-induced activity of the HPA axis in a sexually dimorphic manner at adolescence. Exposure to BPA might contribute to increased susceptibility to stress-related disorders in later life.', 'date' => '2014-03-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/24323913', 'doi' => '', 'modified' => '2015-07-24 15:39:01', 'created' => '2015-07-24 15:39:01', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '1557', 'name' => 'Pattern of heat shock factor and heat shock protein expression in lymphocytes of bipolar patients: Increased HSP70-glucocorticoid receptor heterocomplex.', 'authors' => 'Bei ES, Salpeas V, Alevizos B, Anagnostara C, Pappa D, Moutsatsou P', 'description' => 'Bipolar disorder (BD), a stress-related disease, is characterized by altered glucocorticoid receptor (GR) signalling. Stress response includes activation of heat shock factor (HSF) and subsequent heat shock protein (HSP) synthesis which regulate GR folding and function. The objective of this study was to investigate the possible role of HSFs, HSPs and their interaction with GR in BD. We applied immunoprecipitation, SDS-PAGE/Western blot analysis and electrophoretic mobility shift assay (EMSA) in lymphocytes (whole cell or nuclear extracts) from BD patients and healthy subjects and determined the HSPs (HSP90 and HSP70), the heterocomplexes HSP90-GR and HSP70-GR, the HSFs (HSF1 and HSF4) as well as the HSF-DNA binding. The HSP70-GR heterocomplex was elevated (p < 0.05) in BD patients vs healthy subjects, and nuclear HSP70 was reduced (p ≤ 0.01) in bipolar manic patients. Protein levels of HSF1, HSF4, HSP90, HSP90-GR heterocomplex, and HSF-DNA binding remained unaltered in BD patients vs healthy subjects. The corresponding effect sizes (ES) indicated a large ES for HSP70-GR, HSP70, HSF-DNA binding and HSF4, and a medium ES for HSP90, HSF1 and HSP90-GR between healthy subjects and bipolar patients. Significant correlations among HSFs, HSPs, GR and HSP70-GR heterocomplex were observed in healthy subjects, which were abrogated in bipolar patients. The higher interaction between GR and HSP70 and the disturbances in the relations among heat shock response parameters and GR as observed in our BD patients may provide novel insights into the contribution of these factors in BD aetiopathogenesis.', 'date' => '2013-11-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/23938235', 'doi' => '', 'modified' => '2015-07-24 15:39:00', 'created' => '2015-07-24 15:39:00', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '253', 'name' => 'Coactivation of GR and NFKB alters the repertoire of their binding sites and target genes.', 'authors' => 'Rao NA, McCalman MT, Moulos P, Francoijs KJ, Chatziioannou A, Kolisis FN, Alexis MN, Mitsiou DJ, Stunnenberg HG', 'description' => 'Glucocorticoid receptor (GR) exerts anti-inflammatory action in part by antagonizing proinflammatory transcription factors such as the nuclear factor kappa-b (NFKB). Here, we assess the crosstalk of activated GR and RELA (p65, major NFKB component) by global identification of their binding sites and target genes. We show that coactivation of GR and p65 alters the repertoire of regulated genes and results in their association with novel sites in a mutually dependent manner. These novel sites predominantly cluster with p65 target genes that are antagonized by activated GR and vice versa. Our data show that coactivation of GR and NFKB alters signaling pathways that are regulated by each factor separately and provide insight into the networks underlying the GR and NFKB crosstalk.', 'date' => '2011-09-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/21750107', 'doi' => '', 'modified' => '2015-07-24 15:38:57', 'created' => '2015-07-24 15:38:57', 'ProductsPublication' => array( [maximum depth reached] ) ) ), 'Testimonial' => array(), 'Area' => array(), 'SafetySheet' => array( (int) 0 => array( 'id' => '568', 'name' => 'GR antibody SDS US en', 'language' => 'en', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-US-en-GHS_2_0.pdf', 'countries' => 'US', 'modified' => '2020-07-01 14:51:26', 'created' => '2020-07-01 14:51:26', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '566', 'name' => 'GR antibody SDS GB en', 'language' => 'en', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-GB-en-GHS_2_0.pdf', 'countries' => 'GB', 'modified' => '2020-07-01 14:50:36', 'created' => '2020-07-01 14:50:36', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '561', 'name' => 'GR antibody SDS BE fr', 'language' => 'fr', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-BE-fr-GHS_2_0.pdf', 'countries' => 'BE', 'modified' => '2020-07-01 14:47:08', 'created' => '2020-07-01 14:47:08', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '565', 'name' => 'GR antibody SDS FR fr', 'language' => 'fr', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-FR-fr-GHS_2_0.pdf', 'countries' => 'FR', 'modified' => '2020-07-01 14:49:58', 'created' => '2020-07-01 14:49:58', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '564', 'name' => 'GR antibody SDS ES es', 'language' => 'es', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-ES-es-GHS_2_0.pdf', 'countries' => 'ES', 'modified' => '2020-07-01 14:49:11', 'created' => '2020-07-01 14:49:11', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '563', 'name' => 'GR antibody SDS DE de', 'language' => 'de', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-DE-de-GHS_2_0.pdf', 'countries' => 'DE', 'modified' => '2020-07-01 14:48:31', 'created' => '2020-07-01 14:48:31', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '567', 'name' => 'GR antibody SDS JP ja', 'language' => 'ja', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-JP-ja-GHS_2_0.pdf', 'countries' => 'JP', 'modified' => '2020-07-01 14:51:01', 'created' => '2020-07-01 14:51:01', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 7 => array( 'id' => '562', 'name' => 'GR antibody SDS BE nl', 'language' => 'nl', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-BE-nl-GHS_2_0.pdf', 'countries' => 'BE', 'modified' => '2020-07-01 14:47:51', 'created' => '2020-07-01 14:47:51', 'ProductsSafetySheet' => array( [maximum depth reached] ) ) ) ) $meta_canonical = 'https://www.diagenode.com/jp/p/gr-monoclonal-antibody-classic-50-ug-50-ul' $country = 'US' $countries_allowed = array( (int) 0 => 'CA', (int) 1 => 'US', (int) 2 => 'IE', (int) 3 => 'GB', (int) 4 => 'DK', (int) 5 => 'NO', (int) 6 => 'SE', (int) 7 => 'FI', (int) 8 => 'NL', (int) 9 => 'BE', (int) 10 => 'LU', (int) 11 => 'FR', (int) 12 => 'DE', (int) 13 => 'CH', (int) 14 => 'AT', (int) 15 => 'ES', (int) 16 => 'IT', (int) 17 => 'PT' ) $outsource = true $other_formats = array( (int) 0 => array( 'id' => '1970', 'antibody_id' => '326', 'name' => 'GR Antibody', 'description' => '<p>Alternative names: <strong>NR3C1</strong>,<strong> GCCR</strong>, <strong>GCR</strong>, <strong>GRL</strong></p> <p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human <strong>GR (glucocorticoid receptor)</strong>, using a chimeric protein.</p>', 'label1' => 'Validation Data', 'info1' => '<div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig1.png" alt="GR Antibody ChIP Grade" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 1. ChIP results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP assays were performed using HeLa cells, the Diagenode monoclonal antibody directed against GR (Cat. No. MAb-010-050) and optimized PCR primer sets for qPCR. The cells were treated either with ethanol (EtOH, used as a negative control) or triamcinolone acetonide (TA) for 4 hours prior to cell harvesting. ChIP was performed using sheared chromatin from 3 million cells and 5 μg of antibody. QPCR was performed with primers for the human metallothionein promoter (hMTIIA) and for exon 2 of the human myoglobin gene (hmyo ex2), used as a negative control. Figure 1 shows the recovery (the relative amount of immunoprecipitated DNA compared to input DNA) and the occupancy (ratio +/- control target). These results demonstrate the occupancy of the human metallothionein IIA promoter by GR. </small></p> </div> </div> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2A.png" alt="GR Antibody ChIP-seq Grade" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2B.png" alt="GR Antibody for ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2C.png" alt="GR Antibody for ChIP-seq assay" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2D.png" alt="GR Antibody validated in ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2E.png" alt="GR Antibody ChIP-seq Grade" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 2. ChIP-seq results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP was performed on sheared chromatin from 3.5 million HeLaB2 cells using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). The cells were treated with the synthetic GR ligand triamcinolone acetonide (TA) for 4 hours prior to harvesting. The IP’d DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer’s instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. Figure 2 shows the peak distribution along the complete sequence of chromosome 16 (figure 2A) as well as the MT2A positive control gene (figure 2B). The position of the PCR amplicon is also indicated. Figure 2C, D and E show the results for the known GR target genes PER1 on chromosome 17 and FKBP5 and TNFAIP3 on chromosome 6. </small></p> </div> </div> <p></p> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig3.png" alt="GR Antibody ELISA Validation" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 3. Sandwich ELISA </strong><br />The specificity of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050) was assessed by sandwich ELISA. Figure 3A: schematic representation of the sandwich ELISA with the monoclonal antibody against hGR (clone #:m2F8). Figure 3B: ELISA results using the monoclonal antibody against hGR at a concentration of 0.5 μg/ml. The figure shows an ELISA signal which is proportionally increasing with increasing amounts of recombinant hGR. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig4.png" alt="GR Antibody validated in Western Blot" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 4. Western blot analysis using the Diagenode monoclonal antibody against hGR </strong><br />Figure 4A. Extracts from HeLa cells containing the indicated amounts of GR (from 30 to 240 fmol), and from 5x10e6 Raji or Molt cells were analysed by Western blot using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). Figure 4B. Western blot analysis of extracts from 300,000 HeLa cells with the Diagenode monoclonal antibody against hGR (concentration 1 μg/ml). </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig5.png" alt="GR Antibody validated in Immunohistochemistry" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig6.png" alt="GR Antibody validated for Immunohistochemistry" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 5. Immunohistochemistry and immunofluorescence using the Diagenode monoclonal antibody against hGR </strong><br />1. Immunoreactivity of the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050) in rat CA1 neurons of hippocampus. The antibody was used at a concentration of 2.5 μg/ml. <br />2. COS-7 cells transiently overexpressing human GR were labeled with the antibody against hGR followed by a biotinylated secondary antibody and peroxidase-labeled avidin. The antibody was used at a concentration of 2.5 μg/ml. