| MTA1 antibodies | |
| This is a review about MTA1 antibodies, based on 6 published articles using MTA1 antibodies in western blot, immunohistochemistry, immunoprecipitation, immunocytochemistry, and other immunological technologies. It is aimed to help ExactAntigen visitors find the most suited MTA1 antibody. Information in this review (with links to publications) can be searched freely. |
SIGMA-ALDRICH search Sigma-Aldrich MTA1 products
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| ih | | Sigma MTA1 antibody was tested in immunohistochemistry by Human Protein Atlas. |
SANTA CRUZ BIOTECHNOLOGY search Santa Cruz Biotechnology MTA1 products
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| ih, wb | | Santa Cruz Biotechnology anti-MTA1 monoclonal (A11) sc-17773 antibody was used in western blot and immunohistochemistry to study its role in prostate cancer progression. |
| ip, wb | | Santa Cruz Biotechnology anti-MTA1 antibody was used in western blot and immunoprecipitation to study the interaction between MTA1 and MAT1. |
| wb | | Santa Cruz Biotechnology MTA1 antibody C-17used in western blot to study the function for REA as a mediator of transcriptional repression by nuclear hormone receptors via recruitment of histone deacetylases. |
| wb | | Santa Cruz Biotechnology goat anti-MTA1 antibody was used in western blot to study MTA1-mediated repression of 92-kDa type IV collagenase expression. |
| wb | | Santa Cruz Biotechnology anti-MTA1 antibody was used in western blot to study that MBD3L2 interacts with MBD3 and components of the NuRD complex and can oppose MBD2-MeCP1-mediated methylation silencing. |
Articles Reviewed |
| 1. Chunhong Yan et al. Repression of 92-kDa type IV collagenase expression by MTA1 is mediated through direct interactions with the promoter via a mechanism, which is both dependent on and independent of histone deacetylation. 2003 |
| 2. Amjad H Talukder et al. MTA1 interacts with MAT1, a cyclin-dependent kinase-activating kinase complex ring finger factor, and regulates estrogen receptor transactivation functions. 2003 |
| 3. Matthias D Hofer et al. The role of metastasis-associated protein 1 in prostate cancer progression. 2004 |
| 4. Vladislav Kurtev et al. Transcriptional regulation by the repressor of estrogen receptor activity via recruitment of histone deacetylases. 2004 |
| 5. Seung-Gi Jin et al. MBD3L2 interacts with MBD3 and components of the NuRD complex and can oppose MBD2-MeCP1-mediated methylation silencing. 2005 |
| 6. Anja Persson et al. A human protein atlas based on antibody proteomics. 2006 |
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