Anti-Rad21抗体- ChIP Grade (ab992)

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ab992 被引用在 44 文献中.

  • Quigley IK & Kintner C Rfx2 Stabilizes Foxj1 Binding at Chromatin Loops to Enable Multiciliated Cell Gene Expression. PLoS Genet 13:e1006538 (2017). ChIP ; Xenopus laevis . PubMed: 28103240
  • Uusküla-Reimand L  et al. Topoisomerase II beta interacts with cohesin and CTCF at topological domain borders. Genome Biol 17:182 (2016). WB, ChIP . PubMed: 27582050
  • Rahman S  et al. Cohesin recruits the Esco1 acetyltransferase genome wide to repress transcription and promote cohesion in somatic cells. Proc Natl Acad Sci U S A 112:11270-5 (2015). PubMed: 26305936
  • Majumder K  et al. Domain-Specific and Stage-Intrinsic Changes in Tcrb Conformation during Thymocyte Development. J Immunol 195:1262-72 (2015). ChIP ; Mouse . PubMed: 26101321
  • Qiu Z  et al. Functional interactions between NURF and Ctcf regulate gene expression. Mol Cell Biol 35:224-37 (2015). PubMed: 25348714
  • Lavagnolli T  et al. Initiation and maintenance of pluripotency gene expression in the absence of cohesin. Genes Dev 29:23-38 (2015). WB, ChIP . PubMed: 25561493
  • Gosalia N  et al. Architectural proteins CTCF and cohesin have distinct roles in modulating the higher order structure and expression of the CFTR locus. Nucleic Acids Res 42:9612-22 (2014). ChIP ; Human . PubMed: 25081205
  • Günal-Sadik G  et al. Stage-specific binding profiles of cohesin in resting and activated B lymphocytes suggest a role for cohesin in immunoglobulin class switching and maturation. PLoS One 9:e111748 (2014). ChIP ; Mouse . PubMed: 25375358
  • Yun WJ  et al. The hematopoietic regulator TAL1 is required for chromatin looping between the ß-globin LCR and human ?-globin genes to activate transcription. Nucleic Acids Res 42:4283-93 (2014). WB ; Human . PubMed: 24470145
  • Dluhosova M  et al. Epigenetic control of SPI1 gene by CTCF and ISWI ATPase SMARCA5. PLoS One 9:e87448 (2014). ChIP ; Human . PubMed: 24498324
  • Chen HS  et al. Epigenetic deregulation of the LMP1/LMP2 locus of Epstein-Barr virus by mutation of a single CTCF-cohesin binding site. J Virol 88:1703-13 (2014). PubMed: 24257606
  • Winters T  et al. Meiotic cohesin STAG3 is required for chromosome axis formation and sister chromatid cohesion. EMBO J 33:1256-70 (2014). PubMed: 24797474
  • Matsumoto K  et al. Construction of mate pair full-length cDNAs libraries and characterization of transcriptional start sites and termination sites. Nucleic Acids Res N/A:N/A (2014). ChIP ; Human . PubMed: 25034687
  • Quintin J  et al. Dynamic estrogen receptor interactomes control estrogen-responsive trefoil Factor (TFF) locus cell-specific activities. Mol Cell Biol 34:2418-36 (2014). PubMed: 24752895
  • Makhlouf M  et al. A prominent and conserved role for YY1 in Xist transcriptional activation. Nat Commun 5:4878 (2014). PubMed: 25209548
  • Xu M  et al. CTCF controls HOXA cluster silencing and mediates PRC2-repressive higher-order chromatin structure in NT2/D1 cells. Mol Cell Biol 34:3867-79 (2014). PubMed: 25135475
  • Stong N  et al. Subtelomeric CTCF and cohesin binding site organization using improved subtelomere assemblies and a novel annotation pipeline. Genome Res 24:1039-50 (2014). ChIP ; Human . PubMed: 24676094
  • Tark-Dame M  et al. Depletion of the chromatin looping proteins CTCF and cohesin causes chromatin compaction: insight into chromatin folding by polymer modelling. PLoS Comput Biol 10:e1003877 (2014). PubMed: 25299688
  • Heidari N  et al. Genome-wide map of regulatory interactions in the human genome. Genome Res 24:1905-17 (2014). Human . PubMed: 25228660
  • Iglesias-Platas I  et al. Imprinting at the PLAGL1 domain is contained within a 70-kb CTCF/cohesin-mediated non-allelic chromatin loop. Nucleic Acids Res 41:2171-9 (2013). ChIP ; Human . PubMed: 23295672
  • Li W  et al. Functional roles of enhancer RNAs for oestrogen-dependent transcriptional activation. Nature 498:516-20 (2013). PubMed: 23728302
  • Choi NM  et al. Deep sequencing of the murine IgH repertoire reveals complex regulation of nonrandom v gene rearrangement frequencies. J Immunol 191:2393-402 (2013). PubMed: 23898036