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig7.png" alt="GR Antibody validated in Immunoprecipitation" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 6. Immunoprecipitation using the Diagenode monoclonal antibody against hGR </strong><br />The glucocorticoid receptor was immunoprecipitated from HeLa cell extracts (5 million HeLa cells in 100 μl IP reaction solution) using 5 μg of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050). The IP was followed by Western blot analysis as described above </small></p> </div> </div>', 'label2' => 'Target Description', 'info2' => '<p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.</p>', 'label3' => '', 'info3' => '', 'format' => '50 µg', 'catalog_number' => 'C15200010', 'old_catalog_number' => 'MAb-010-050', 'sf_code' => 'C15200010-D001-000581', 'type' => 'FRE', 'search_order' => '03-Antibody', 'price_EUR' => '380', 'price_USD' => '380', 'price_GBP' => '340', 'price_JPY' => '59525', 'price_CNY' => '', 'price_AUD' => '950', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => true, 'last_datasheet_update' => '0000-00-00', 'slug' => 'gr-monoclonal-antibody-classic-50-ug-50-ul', 'meta_title' => 'GR Antibody - ChIP-seq Grade (C15200010) | Diagenode', 'meta_keywords' => '', 'meta_description' => 'GR (Glucocorticoid receptor) Monoclonal Antibody validated in ChIP-seq, ChIP-qPCR, WB, Flow Cyt, IP and ELISA. Batch-specific data available on the website. Alternative names: NR3C1, GCCR, GCR, GRL. Sample size avaialble.', 'modified' => '2024-11-19 16:56:51', 'created' => '2015-06-29 14:08:20' ) ) $pro = array( 'id' => '2893', 'antibody_id' => '326', 'name' => 'GR Antibody (sample size)', 'description' => '<p>Alternative names: <strong>NR3C1, GCCR, GCR, GRL </strong></p> <p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human <strong>GR (glucocorticoid receptor),</strong> using a chimeric protein.</p>', 'label1' => 'Validation data', 'info1' => '', 'label2' => '', 'info2' => '', 'label3' => '', 'info3' => '', 'format' => '10 µg', 'catalog_number' => 'C15200010-10', 'old_catalog_number' => '', 'sf_code' => 'C15200010-D001-000582', 'type' => 'FRE', 'search_order' => '', 'price_EUR' => '105', 'price_USD' => '115', 'price_GBP' => '100', 'price_JPY' => '16450', 'price_CNY' => '', 'price_AUD' => '288', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => false, 'last_datasheet_update' => '', 'slug' => 'gr-monoclonal-antibody-classic-10-ug', 'meta_title' => 'GR Antibody - ChIP-seq Grade (C15200010) | Diagenode', 'meta_keywords' => '', 'meta_description' => 'GR (Glucocorticoid receptor) Monoclonal Antibody validated in ChIP-seq, ChIP-qPCR, WB, IP, and ELISA. Batch-specific data available on the website. Alternative names: NR3C1, GCCR, GCR, GRL. Sample size available.', 'modified' => '2022-01-05 14:49:33', 'created' => '2017-05-17 14:56:35', 'ProductsGroup' => array( 'id' => '234', 'product_id' => '2893', 'group_id' => '209' ) ) $edit = '' $testimonials = '' $featured_testimonials = '' $related_products = '' $rrbs_service = array( (int) 0 => (int) 1894, (int) 1 => (int) 1895 ) $chipseq_service = array( (int) 0 => (int) 2683, (int) 1 => (int) 1835, (int) 2 => (int) 1836, (int) 3 => (int) 2684, (int) 4 => (int) 1838, (int) 5 => (int) 1839, (int) 6 => (int) 1856 ) $labelize = object(Closure) { } $old_catalog_number = ' <span style="color:#CCC">(MAb-010-050)</span>' $country_code = 'US' $other_format = array( 'id' => '1970', 'antibody_id' => '326', 'name' => 'GR Antibody', 'description' => '<p>Alternative names: <strong>NR3C1</strong>,<strong> GCCR</strong>, <strong>GCR</strong>, <strong>GRL</strong></p> <p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human <strong>GR (glucocorticoid receptor)</strong>, using a chimeric protein.</p>', 'label1' => 'Validation Data', 'info1' => '<div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig1.png" alt="GR Antibody ChIP Grade" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 1. ChIP results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP assays were performed using HeLa cells, the Diagenode monoclonal antibody directed against GR (Cat. No. MAb-010-050) and optimized PCR primer sets for qPCR. The cells were treated either with ethanol (EtOH, used as a negative control) or triamcinolone acetonide (TA) for 4 hours prior to cell harvesting. ChIP was performed using sheared chromatin from 3 million cells and 5 μg of antibody. QPCR was performed with primers for the human metallothionein promoter (hMTIIA) and for exon 2 of the human myoglobin gene (hmyo ex2), used as a negative control. Figure 1 shows the recovery (the relative amount of immunoprecipitated DNA compared to input DNA) and the occupancy (ratio +/- control target). These results demonstrate the occupancy of the human metallothionein IIA promoter by GR. </small></p> </div> </div> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2A.png" alt="GR Antibody ChIP-seq Grade" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2B.png" alt="GR Antibody for ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2C.png" alt="GR Antibody for ChIP-seq assay" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2D.png" alt="GR Antibody validated in ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2E.png" alt="GR Antibody ChIP-seq Grade" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 2. ChIP-seq results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP was performed on sheared chromatin from 3.5 million HeLaB2 cells using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). The cells were treated with the synthetic GR ligand triamcinolone acetonide (TA) for 4 hours prior to harvesting. The IP’d DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer’s instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. Figure 2 shows the peak distribution along the complete sequence of chromosome 16 (figure 2A) as well as the MT2A positive control gene (figure 2B). The position of the PCR amplicon is also indicated. Figure 2C, D and E show the results for the known GR target genes PER1 on chromosome 17 and FKBP5 and TNFAIP3 on chromosome 6. </small></p> </div> </div> <p></p> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig3.png" alt="GR Antibody ELISA Validation" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 3. Sandwich ELISA </strong><br />The specificity of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050) was assessed by sandwich ELISA. Figure 3A: schematic representation of the sandwich ELISA with the monoclonal antibody against hGR (clone #:m2F8). Figure 3B: ELISA results using the monoclonal antibody against hGR at a concentration of 0.5 μg/ml. The figure shows an ELISA signal which is proportionally increasing with increasing amounts of recombinant hGR. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig4.png" alt="GR Antibody validated in Western Blot" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 4. Western blot analysis using the Diagenode monoclonal antibody against hGR </strong><br />Figure 4A. Extracts from HeLa cells containing the indicated amounts of GR (from 30 to 240 fmol), and from 5x10e6 Raji or Molt cells were analysed by Western blot using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). Figure 4B. Western blot analysis of extracts from 300,000 HeLa cells with the Diagenode monoclonal antibody against hGR (concentration 1 μg/ml). </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig5.png" alt="GR Antibody validated in Immunohistochemistry" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig6.png" alt="GR Antibody validated for Immunohistochemistry" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 5. Immunohistochemistry and immunofluorescence using the Diagenode monoclonal antibody against hGR </strong><br />1. Immunoreactivity of the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050) in rat CA1 neurons of hippocampus. The antibody was used at a concentration of 2.5 μg/ml. <br />2. COS-7 cells transiently overexpressing human GR were labeled with the antibody against hGR followed by a biotinylated secondary antibody and peroxidase-labeled avidin. The antibody was used at a concentration of 2.5 μg/ml. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig7.png" alt="GR Antibody validated in Immunoprecipitation" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 6. Immunoprecipitation using the Diagenode monoclonal antibody against hGR </strong><br />The glucocorticoid receptor was immunoprecipitated from HeLa cell extracts (5 million HeLa cells in 100 μl IP reaction solution) using 5 μg of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050). The IP was followed by Western blot analysis as described above </small></p> </div> </div>', 'label2' => 'Target Description', 'info2' => '<p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.</p>', 'label3' => '', 'info3' => '', 'format' => '50 µg', 'catalog_number' => 'C15200010', 'old_catalog_number' => 'MAb-010-050', 'sf_code' => 'C15200010-D001-000581', 'type' => 'FRE', 'search_order' => '03-Antibody', 'price_EUR' => '380', 'price_USD' => '380', 'price_GBP' => '340', 'price_JPY' => '59525', 'price_CNY' => '', 'price_AUD' => '950', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => true, 'last_datasheet_update' => '0000-00-00', 'slug' => 'gr-monoclonal-antibody-classic-50-ug-50-ul', 'meta_title' => 'GR Antibody - ChIP-seq Grade (C15200010) | Diagenode', 'meta_keywords' => '', 'meta_description' => 'GR (Glucocorticoid receptor) Monoclonal Antibody validated in ChIP-seq, ChIP-qPCR, WB, Flow Cyt, IP and ELISA. 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Here, we assess the crosstalk of activated GR and RELA (p65, major NFKB component) by global identification of their binding sites and target genes. We show that coactivation of GR and p65 alters the repertoire of regulated genes and results in their association with novel sites in a mutually dependent manner. These novel sites predominantly cluster with p65 target genes that are antagonized by activated GR and vice versa. Our data show that coactivation of GR and NFKB alters signaling pathways that are regulated by each factor separately and provide insight into the networks underlying the GR and NFKB crosstalk.', 'date' => '2011-09-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/21750107', 'doi' => '', 'modified' => '2015-07-24 15:38:57', 'created' => '2015-07-24 15:38:57', 'ProductsPublication' => array( 'id' => '2027', 'product_id' => '2893', 'publication_id' => '253' ) ) $externalLink = ' <a href="https://www.ncbi.nlm.nih.gov/pubmed/21750107" target="_blank"><i class="fa fa-external-link"></i></a>'include - APP/View/Products/view.ctp, line 755 View::_evaluate() - CORE/Cake/View/View.php, line 971 View::_render() - CORE/Cake/View/View.php, line 933 View::render() - CORE/Cake/View/View.php, line 473 Controller::render() - CORE/Cake/Controller/Controller.php, line 963 ProductsController::slug() - APP/Controller/ProductsController.php, line 1052 ReflectionMethod::invokeArgs() - [internal], line ?? 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ChIP results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP assays were performed using HeLa cells, the Diagenode monoclonal antibody directed against GR (Cat. No. MAb-010-050) and optimized PCR primer sets for qPCR. The cells were treated either with ethanol (EtOH, used as a negative control) or triamcinolone acetonide (TA) for 4 hours prior to cell harvesting. ChIP was performed using sheared chromatin from 3 million cells and 5 μg of antibody. QPCR was performed with primers for the human metallothionein promoter (hMTIIA) and for exon 2 of the human myoglobin gene (hmyo ex2), used as a negative control. Figure 1 shows the recovery (the relative amount of immunoprecipitated DNA compared to input DNA) and the occupancy (ratio +/- control target). These results demonstrate the occupancy of the human metallothionein IIA promoter by GR. </small></p> </div> </div> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2A.png" alt="GR Antibody ChIP-seq Grade" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2B.png" alt="GR Antibody for ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2C.png" alt="GR Antibody for ChIP-seq assay" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2D.png" alt="GR Antibody validated in ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2E.png" alt="GR Antibody ChIP-seq Grade" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 2. ChIP-seq results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP was performed on sheared chromatin from 3.5 million HeLaB2 cells using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). The cells were treated with the synthetic GR ligand triamcinolone acetonide (TA) for 4 hours prior to harvesting. The IP’d DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer’s instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. Figure 2 shows the peak distribution along the complete sequence of chromosome 16 (figure 2A) as well as the MT2A positive control gene (figure 2B). The position of the PCR amplicon is also indicated. Figure 2C, D and E show the results for the known GR target genes PER1 on chromosome 17 and FKBP5 and TNFAIP3 on chromosome 6. </small></p> </div> </div> <p></p> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig3.png" alt="GR Antibody ELISA Validation" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 3. Sandwich ELISA </strong><br />The specificity of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050) was assessed by sandwich ELISA. Figure 3A: schematic representation of the sandwich ELISA with the monoclonal antibody against hGR (clone #:m2F8). Figure 3B: ELISA results using the monoclonal antibody against hGR at a concentration of 0.5 μg/ml. The figure shows an ELISA signal which is proportionally increasing with increasing amounts of recombinant hGR. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig4.png" alt="GR Antibody validated in Western Blot" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 4. Western blot analysis using the Diagenode monoclonal antibody against hGR </strong><br />Figure 4A. Extracts from HeLa cells containing the indicated amounts of GR (from 30 to 240 fmol), and from 5x10e6 Raji or Molt cells were analysed by Western blot using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). Figure 4B. Western blot analysis of extracts from 300,000 HeLa cells with the Diagenode monoclonal antibody against hGR (concentration 1 μg/ml). </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig5.png" alt="GR Antibody validated in Immunohistochemistry" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig6.png" alt="GR Antibody validated for Immunohistochemistry" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 5. Immunohistochemistry and immunofluorescence using the Diagenode monoclonal antibody against hGR </strong><br />1. Immunoreactivity of the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050) in rat CA1 neurons of hippocampus. The antibody was used at a concentration of 2.5 μg/ml. <br />2. COS-7 cells transiently overexpressing human GR were labeled with the antibody against hGR followed by a biotinylated secondary antibody and peroxidase-labeled avidin. The antibody was used at a concentration of 2.5 μg/ml. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig7.png" alt="GR Antibody validated in Immunoprecipitation" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 6. Immunoprecipitation using the Diagenode monoclonal antibody against hGR </strong><br />The glucocorticoid receptor was immunoprecipitated from HeLa cell extracts (5 million HeLa cells in 100 μl IP reaction solution) using 5 μg of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050). The IP was followed by Western blot analysis as described above </small></p> </div> </div>', 'label2' => 'Target Description', 'info2' => '<p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.</p>', 'label3' => '', 'info3' => '', 'format' => '10 µg', 'catalog_number' => 'C15200010-10', 'old_catalog_number' => '', 'sf_code' => 'C15200010-D001-000582', 'type' => 'FRE', 'search_order' => '', 'price_EUR' => '105', 'price_USD' => '115', 'price_GBP' => '100', 'price_JPY' => '16450', 'price_CNY' => '', 'price_AUD' => '288', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => false, 'last_datasheet_update' => '', 'slug' => 'gr-monoclonal-antibody-classic-10-ug', 'meta_title' => '', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2022-01-05 14:49:33', 'created' => '2017-05-17 14:56:35', 'locale' => 'jpn' ), 'Antibody' => array( 'host' => '*****', 'id' => '326', 'name' => 'GR monoclonal antibody', 'description' => 'Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.', 'clonality' => '', 'isotype' => '', 'lot' => 'NR-010', 'concentration' => '1.0 µg/µl', 'reactivity' => 'Human, rat', 'type' => 'Monoclonal', 'purity' => 'Ammonium sulphate purified', 'classification' => 'Classic', 'application_table' => '<table> <thead> <tr> <th>Applications</th> <th>Suggested dilution</th> <th>References</th> </tr> </thead> <tbody> <tr> <td>ChIP/ChIP-seq</td> <td>5 μg/ChIP</td> <td>Fig 1, 2</td> </tr> <tr> <td>ELISA</td> <td>0.5 μg/ml</td> <td>Fig 3</td> </tr> <tr> <td>Western Blotting</td> <td>1 μg/ml</td> <td>Fig 4</td> </tr> <tr> <td>Gel Supershift</td> <td>5 μg/ml</td> <td></td> </tr> <tr> <td>Immunochemistry</td> <td>2.5 μg/ml</td> <td>Fig 5, 6</td> </tr> <tr> <td>Flow cytometry</td> <td>0.5 μg/ml</td> <td></td> </tr> <tr> <td>Immunoprecipitation</td> <td>5 μg/IP</td> <td>Fig 7</td> </tr> </tbody> </table> <p></p>', 'storage_conditions' => '', 'storage_buffer' => '', 'precautions' => 'This product is for research use only. Not for use in diagnostic or therapeutic procedures.', 'uniprot_acc' => '', 'slug' => '', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2020-09-18 16:34:22', 'created' => '0000-00-00 00:00:00', 'select_label' => '326 - GR monoclonal antibody (NR-010 - 1.0 µg/µl - Human, rat - Ammonium sulphate purified - Mouse)' ), 'Slave' => array(), 'Group' => array( 'Group' => array( 'id' => '209', 'name' => 'C15200010', 'product_id' => '1970', 'modified' => '2017-05-17 14:57:11', 'created' => '2017-05-17 14:57:11' ), 'Master' => array( 'id' => '1970', 'antibody_id' => '326', 'name' => 'GR Antibody', 'description' => '<p>Alternative names: <strong>NR3C1</strong>,<strong> GCCR</strong>, <strong>GCR</strong>, <strong>GRL</strong></p> <p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human <strong>GR (glucocorticoid receptor)</strong>, using a chimeric protein.</p>', 'label1' => 'Validation Data', 'info1' => '<div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig1.png" alt="GR Antibody ChIP Grade" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 1. ChIP results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP assays were performed using HeLa cells, the Diagenode monoclonal antibody directed against GR (Cat. No. MAb-010-050) and optimized PCR primer sets for qPCR. The cells were treated either with ethanol (EtOH, used as a negative control) or triamcinolone acetonide (TA) for 4 hours prior to cell harvesting. ChIP was performed using sheared chromatin from 3 million cells and 5 μg of antibody. QPCR was performed with primers for the human metallothionein promoter (hMTIIA) and for exon 2 of the human myoglobin gene (hmyo ex2), used as a negative control. Figure 1 shows the recovery (the relative amount of immunoprecipitated DNA compared to input DNA) and the occupancy (ratio +/- control target). These results demonstrate the occupancy of the human metallothionein IIA promoter by GR. </small></p> </div> </div> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2A.png" alt="GR Antibody ChIP-seq Grade" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2B.png" alt="GR Antibody for ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2C.png" alt="GR Antibody for ChIP-seq assay" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2D.png" alt="GR Antibody validated in ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2E.png" alt="GR Antibody ChIP-seq Grade" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 2. ChIP-seq results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP was performed on sheared chromatin from 3.5 million HeLaB2 cells using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). The cells were treated with the synthetic GR ligand triamcinolone acetonide (TA) for 4 hours prior to harvesting. The IP’d DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer’s instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. Figure 2 shows the peak distribution along the complete sequence of chromosome 16 (figure 2A) as well as the MT2A positive control gene (figure 2B). The position of the PCR amplicon is also indicated. Figure 2C, D and E show the results for the known GR target genes PER1 on chromosome 17 and FKBP5 and TNFAIP3 on chromosome 6. </small></p> </div> </div> <p></p> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig3.png" alt="GR Antibody ELISA Validation" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 3. Sandwich ELISA </strong><br />The specificity of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050) was assessed by sandwich ELISA. Figure 3A: schematic representation of the sandwich ELISA with the monoclonal antibody against hGR (clone #:m2F8). Figure 3B: ELISA results using the monoclonal antibody against hGR at a concentration of 0.5 μg/ml. The figure shows an ELISA signal which is proportionally increasing with increasing amounts of recombinant hGR. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig4.png" alt="GR Antibody validated in Western Blot" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 4. Western blot analysis using the Diagenode monoclonal antibody against hGR </strong><br />Figure 4A. Extracts from HeLa cells containing the indicated amounts of GR (from 30 to 240 fmol), and from 5x10e6 Raji or Molt cells were analysed by Western blot using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). Figure 4B. Western blot analysis of extracts from 300,000 HeLa cells with the Diagenode monoclonal antibody against hGR (concentration 1 μg/ml). </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig5.png" alt="GR Antibody validated in Immunohistochemistry" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig6.png" alt="GR Antibody validated for Immunohistochemistry" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 5. Immunohistochemistry and immunofluorescence using the Diagenode monoclonal antibody against hGR </strong><br />1. Immunoreactivity of the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050) in rat CA1 neurons of hippocampus. The antibody was used at a concentration of 2.5 μg/ml. <br />2. COS-7 cells transiently overexpressing human GR were labeled with the antibody against hGR followed by a biotinylated secondary antibody and peroxidase-labeled avidin. The antibody was used at a concentration of 2.5 μg/ml. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig7.png" alt="GR Antibody validated in Immunoprecipitation" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 6. Immunoprecipitation using the Diagenode monoclonal antibody against hGR </strong><br />The glucocorticoid receptor was immunoprecipitated from HeLa cell extracts (5 million HeLa cells in 100 μl IP reaction solution) using 5 μg of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050). The IP was followed by Western blot analysis as described above </small></p> </div> </div>', 'label2' => 'Target Description', 'info2' => '<p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.</p>', 'label3' => '', 'info3' => '', 'format' => '50 µg', 'catalog_number' => 'C15200010', 'old_catalog_number' => 'MAb-010-050', 'sf_code' => 'C15200010-D001-000581', 'type' => 'FRE', 'search_order' => '03-Antibody', 'price_EUR' => '380', 'price_USD' => '380', 'price_GBP' => '340', 'price_JPY' => '59525', 'price_CNY' => '', 'price_AUD' => '950', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => true, 'last_datasheet_update' => '0000-00-00', 'slug' => 'gr-monoclonal-antibody-classic-50-ug-50-ul', 'meta_title' => 'GR Antibody - ChIP-seq Grade (C15200010) | Diagenode', 'meta_keywords' => '', 'meta_description' => 'GR (Glucocorticoid receptor) Monoclonal Antibody validated in ChIP-seq, ChIP-qPCR, WB, Flow Cyt, IP and ELISA. Batch-specific data available on the website. Alternative names: NR3C1, GCCR, GCR, GRL. Sample size avaialble.', 'modified' => '2024-11-19 16:56:51', 'created' => '2015-06-29 14:08:20' ), 'Product' => array( (int) 0 => array( [maximum depth reached] ) ) ), 'Related' => array(), 'Application' => array( (int) 0 => array( 'id' => '42', 'position' => '10', 'parent_id' => '40', 'name' => 'ChIP-seq (ab)', 'description' => '', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'chip-seq-antibodies', 'meta_keywords' => 'Chromatin Immunoprecipitation Sequencing,ChIP-Seq,ChIP-seq grade antibodies,DNA purification,qPCR,Shearing of chromatin', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for ChIP Sequencing applications', 'meta_title' => 'ChIP Sequencing Antibodies (ChIP-Seq) | Diagenode', 'modified' => '2016-01-20 11:06:19', 'created' => '2015-10-20 11:44:45', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '43', 'position' => '10', 'parent_id' => '40', 'name' => 'ChIP-qPCR (ab)', 'description' => '', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'chip-qpcr-antibodies', 'meta_keywords' => 'Chromatin Immunoprecipitation Sequencing,ChIP-Seq,ChIP-seq grade antibodies,DNA purification,qPCR,Shearing of chromatin', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for ChIP-qPCR applications', 'meta_title' => 'ChIP Quantitative PCR Antibodies (ChIP-qPCR) | Diagenode', 'modified' => '2016-01-20 11:30:24', 'created' => '2015-10-20 11:45:36', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '20', 'position' => '10', 'parent_id' => '40', 'name' => 'ELISA', 'description' => '<div class="row"> <div class="small-12 medium-12 large-12 columns">Enzyme-linked immunosorbent assay.</div> </div>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'elisa-antibodies', 'meta_keywords' => ' ELISA Antibodies,Monoclonal antibody, Polyclonal antibody', 'meta_description' => 'Diagenode offers Monoclonal & Polyclonal antibodies for ELISA applications', 'meta_title' => 'ELISA Antibodies - Monoclonal & Polyclonal antibody | Diagenode', 'modified' => '2016-01-13 12:21:41', 'created' => '2014-07-08 08:13:28', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '19', 'position' => '10', 'parent_id' => '40', 'name' => 'WB', 'description' => '<p><strong>Western blot</strong> : The quality of antibodies used in this technique is crucial for correct and specific protein identification. Diagenode offers huge selection of highly sensitive and specific western blot-validated antibodies.</p> <p>Learn more about: <a href="https://www.diagenode.com/applications/western-blot">Loading control, MW marker visualization</a><em>. <br /></em></p> <p><em></em>Check our selection of antibodies validated in Western blot.</p>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'western-blot-antibodies', 'meta_keywords' => ' Western Blot Antibodies ,western blot protocol,Western Blotting Products,Polyclonal antibodies ,monoclonal antibodies ', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for western blot applications', 'meta_title' => ' Western Blot - Monoclonal antibody - Polyclonal antibody | Diagenode', 'modified' => '2016-04-26 12:44:51', 'created' => '2015-01-07 09:20:00', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '30', 'position' => '10', 'parent_id' => '40', 'name' => 'IP', 'description' => '<p>Immunoprecipitation</p>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'immunoprecipitation', 'meta_keywords' => 'Immunoprecipitation,Monoclonal antibody,Polyclonal antibody', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for Immunoprecipitation applications', 'meta_title' => 'Immunoprecipitation - Monoclonal antibody - Polyclonal antibody | Diagenode', 'modified' => '2016-01-13 12:23:07', 'created' => '2015-07-08 13:46:50', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '33', 'position' => '10', 'parent_id' => '40', 'name' => 'GSA', 'description' => '<p><span>Gel Supershift</span></p>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'gel-supershift-assays', 'meta_keywords' => 'GSA,Gel Super Shift Assays,Gel Shift', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for Gel Supershift applications', 'meta_title' => 'Gel Shift/Gel Super Shift Assays - Monoclonal antibody | Diagenode', 'modified' => '2016-01-13 12:24:19', 'created' => '2015-07-08 13:51:58', 'ProductsApplication' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '34', 'position' => '10', 'parent_id' => '40', 'name' => 'Flow Cyt', 'description' => '<p>Flow cyt</p>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'flow-cytometry', 'meta_keywords' => 'Flow cytometry,Flow cyt,Monoclonal antibody,GR monoclonal antibody ', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for Flow cytometry applications', 'meta_title' => 'Flow cytometry - Monoclonal antibody | Diagenode', 'modified' => '2016-01-13 12:24:36', 'created' => '2015-07-08 13:53:00', 'ProductsApplication' => array( [maximum depth reached] ) ) ), 'Category' => array( (int) 0 => array( 'id' => '127', 'position' => '10', 'parent_id' => '4', 'name' => 'ChIP-grade antibodies', 'description' => '<div class="row"> <div class="small-12 columns"><center></center> <p><br />Chromatin immunoprecipitation (<b>ChIP</b>) is a technique to study the associations of proteins with the specific genomic regions in intact cells. One of the most important steps of this protocol is the immunoprecipitation of targeted protein using the antibody specifically recognizing it. The quality of antibodies used in ChIP is essential for the success of the experiment. Diagenode offers extensively validated ChIP-grade antibodies, confirmed for their specificity, and high level of performance in ChIP. Each batch is validated, and batch-specific data are available on the website.</p> <p></p> </div> </div> <p><strong>ChIP results</strong> obtained with the antibody directed against H3K4me3 (Cat. No. <a href="../p/h3k4me3-polyclonal-antibody-premium-50-ug-50-ul">C15410003</a>). </p> <div class="row"> <div class="small-12 medium-6 large-6 columns"><img src="https://www.diagenode.com/img/product/antibodies/C15410003-fig1-ChIP.jpg" alt="" width="400" height="315" /> </div> <div class="small-12 medium-6 large-6 columns"> <p></p> <p></p> <p></p> </div> </div> <p></p> <p>Our aim at Diagenode is to offer the largest collection of highly specific <strong>ChIP-grade antibodies</strong>. We add new antibodies monthly. Find your ChIP-grade antibody in the list below and check more information about tested applications, extensive validation data, and product information.</p>', 'no_promo' => false, 'in_menu' => true, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => false, 'is_antibody' => true, 'slug' => 'chip-grade-antibodies', 'cookies_tag_id' => null, 'meta_keywords' => 'ChIP-grade antibodies, polyclonal antibody, monoclonal antibody, Diagenode', 'meta_description' => 'Diagenode Offers Extensively Validated ChIP-Grade Antibodies, Confirmed for their Specificity, and high level of Performance in Chromatin Immunoprecipitation ChIP', 'meta_title' => 'Chromatin immunoprecipitation ChIP-grade antibodies | Diagenode', 'modified' => '2024-11-19 17:27:07', 'created' => '2017-02-14 11:16:04', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ), (int) 1 => array( 'id' => '17', 'position' => '10', 'parent_id' => '4', 'name' => 'ChIP-seq grade antibodies', 'description' => '<p><b>Unparalleled ChIP-Seq results with the most rigorously validated antibodies</b></p> <p><span style="font-weight: 400;">Diagenode provides leading solutions for epigenetic research. Because ChIP-seq is a widely-used technique, we validate our antibodies in ChIP and ChIP-seq experiments (in addition to conventional methods like Western blot, Dot blot, ELISA, and immunofluorescence) to provide the highest quality antibody. We standardize our validation and production to guarantee high product quality without technical bias. Diagenode guarantees ChIP-seq grade antibody performance under our suggested conditions.</span></p> <div class="row"> <div class="small-12 medium-9 large-9 columns"> <p><strong>ChIP-seq profile</strong> of active (H3K4me3 and H3K36me3) and inactive (H3K27me3) marks using Diagenode antibodies.