  • Seitan VC  et al. Cohesin-based chromatin interactions enable regulated gene expression within preexisting architectural compartments. Genome Res 23:2066-77 (2013). ChIP ; Human . PubMed: 24002784
  • Ren L  et al. CTCF mediates the cell-type specific spatial organization of the Kcnq5 locus and the local gene regulation. PLoS One 7:e31416 (2012). ChIP ; Human . PubMed: 22347474
  • Taberlay PC  et al. Polycomb-repressed genes have permissive enhancers that initiate reprogramming. Cell 147:1283-94 (2011). ChIP ; Human . PubMed: 22153073
  • Xiao T  et al. Specific Sites in the C Terminus of CTCF Interact with the SA2 Subunit of the Cohesin Complex and Are Required for Cohesin-Dependent Insulation Activity. Mol Cell Biol 31:2174-83 (2011). WB ; Human . PubMed: 21444719
  • Chatterjee S  et al. Dynamic changes in binding of immunoglobulin heavy chain 3' regulatory region to protein factors during class switching. J Biol Chem 286:29303-12 (2011). ChIP ; Mouse . PubMed: 21685395
  • Kahyo T  et al. A novel tumor-derived SGOL1 variant causes abnormal mitosis and unstable chromatid cohesion. Oncogene 30:4453-63 (2011). PubMed: 21532624
  • Paakinaho V  et al. Glucocorticoid receptor activates poised FKBP51 locus through long-distance interactions. Mol Endocrinol 24:511-25 (2010). PubMed: 20093418
  • Ramachandrareddy H  et al. BCL6 promoter interacts with far upstream sequences with greatly enhanced activating histone modifications in germinal center B cells. Proc Natl Acad Sci U S A : (2010). ChIP ; Human . PubMed: 20547840
  • Manning AL  et al. Loss of pRB causes centromere dysfunction and chromosomal instability. Genes Dev 24:1364-76 (2010). WB, ICC/IF ; Human . PubMed: 20551165
  • Schmidt D  et al. A CTCF-independent role for cohesin in tissue-specific transcription. Genome Res 20:578-88 (2010). ChIP ; Human . PubMed: 20219941
  • Degner SC  et al. Cutting edge: developmental stage-specific recruitment of cohesin to CTCF sites throughout immunoglobulin loci during B lymphocyte development. J Immunol 182:44-8 (2009). ChIP ; Mouse . PubMed: 19109133
  • Hadjur S  et al. Cohesins form chromosomal cis-interactions at the developmentally regulated IFNG locus. Nature 460:410-3 (2009). ChIP ; Mouse . PubMed: 19458616
  • Bowers SR  et al. A conserved insulator that recruits CTCF and cohesin exists between the closely related but divergently regulated interleukin-3 and granulocyte-macrophage colony-stimulating factor genes. Mol Cell Biol 29:1682-93 (2009). ChIP ; Human . PubMed: 19158269
  • Røe OD  et al. Genome-wide profile of pleural mesothelioma versus parietal and visceral pleura: the emerging gene portrait of the mesothelioma phenotype. PLoS One 4:e6554 (2009). IHC-P ; Human . PubMed: 19662092
  • Liu J  et al. SMC1A expression and mechanism of pathogenicity in probands with X-Linked Cornelia de Lange syndrome. Hum Mutat 30:1535-42 (2009). WB ; Human . PubMed: 19701948
  • Li Z  et al. Characterization of viral and human RNAs smaller than canonical MicroRNAs. J Virol 83:12751-8 (2009). WB ; Human . PubMed: 19812168
  • Wendt KS  et al. Cohesin mediates transcriptional insulation by CCCTC-binding factor. Nature : (2008). ChIP ; Human . PubMed: 18235444
  • Hou C  et al. CTCF-dependent enhancer-blocking by alternative chromatin loop formation. Proc Natl Acad Sci U S A 105:20398-403 (2008). ChIP ; Mouse . PubMed: 19074263
  • Díaz-Martínez LA  et al. Regulation of centromeric cohesion by sororin independently of the APC/C. Cell Cycle 6:714-24 (2007). PubMed: 17361102
  • Díaz-Martínez LA  et al. Cohesin is dispensable for centromere cohesion in human cells. PLoS ONE 2:e318 (2007). WB ; Human . PubMed: 17389909
  • Seitan VC  et al. Metazoan Scc4 homologs link sister chromatid cohesion to cell and axon migration guidance. PLoS Biol 4:e242 (2006). PubMed: 16802858
  • Giménez-Abián JF  et al. Regulated separation of sister centromeres depends on the spindle assembly checkpoint but not on the Anaphase Promoting Complex/Cyclosome. Cell Cycle 4:1561-75 (2005). PubMed: 16205119