</p> <img src="https://www.diagenode.com/img/categories/antibodies/chip-seq-grade-antibodies.png" /></div> <div class="small-12 medium-3 large-3 columns"> <p><small> ChIP was performed on sheared chromatin from 100,000 K562 cells using iDeal ChIP-seq kit for Histones (cat. No. C01010051) with 1 µg of the Diagenode antibodies against H3K27me3 (cat. No. C15410195) and H3K4me3 (cat. No. C15410003), and 0.5 µg of the antibody against H3K36me3 (cat. No. C15410192). The IP'd DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer's instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. The figure shows the signal distribution along the complete sequence of human chromosome 3, a zoomin to a 10 Mb region and a further zoomin to a 1.5 Mb region. </small></p> </div> </div> <p>Diagenode’s highly validated antibodies:</p> <ul> <li>Highly sensitive and specific</li> <li>Cost-effective (requires less antibody per reaction)</li> <li>Batch-specific data is available on the website</li> <li>Expert technical support</li> <li>Sample sizes available</li> <li>100% satisfaction guarantee</li> </ul>', 'no_promo' => false, 'in_menu' => true, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => false, 'is_antibody' => true, 'slug' => 'chip-seq-grade-antibodies', 'cookies_tag_id' => null, 'meta_keywords' => 'ChIP-seq grade antibodies,polyclonal antibody,WB, ELISA, ChIP-seq (ab), ChIP-qPCR (ab)', 'meta_description' => 'Diagenode Offers Wide Range of Validated ChIP-Seq Grade Antibodies for Unparalleled ChIP-Seq Results', 'meta_title' => 'Chromatin Immunoprecipitation ChIP-Seq Grade Antibodies | Diagenode', 'modified' => '2019-07-03 10:57:22', 'created' => '2015-02-16 02:24:01', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ), (int) 2 => array( 'id' => '103', 'position' => '0', 'parent_id' => '4', 'name' => 'All antibodies', 'description' => '<p><span style="font-weight: 400;">All Diagenode’s antibodies are listed below. Please, use our Quick search field to find the antibody of interest by target name, application, purity.</span></p> <p><span style="font-weight: 400;">Diagenode’s highly validated antibodies:</span></p> <ul> <li>Highly sensitive and specific</li> <li>Cost-effective (requires less antibody per reaction)</li> <li>Batch-specific data is available on the website</li> <li>Expert technical support</li> <li>Sample sizes available</li> <li>100% satisfaction guarantee</li> </ul>', 'no_promo' => false, 'in_menu' => true, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => false, 'is_antibody' => true, 'slug' => 'all-antibodies', 'cookies_tag_id' => null, 'meta_keywords' => 'Antibodies,Premium Antibodies,Classic,Pioneer', 'meta_description' => 'Diagenode Offers Strict quality standards with Rigorous QC and validated Antibodies. Classified based on level of validation for flexibility of Application. Comprehensive selection of histone and non-histone Antibodies', 'meta_title' => 'Diagenode's selection of Antibodies is exclusively dedicated for Epigenetic Research | Diagenode', 'modified' => '2019-07-03 10:55:44', 'created' => '2015-11-02 14:49:22', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ), (int) 3 => array( 'id' => '102', 'position' => '1', 'parent_id' => '4', 'name' => 'Sample size antibodies', 'description' => '<h1><strong>Validated epigenetics antibodies</strong> – care for a sample?<br /> </h1> <p>Diagenode has partnered with leading epigenetics experts and numerous epigenetics consortiums to bring to you a validated and comprehensive collection of epigenetic antibodies. As an expert in epigenetics, we are committed to offering highly-specific antibodies validated for ChIP/ChIP-seq and many other applications. All batch-specific validation data is available on our website.<br /><a href="../categories/antibodies">Read about our expertise in antibody production</a>.</p> <ul> <li><strong>Focused</strong> - Diagenode's selection of antibodies is exclusively dedicated for epigenetic research. <a title="See the full collection." href="../categories/all-antibodies">See the full collection.</a></li> <li><strong>Strict quality standards</strong> with rigorous QC and validation</li> <li><strong>Classified</strong> based on level of validation for flexibility of application</li> </ul> <p>Existing sample sizes are listed below. We will soon expand our collection. Are you looking for a sample size of another antibody? Just <a href="mailto:agnieszka.zelisko@diagenode.com?Subject=Sample%20Size%20Request" target="_top">Contact us</a>.</p>', 'no_promo' => false, 'in_menu' => true, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => true, 'is_antibody' => true, 'slug' => 'sample-size-antibodies', 'cookies_tag_id' => null, 'meta_keywords' => '5-hmC monoclonal antibody,CRISPR/Cas9 polyclonal antibody ,H3K36me3 polyclonal antibody,diagenode', 'meta_description' => 'Diagenode offers sample volume on selected antibodies for researchers to test, validate and provide confidence and flexibility in choosing from our wide range of antibodies ', 'meta_title' => 'Sample-size Antibodies | Diagenode', 'modified' => '2019-07-03 10:57:05', 'created' => '2015-10-27 12:13:34', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ), (int) 4 => array( 'id' => '30', 'position' => '50', 'parent_id' => '4', 'name' => 'Transcription', 'description' => '<p><span style="font-weight: 400;">The list of Diagenode’s highly specific antibodies for transcription studies includes the antibodies against many transcription factors and nuclear receptors. Check the list below to see our targets.</span></p> <p><span style="font-weight: 400;">Diagenode’s highly validated antibodies:</span></p> <ul> <li><span style="font-weight: 400;"> Highly sensitive and specific</span></li> <li><span style="font-weight: 400;"> Cost-effective (requires less antibody per reaction)</span></li> <li><span style="font-weight: 400;"> Batch-specific data is available on the website</span></li> <li><span style="font-weight: 400;"> Expert technical support</span></li> <li><span style="font-weight: 400;"> Sample sizes available</span></li> <li><span style="font-weight: 400;"> 100% satisfaction guarantee</span></li> </ul>', 'no_promo' => false, 'in_menu' => false, 'online' => true, 'tabular' => false, 'hide' => true, 'all_format' => false, 'is_antibody' => true, 'slug' => 'transcription-factor', 'cookies_tag_id' => null, 'meta_keywords' => ' Transcription factor antibodies,monoclonal antibodies,polyclonal antibodies', 'meta_description' => 'Diagenode offers polyclonal and monoclonal antibodies for Transcription studie', 'meta_title' => 'Transcription factor Antibodies | Diagenode', 'modified' => '2020-07-06 12:59:19', 'created' => '2015-03-12 10:20:08', 'ProductsCategory' => array( [maximum depth reached] ), 'CookiesTag' => array([maximum depth reached]) ) ), 'Document' => array( (int) 0 => array( 'id' => '11', 'name' => 'Antibodies you can trust', 'description' => '<p style="text-align: justify;"><span>Epigenetic research tools have evolved over time from endpoint PCR to qPCR to the analyses of large sets of genome-wide sequencing data. ChIP sequencing (ChIP-seq) has now become the gold standard method for chromatin studies, given the accuracy and coverage scale of the approach over other methods. Successful ChIP-seq, however, requires a higher level of experimental accuracy and consistency in all steps of ChIP than ever before. Particularly crucial is the quality of ChIP antibodies. </span></p>', 'image_id' => null, 'type' => 'Poster', 'url' => 'files/posters/Antibodies_you_can_trust_Poster.pdf', 'slug' => 'antibodies-you-can-trust-poster', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2015-10-01 20:18:31', 'created' => '2015-07-03 16:05:15', 'ProductsDocument' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '38', 'name' => 'Epigenetic Antibodies Brochure', 'description' => '<p>More than in any other immuoprecipitation assays, quality antibodies are critical tools in many epigenetics experiments. Since 10 years, Diagenode has developed the most stringent quality production available on the market for antibodies exclusively focused on epigenetic uses. All our antibodies have been qualified to work in epigenetic applications.</p>', 'image_id' => null, 'type' => 'Brochure', 'url' => 'files/brochures/Epigenetic_Antibodies_Brochure.pdf', 'slug' => 'epigenetic-antibodies-brochure', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2016-06-15 11:24:06', 'created' => '2015-07-03 16:05:27', 'ProductsDocument' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '440', 'name' => 'Datasheet hGR C15200010', 'description' => '<p>Datasheet description</p>', 'image_id' => null, 'type' => 'Datasheet', 'url' => 'files/products/antibodies/Datasheet_hGR_C15200010.pdf', 'slug' => 'datasheet-hgr-C15200010', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2015-11-20 17:16:18', 'created' => '2015-07-07 11:47:44', 'ProductsDocument' => array( [maximum depth reached] ) ) ), 'Feature' => array(), 'Image' => array( (int) 0 => array( 'id' => '1783', 'name' => 'product/antibodies/chipseq-grade-ab-icon.png', 'alt' => 'ChIP-seq Grade', 'modified' => '2020-11-27 07:04:40', 'created' => '2018-03-15 15:54:09', 'ProductsImage' => array( [maximum depth reached] ) ) ), 'Promotion' => array(), 'Protocol' => array(), 'Publication' => array( (int) 0 => array( 'id' => '4253', 'name' => 'Coordinated glucocorticoid receptor and MAFB action inducestolerogenesis and epigenome remodeling in dendritic cells', 'authors' => 'Morante-Palacios Octavio et al.', 'description' => '<p>Abstract Glucocorticoids (GCs) exert potent anti-inflammatory effects in immune cells through the glucocorticoid receptor (GR). Dendritic cells (DCs), central actors for coordinating immune responses, acquire tolerogenic properties in response to GCs. Tolerogenic DCs (tolDCs) have emerged as a potential treatment for various inflammatory diseases. To date, the underlying cell type-specific regulatory mechanisms orchestrating GC-mediated acquisition of immunosuppressive properties remain poorly understood. In this study, we investigated the transcriptomic and epigenomic remodeling associated with differentiation to DCs in the presence of GCs. Our analysis demonstrates a major role of MAFB in this process, in synergy with GR. GR and MAFB both interact with methylcytosine dioxygenase TET2 and bind to genomic loci that undergo specific demethylation in tolDCs. We also show that the role of MAFB is more extensive, binding to thousands of genomic loci in tolDCs. Finally, MAFB knockdown erases the tolerogenic properties of tolDCs and reverts the specific DNA demethylation and gene upregulation. The preeminent role of MAFB is also demonstrated in vivo for myeloid cells from synovium in rheumatoid arthritis following GC treatment. Our results imply that, once directly activated by GR, MAFB plays a critical role in orchestrating the epigenomic and transcriptomic remodeling that define the tolerogenic phenotype.</p>', 'date' => '2022-01-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/34893889', 'doi' => '10.1093/nar/gkab1182', 'modified' => '2022-05-20 09:44:29', 'created' => '2022-05-19 10:41:50', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '3208', 'name' => 'The Role of S-Palmitoylation of the Human Glucocorticoid Receptor (hGR) in Mediating the Nongenomic Glucocorticoid Actions', 'authors' => 'Nicolaides N. et al.', 'description' => '<p>Background: Many rapid nongenomic glucocorticoid actions are mediated by membrane-bound glucocorticoid receptors (GRs). S-palmitoylation is a lipid post-translational modification that mediates the membrane localization of some steroid receptors. A highly homologous amino acid sequence (663YLCM KTLLL671) is present in the ligand-binding domain of hGRα, suggesting that hGRα might also undergo S-palmitoylation.</p> <p>Aim: To investigate the role of the motif 663YLCMKTLLL671 in membrane localization of the hGRα and in mediating rapid nongenomic glucocorticoid signaling.</p> <p>Methods and Results: We showed that the mutant receptors hGRαY663A, hGRαC665A and hGRαLL670/671AA, and the addition of the palmitoylation inhibitor 2-bromopalmitate did not prevent membrane localization of hGRα and co-localization with caveolin-1, and did not influence the biphasic activation of mitogen-activated protein kinase (MAPK) signaling pathway in the early time points. Finally, the hGRα was not shown to undergo S-palmitoylation.</p> <p>Conclusions: The motif 663YLCMKTLLL671 does not play a role in membrane localization of hGRα and does not mediate the nongenomic glucocorticoid actions.</p>', 'date' => '2017-04-15', 'pmid' => 'http://www.jmolbiochem.com/index.php/JmolBiochem/article/view/199', 'doi' => '', 'modified' => '2017-07-07 16:21:23', 'created' => '2017-07-07 16:21:23', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '2923', 'name' => 'Three Novel Heterozygous Point Mutations of NR3C1 causing Glucocorticoid Resistance', 'authors' => 'Vitellius G et al.', 'description' => '<p>Generalized glucocorticoid resistance is associated with glucocorticoid receptor (GR, NR3C1) mutations. Three novel heterozygous missense NR3C1 mutations (R477S, Y478C and L672P) were identified in patients presenting with adrenal incidentalomas, glucocorticoid excess without Cushing syndrome. Dexamethasone (DXM) binding studies demonstrated that the affinity of GR<sub>R477S</sub> and GR<sub>Y478C</sub> mutants, located in the DNA-binding domain of GR, was similar to wild-type GR (Kd = 2-3 nM). In contrast, GR<sub>L672P</sub> mutant, located in the ligand-binding domain of GR, was unable to bind glucocorticoids and was more sensitive to protein degradation. GR subcellular distribution revealed a marked decrease in DXM-induced nuclear translocation of GR<sub>R477S</sub> and GR<sub>Y478C</sub> mutants, whereas GR<sub>L672P</sub> remained exclusively cytoplasmic. Chromatin immunoprecipitation demonstrated impaired recruitment of DBD mutants onto the regulatory sequence of FKBP5. Transactivation assays disclosed the lack of transcriptional activity of GR<sub>R477S</sub> and GR<sub>L672P</sub> while GR<sub>Y478C</sub> had a reduced transactivation capacity. Three-D modeling indicated that R477S lost two essential hydrogen bonds with DNA, Y478C resulted in altered interaction with surrounding amino-acids, destabilizing DBD, while L672P altered the H8 helix folding, leading to unstructured LBD. This study identifies novel NR3C1 mutations with their molecular consequences on altered GR signaling and suggests that genetic screening of NR3C1 should be conducted in patients with subclinical hypercorticism.</p>', 'date' => '2016-04-27', 'pmid' => 'http://www.ncbi.nlm.nih.gov/pubmed/27120390', 'doi' => '10.1002/humu.23008', 'modified' => '2016-05-13 17:32:26', 'created' => '2016-05-13 17:32:26', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '2967', 'name' => 'Functional characterization of the hGRαT556I causing Chrousos syndrome', 'authors' => 'Nicolaides NC et al.', 'description' => '<h4>BACKGROUND:</h4> <p><abstracttext label="BACKGROUND" nlmcategory="BACKGROUND">Chrousos syndrome is a rare pathologic condition characterized by generalized, partial resistance of target tissues to glucocorticoids and caused by inactivating mutations of the human glucocorticoid receptor (hGR) gene. A novel case of Chrousos syndrome has been reported in a patient with adrenal incidentaloma, who harboured a heterozygous point mutation in the hGR gene, which resulted in threonine (T) to isoleucine (I) substitution at amino acid position 556 in the ligand-binding domain of the receptor.</abstracttext></p> <h4>OBJECTIVE:</h4> <p><abstracttext label="OBJECTIVE" nlmcategory="OBJECTIVE">To delineate the molecular mechanisms through which the mutant receptor hGRαT556I causes Chrousos syndrome.</abstracttext></p> <h4>DESIGN AND RESULTS:</h4> <p><abstracttext label="DESIGN AND RESULTS" nlmcategory="RESULTS">Compared with the wild-type receptor, the mutant receptor hGRαT556I demonstrated 50% reduction in its ability to transactivate glucocorticoid-responsive genes and in the affinity for the ligand, 30% increase in the ability to transrepress the nuclear factor-κB-target genes and a 3,4-fold delay in the cytoplasmic-to-nuclear translocation. The mutant receptor hGRαT556I did not exert a dominant negative effect upon the hGRα-mediated transcriptional activity; it preserved its ability to bind to DNA and interacted with the glucocorticoid receptor-interacting protein 1 coactivator mostly through its activation function-1 domain. Structural biology studies revealed that the T556I mutation caused disruption of the hydrogen bond formed by the T556 with the =O group of P637 backbone, which resulted in a significant relocation of the P637-bearing loop. This conformational alteration affected the local 3D arrangement of the receptor and hence the electrostatic surface of the region.</abstracttext></p> <h4>CONCLUSIONS:</h4> <p><abstracttext label="CONCLUSIONS" nlmcategory="CONCLUSIONS">The hGRαT556I causes Chrousos syndrome by impairing multiple steps of the glucocorticoid signal transduction pathway.</abstracttext></p>', 'date' => '2016-01-01', 'pmid' => 'http://www.ncbi.nlm.nih.gov/pubmed/26541474', 'doi' => ' 10.1111/eci.12563', 'modified' => '2016-06-29 09:41:42', 'created' => '2016-06-29 09:41:42', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '1776', 'name' => 'Perinatal exposure to low-dose bisphenol A affects the neuroendocrine stress response in rats.', 'authors' => 'Panagiotidou E, Zerva S, Mitsiou DJ, Alexis MN, Kitraki E', 'description' => 'Bisphenol A (BPA) is an estrogen-mimicking endocrine disruptor. Early-life exposures to low doses of BPA exert long-lasting effects on animals' reproductive and brain physiology. However, little is known about the effects of BPA on the stress-response system. Given the interaction of sex and stress hormones, we examined the effect of a low perinatal BPA exposure on the function of the hypothalamic-pituitary-adrenal (HPA) axis at rest and upon application of acute stress. Throughout pregnancy and lactation rats received daily 40 μg BPA/kg body weight orally via cornflakes. We studied the effect of this low but chronic exposure to BPA in the male and female offspring at puberty. BPA exposure led to abnormal adrenal histology including reduced zona reticularis especially in male offspring, hyperplasia of zona fasciculata in both sexes, and increased adrenal weight in female offspring. BPA-treated females had increased basal corticosterone and reduced hypothalamic glucocorticoid receptors (GR) levels. Stressed BPA-exposed females exhibited anxiety-like behavioral coping, a less rigorous corticosterone response, and did not downregulate GR in the hypothalamus, compared with control females. BPA-exposed males exhibited a heightened corticosterone stress response compared with females; they also displayed increased pro-opiomelanocortin mRNA levels and retained the prestress levels of pituitary corticotropin-releasing hormone-receptor 1, compared with control males. We found that perinatal chronic exposure to a low dose of BPA perturbs the basal and stress-induced activity of the HPA axis in a sexually dimorphic manner at adolescence. Exposure to BPA might contribute to increased susceptibility to stress-related disorders in later life.', 'date' => '2014-03-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/24323913', 'doi' => '', 'modified' => '2015-07-24 15:39:01', 'created' => '2015-07-24 15:39:01', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '1557', 'name' => 'Pattern of heat shock factor and heat shock protein expression in lymphocytes of bipolar patients: Increased HSP70-glucocorticoid receptor heterocomplex.', 'authors' => 'Bei ES, Salpeas V, Alevizos B, Anagnostara C, Pappa D, Moutsatsou P', 'description' => 'Bipolar disorder (BD), a stress-related disease, is characterized by altered glucocorticoid receptor (GR) signalling. Stress response includes activation of heat shock factor (HSF) and subsequent heat shock protein (HSP) synthesis which regulate GR folding and function. The objective of this study was to investigate the possible role of HSFs, HSPs and their interaction with GR in BD. We applied immunoprecipitation, SDS-PAGE/Western blot analysis and electrophoretic mobility shift assay (EMSA) in lymphocytes (whole cell or nuclear extracts) from BD patients and healthy subjects and determined the HSPs (HSP90 and HSP70), the heterocomplexes HSP90-GR and HSP70-GR, the HSFs (HSF1 and HSF4) as well as the HSF-DNA binding. The HSP70-GR heterocomplex was elevated (p < 0.05) in BD patients vs healthy subjects, and nuclear HSP70 was reduced (p ≤ 0.01) in bipolar manic patients. Protein levels of HSF1, HSF4, HSP90, HSP90-GR heterocomplex, and HSF-DNA binding remained unaltered in BD patients vs healthy subjects. The corresponding effect sizes (ES) indicated a large ES for HSP70-GR, HSP70, HSF-DNA binding and HSF4, and a medium ES for HSP90, HSF1 and HSP90-GR between healthy subjects and bipolar patients. Significant correlations among HSFs, HSPs, GR and HSP70-GR heterocomplex were observed in healthy subjects, which were abrogated in bipolar patients. The higher interaction between GR and HSP70 and the disturbances in the relations among heat shock response parameters and GR as observed in our BD patients may provide novel insights into the contribution of these factors in BD aetiopathogenesis.', 'date' => '2013-11-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/23938235', 'doi' => '', 'modified' => '2015-07-24 15:39:00', 'created' => '2015-07-24 15:39:00', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '253', 'name' => 'Coactivation of GR and NFKB alters the repertoire of their binding sites and target genes.', 'authors' => 'Rao NA, McCalman MT, Moulos P, Francoijs KJ, Chatziioannou A, Kolisis FN, Alexis MN, Mitsiou DJ, Stunnenberg HG', 'description' => 'Glucocorticoid receptor (GR) exerts anti-inflammatory action in part by antagonizing proinflammatory transcription factors such as the nuclear factor kappa-b (NFKB). Here, we assess the crosstalk of activated GR and RELA (p65, major NFKB component) by global identification of their binding sites and target genes. We show that coactivation of GR and p65 alters the repertoire of regulated genes and results in their association with novel sites in a mutually dependent manner. These novel sites predominantly cluster with p65 target genes that are antagonized by activated GR and vice versa. Our data show that coactivation of GR and NFKB alters signaling pathways that are regulated by each factor separately and provide insight into the networks underlying the GR and NFKB crosstalk.', 'date' => '2011-09-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/21750107', 'doi' => '', 'modified' => '2015-07-24 15:38:57', 'created' => '2015-07-24 15:38:57', 'ProductsPublication' => array( [maximum depth reached] ) ) ), 'Testimonial' => array(), 'Area' => array(), 'SafetySheet' => array( (int) 0 => array( 'id' => '568', 'name' => 'GR antibody SDS US en', 'language' => 'en', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-US-en-GHS_2_0.pdf', 'countries' => 'US', 'modified' => '2020-07-01 14:51:26', 'created' => '2020-07-01 14:51:26', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '566', 'name' => 'GR antibody SDS GB en', 'language' => 'en', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-GB-en-GHS_2_0.pdf', 'countries' => 'GB', 'modified' => '2020-07-01 14:50:36', 'created' => '2020-07-01 14:50:36', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '561', 'name' => 'GR antibody SDS BE fr', 'language' => 'fr', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-BE-fr-GHS_2_0.pdf', 'countries' => 'BE', 'modified' => '2020-07-01 14:47:08', 'created' => '2020-07-01 14:47:08', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '565', 'name' => 'GR antibody SDS FR fr', 'language' => 'fr', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-FR-fr-GHS_2_0.pdf', 'countries' => 'FR', 'modified' => '2020-07-01 14:49:58', 'created' => '2020-07-01 14:49:58', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '564', 'name' => 'GR antibody SDS ES es', 'language' => 'es', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-ES-es-GHS_2_0.pdf', 'countries' => 'ES', 'modified' => '2020-07-01 14:49:11', 'created' => '2020-07-01 14:49:11', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '563', 'name' => 'GR antibody SDS DE de', 'language' => 'de', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-DE-de-GHS_2_0.pdf', 'countries' => 'DE', 'modified' => '2020-07-01 14:48:31', 'created' => '2020-07-01 14:48:31', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '567', 'name' => 'GR antibody SDS JP ja', 'language' => 'ja', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-JP-ja-GHS_2_0.pdf', 'countries' => 'JP', 'modified' => '2020-07-01 14:51:01', 'created' => '2020-07-01 14:51:01', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 7 => array( 'id' => '562', 'name' => 'GR antibody SDS BE nl', 'language' => 'nl', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-BE-nl-GHS_2_0.pdf', 'countries' => 'BE', 'modified' => '2020-07-01 14:47:51', 'created' => '2020-07-01 14:47:51', 'ProductsSafetySheet' => array( [maximum depth reached] ) ) ) ) $meta_canonical = 'https://www.diagenode.com/jp/p/gr-monoclonal-antibody-classic-50-ug-50-ul' $country = 'US' $countries_allowed = array( (int) 0 => 'CA', (int) 1 => 'US', (int) 2 => 'IE', (int) 3 => 'GB', (int) 4 => 'DK', (int) 5 => 'NO', (int) 6 => 'SE', (int) 7 => 'FI', (int) 8 => 'NL', (int) 9 => 'BE', (int) 10 => 'LU', (int) 11 => 'FR', (int) 12 => 'DE', (int) 13 => 'CH', (int) 14 => 'AT', (int) 15 => 'ES', (int) 16 => 'IT', (int) 17 => 'PT' ) $outsource = true $other_formats = array( (int) 0 => array( 'id' => '1970', 'antibody_id' => '326', 'name' => 'GR Antibody', 'description' => '<p>Alternative names: <strong>NR3C1</strong>,<strong> GCCR</strong>, <strong>GCR</strong>, <strong>GRL</strong></p> <p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human <strong>GR (glucocorticoid receptor)</strong>, using a chimeric protein.</p>', 'label1' => 'Validation Data', 'info1' => '<div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig1.png" alt="GR Antibody ChIP Grade" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 1. ChIP results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP assays were performed using HeLa cells, the Diagenode monoclonal antibody directed against GR (Cat. No. MAb-010-050) and optimized PCR primer sets for qPCR. The cells were treated either with ethanol (EtOH, used as a negative control) or triamcinolone acetonide (TA) for 4 hours prior to cell harvesting. ChIP was performed using sheared chromatin from 3 million cells and 5 μg of antibody. QPCR was performed with primers for the human metallothionein promoter (hMTIIA) and for exon 2 of the human myoglobin gene (hmyo ex2), used as a negative control. Figure 1 shows the recovery (the relative amount of immunoprecipitated DNA compared to input DNA) and the occupancy (ratio +/- control target). These results demonstrate the occupancy of the human metallothionein IIA promoter by GR. </small></p> </div> </div> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2A.png" alt="GR Antibody ChIP-seq Grade" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2B.png" alt="GR Antibody for ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2C.png" alt="GR Antibody for ChIP-seq assay" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2D.png" alt="GR Antibody validated in ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2E.png" alt="GR Antibody ChIP-seq Grade" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 2. ChIP-seq results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP was performed on sheared chromatin from 3.5 million HeLaB2 cells using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). The cells were treated with the synthetic GR ligand triamcinolone acetonide (TA) for 4 hours prior to harvesting. The IP’d DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer’s instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. Figure 2 shows the peak distribution along the complete sequence of chromosome 16 (figure 2A) as well as the MT2A positive control gene (figure 2B). The position of the PCR amplicon is also indicated. Figure 2C, D and E show the results for the known GR target genes PER1 on chromosome 17 and FKBP5 and TNFAIP3 on chromosome 6. </small></p> </div> </div> <p></p> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig3.png" alt="GR Antibody ELISA Validation" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 3. Sandwich ELISA </strong><br />The specificity of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050) was assessed by sandwich ELISA. Figure 3A: schematic representation of the sandwich ELISA with the monoclonal antibody against hGR (clone #:m2F8). Figure 3B: ELISA results using the monoclonal antibody against hGR at a concentration of 0.5 μg/ml. The figure shows an ELISA signal which is proportionally increasing with increasing amounts of recombinant hGR. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig4.png" alt="GR Antibody validated in Western Blot" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 4. Western blot analysis using the Diagenode monoclonal antibody against hGR </strong><br />Figure 4A. Extracts from HeLa cells containing the indicated amounts of GR (from 30 to 240 fmol), and from 5x10e6 Raji or Molt cells were analysed by Western blot using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). Figure 4B. Western blot analysis of extracts from 300,000 HeLa cells with the Diagenode monoclonal antibody against hGR (concentration 1 μg/ml). </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig5.png" alt="GR Antibody validated in Immunohistochemistry" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig6.png" alt="GR Antibody validated for Immunohistochemistry" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 5. Immunohistochemistry and immunofluorescence using the Diagenode monoclonal antibody against hGR </strong><br />1. Immunoreactivity of the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050) in rat CA1 neurons of hippocampus. The antibody was used at a concentration of 2.5 μg/ml. <br />2. COS-7 cells transiently overexpressing human GR were labeled with the antibody against hGR followed by a biotinylated secondary antibody and peroxidase-labeled avidin. The antibody was used at a concentration of 2.5 μg/ml. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig7.png" alt="GR Antibody validated in Immunoprecipitation" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 6. Immunoprecipitation using the Diagenode monoclonal antibody against hGR </strong><br />The glucocorticoid receptor was immunoprecipitated from HeLa cell extracts (5 million HeLa cells in 100 μl IP reaction solution) using 5 μg of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050). The IP was followed by Western blot analysis as described above </small></p> </div> </div>', 'label2' => 'Target Description', 'info2' => '<p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.</p>', 'label3' => '', 'info3' => '', 'format' => '50 µg', 'catalog_number' => 'C15200010', 'old_catalog_number' => 'MAb-010-050', 'sf_code' => 'C15200010-D001-000581', 'type' => 'FRE', 'search_order' => '03-Antibody', 'price_EUR' => '380', 'price_USD' => '380', 'price_GBP' => '340', 'price_JPY' => '59525', 'price_CNY' => '', 'price_AUD' => '950', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => true, 'last_datasheet_update' => '0000-00-00', 'slug' => 'gr-monoclonal-antibody-classic-50-ug-50-ul', 'meta_title' => 'GR Antibody - ChIP-seq Grade (C15200010) | Diagenode', 'meta_keywords' => '', 'meta_description' => 'GR (Glucocorticoid receptor) Monoclonal Antibody validated in ChIP-seq, ChIP-qPCR, WB, Flow Cyt, IP and ELISA. Batch-specific data available on the website. Alternative names: NR3C1, GCCR, GCR, GRL. Sample size avaialble.', 'modified' => '2024-11-19 16:56:51', 'created' => '2015-06-29 14:08:20' ) ) $pro = array( 'id' => '2893', 'antibody_id' => '326', 'name' => 'GR Antibody (sample size)', 'description' => '<p>Alternative names: <strong>NR3C1, GCCR, GCR, GRL </strong></p> <p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human <strong>GR (glucocorticoid receptor),</strong> using a chimeric protein.</p>', 'label1' => 'Validation data', 'info1' => '', 'label2' => '', 'info2' => '', 'label3' => '', 'info3' => '', 'format' => '10 µg', 'catalog_number' => 'C15200010-10', 'old_catalog_number' => '', 'sf_code' => 'C15200010-D001-000582', 'type' => 'FRE', 'search_order' => '', 'price_EUR' => '105', 'price_USD' => '115', 'price_GBP' => '100', 'price_JPY' => '16450', 'price_CNY' => '', 'price_AUD' => '288', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => false, 'last_datasheet_update' => '', 'slug' => 'gr-monoclonal-antibody-classic-10-ug', 'meta_title' => 'GR Antibody - ChIP-seq Grade (C15200010) | Diagenode', 'meta_keywords' => '', 'meta_description' => 'GR (Glucocorticoid receptor) Monoclonal Antibody validated in ChIP-seq, ChIP-qPCR, WB, IP, and ELISA. Batch-specific data available on the website. Alternative names: NR3C1, GCCR, GCR, GRL. Sample size available.', 'modified' => '2022-01-05 14:49:33', 'created' => '2017-05-17 14:56:35', 'ProductsGroup' => array( 'id' => '234', 'product_id' => '2893', 'group_id' => '209' ) ) $edit = '' $testimonials = '' $featured_testimonials = '' $related_products = '' $rrbs_service = array( (int) 0 => (int) 1894, (int) 1 => (int) 1895 ) $chipseq_service = array( (int) 0 => (int) 2683, (int) 1 => (int) 1835, (int) 2 => (int) 1836, (int) 3 => (int) 2684, (int) 4 => (int) 1838, (int) 5 => (int) 1839, (int) 6 => (int) 1856 ) $labelize = object(Closure) { } $old_catalog_number = ' <span style="color:#CCC">(MAb-010-050)</span>' $country_code = 'US' $other_format = array( 'id' => '1970', 'antibody_id' => '326', 'name' => 'GR Antibody', 'description' => '<p>Alternative names: <strong>NR3C1</strong>,<strong> GCCR</strong>, <strong>GCR</strong>, <strong>GRL</strong></p> <p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human <strong>GR (glucocorticoid receptor)</strong>, using a chimeric protein.</p>', 'label1' => 'Validation Data', 'info1' => '<div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig1.png" alt="GR Antibody ChIP Grade" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 1. ChIP results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP assays were performed using HeLa cells, the Diagenode monoclonal antibody directed against GR (Cat. No. MAb-010-050) and optimized PCR primer sets for qPCR. The cells were treated either with ethanol (EtOH, used as a negative control) or triamcinolone acetonide (TA) for 4 hours prior to cell harvesting. ChIP was performed using sheared chromatin from 3 million cells and 5 μg of antibody. QPCR was performed with primers for the human metallothionein promoter (hMTIIA) and for exon 2 of the human myoglobin gene (hmyo ex2), used as a negative control. Figure 1 shows the recovery (the relative amount of immunoprecipitated DNA compared to input DNA) and the occupancy (ratio +/- control target). These results demonstrate the occupancy of the human metallothionein IIA promoter by GR. </small></p> </div> </div> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2A.png" alt="GR Antibody ChIP-seq Grade" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2B.png" alt="GR Antibody for ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2C.png" alt="GR Antibody for ChIP-seq assay" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2D.png" alt="GR Antibody validated in ChIP-seq" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig2E.png" alt="GR Antibody ChIP-seq Grade" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 2. ChIP-seq results obtained with the Diagenode monoclonal antibody directed against hGR </strong><br />ChIP was performed on sheared chromatin from 3.5 million HeLaB2 cells using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). The cells were treated with the synthetic GR ligand triamcinolone acetonide (TA) for 4 hours prior to harvesting. The IP’d DNA was subsequently analysed on an Illumina Genome Analyzer. Library preparation, cluster generation and sequencing were performed according to the manufacturer’s instructions. The 36 bp tags were aligned to the human genome using the ELAND algorithm. Figure 2 shows the peak distribution along the complete sequence of chromosome 16 (figure 2A) as well as the MT2A positive control gene (figure 2B). The position of the PCR amplicon is also indicated. Figure 2C, D and E show the results for the known GR target genes PER1 on chromosome 17 and FKBP5 and TNFAIP3 on chromosome 6. </small></p> </div> </div> <p></p> <div class="row"> <div class="small-6 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig3.png" alt="GR Antibody ELISA Validation" /></p> </div> <div class="small-6 columns"> <p><small><strong> Figure 3. Sandwich ELISA </strong><br />The specificity of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050) was assessed by sandwich ELISA. Figure 3A: schematic representation of the sandwich ELISA with the monoclonal antibody against hGR (clone #:m2F8). Figure 3B: ELISA results using the monoclonal antibody against hGR at a concentration of 0.5 μg/ml. The figure shows an ELISA signal which is proportionally increasing with increasing amounts of recombinant hGR. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig4.png" alt="GR Antibody validated in Western Blot" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 4. Western blot analysis using the Diagenode monoclonal antibody against hGR </strong><br />Figure 4A. Extracts from HeLa cells containing the indicated amounts of GR (from 30 to 240 fmol), and from 5x10e6 Raji or Molt cells were analysed by Western blot using the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050). Figure 4B. Western blot analysis of extracts from 300,000 HeLa cells with the Diagenode monoclonal antibody against hGR (concentration 1 μg/ml). </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig5.png" alt="GR Antibody validated in Immunohistochemistry" /></p> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig6.png" alt="GR Antibody validated for Immunohistochemistry" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 5. Immunohistochemistry and immunofluorescence using the Diagenode monoclonal antibody against hGR </strong><br />1. Immunoreactivity of the Diagenode monoclonal antibody against hGR (Cat. No. MAb-010-050) in rat CA1 neurons of hippocampus. The antibody was used at a concentration of 2.5 μg/ml. <br />2. COS-7 cells transiently overexpressing human GR were labeled with the antibody against hGR followed by a biotinylated secondary antibody and peroxidase-labeled avidin. The antibody was used at a concentration of 2.5 μg/ml. </small></p> </div> </div> <div class="row"> <div class="small-4 columns"> <p><img src="https://www.diagenode.com/img/product/antibodies/C15200010_fig7.png" alt="GR Antibody validated in Immunoprecipitation" /></p> </div> <div class="small-8 columns"> <p><small><strong> Figure 6. Immunoprecipitation using the Diagenode monoclonal antibody against hGR </strong><br />The glucocorticoid receptor was immunoprecipitated from HeLa cell extracts (5 million HeLa cells in 100 μl IP reaction solution) using 5 μg of the Diagenode monoclonal antibody directed against hGR (Cat. No. MAb-010-050). The IP was followed by Western blot analysis as described above </small></p> </div> </div>', 'label2' => 'Target Description', 'info2' => '<p>Monoclonal antibody raised in mouse against amino acids 304-428 of the human GR (glucocorticoid receptor), using a chimeric protein.</p>', 'label3' => '', 'info3' => '', 'format' => '50 µg', 'catalog_number' => 'C15200010', 'old_catalog_number' => 'MAb-010-050', 'sf_code' => 'C15200010-D001-000581', 'type' => 'FRE', 'search_order' => '03-Antibody', 'price_EUR' => '380', 'price_USD' => '380', 'price_GBP' => '340', 'price_JPY' => '59525', 'price_CNY' => '', 'price_AUD' => '950', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => true, 'last_datasheet_update' => '0000-00-00', 'slug' => 'gr-monoclonal-antibody-classic-50-ug-50-ul', 'meta_title' => 'GR Antibody - ChIP-seq Grade (C15200010) | Diagenode', 'meta_keywords' => '', 'meta_description' => 'GR (Glucocorticoid receptor) Monoclonal Antibody validated in ChIP-seq, ChIP-qPCR, WB, Flow Cyt, IP and ELISA. Batch-specific data available on the website. Alternative names: NR3C1, GCCR, GCR, GRL. Sample size avaialble.', 'modified' => '2024-11-19 16:56:51', 'created' => '2015-06-29 14:08:20' ) $img = 'banners/banner-cut_tag-chipmentation-500.jpg' $label = '<img src="/img/banners/banner-customizer-back.png" alt=""/>' $application = array( 'id' => '34', 'position' => '10', 'parent_id' => '40', 'name' => 'Flow Cyt', 'description' => '<p>Flow cyt</p>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'flow-cytometry', 'meta_keywords' => 'Flow cytometry,Flow cyt,Monoclonal antibody,GR monoclonal antibody ', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for Flow cytometry applications', 'meta_title' => 'Flow cytometry - Monoclonal antibody | Diagenode', 'modified' => '2016-01-13 12:24:36', 'created' => '2015-07-08 13:53:00', 'ProductsApplication' => array( 'id' => '4648', 'product_id' => '2893', 'application_id' => '34' ) ) $slugs = array( (int) 0 => 'flow-cytometry' ) $applications = array( 'id' => '34', 'position' => '10', 'parent_id' => '40', 'name' => 'Flow Cyt', 'description' => '<p>Flow cyt</p>', 'in_footer' => false, 'in_menu' => false, 'online' => true, 'tabular' => true, 'slug' => 'flow-cytometry', 'meta_keywords' => 'Flow cytometry,Flow cyt,Monoclonal antibody,GR monoclonal antibody ', 'meta_description' => 'Diagenode offers a wide range of antibodies and technical support for Flow cytometry applications', 'meta_title' => 'Flow cytometry - Monoclonal antibody | Diagenode', 'modified' => '2016-01-13 12:24:36', 'created' => '2015-07-08 13:53:00', 'locale' => 'jpn' ) $description = '<p>Flow cyt</p>' $name = 'Flow Cyt' $document = array( 'id' => '440', 'name' => 'Datasheet hGR C15200010', 'description' => '<p>Datasheet description</p>', 'image_id' => null, 'type' => 'Datasheet', 'url' => 'files/products/antibodies/Datasheet_hGR_C15200010.pdf', 'slug' => 'datasheet-hgr-C15200010', 'meta_keywords' => '', 'meta_description' => '', 'modified' => '2015-11-20 17:16:18', 'created' => '2015-07-07 11:47:44', 'ProductsDocument' => array( 'id' => '2348', 'product_id' => '2893', 'document_id' => '440' ) ) $sds = array( 'id' => '562', 'name' => 'GR antibody SDS BE nl', 'language' => 'nl', 'url' => 'files/SDS/GR/SDS-C15200010-GR_Antibody-BE-nl-GHS_2_0.pdf', 'countries' => 'BE', 'modified' => '2020-07-01 14:47:51', 'created' => '2020-07-01 14:47:51', 'ProductsSafetySheet' => array( 'id' => '1083', 'product_id' => '2893', 'safety_sheet_id' => '562' ) ) $publication = array( 'id' => '253', 'name' => 'Coactivation of GR and NFKB alters the repertoire of their binding sites and target genes.', 'authors' => 'Rao NA, McCalman MT, Moulos P, Francoijs KJ, Chatziioannou A, Kolisis FN, Alexis MN, Mitsiou DJ, Stunnenberg HG', 'description' => 'Glucocorticoid receptor (GR) exerts anti-inflammatory action in part by antagonizing proinflammatory transcription factors such as the nuclear factor kappa-b (NFKB). Here, we assess the crosstalk of activated GR and RELA (p65, major NFKB component) by global identification of their binding sites and target genes. We show that coactivation of GR and p65 alters the repertoire of regulated genes and results in their association with novel sites in a mutually dependent manner. These novel sites predominantly cluster with p65 target genes that are antagonized by activated GR and vice versa. Our data show that coactivation of GR and NFKB alters signaling pathways that are regulated by each factor separately and provide insight into the networks underlying the GR and NFKB crosstalk.', 'date' => '2011-09-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/21750107', 'doi' => '', 'modified' => '2015-07-24 15:38:57', 'created' => '2015-07-24 15:38:57', 'ProductsPublication' => array( 'id' => '2027', 'product_id' => '2893', 'publication_id' => '253' ) ) $externalLink = ' <a href="https://www.ncbi.nlm.nih.gov/pubmed/21750107" target="_blank"><i class="fa fa-external-link"></i></a>'include - APP/View/Products/view.ctp, line 755 View::_evaluate() - CORE/Cake/View/View.php, line 971 View::_render() - CORE/Cake/View/View.php, line 933 View::render() - CORE/Cake/View/View.php, line 473 Controller::render() - CORE/Cake/Controller/Controller.php, line 963 ProductsController::slug() - APP/Controller/ProductsController.php, line 1052 ReflectionMethod::invokeArgs() - [internal], line ?? 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