CTCF is a highly conserved, multi-functional nuclear factor that involved both in global genome architecture and in many aspects of gene regulation, the latter ranging from the direct gene repression/activation to enhancer blocking and hormone-facilitated silencing. CTCF contains a highly conserved 11 Zn-finger DNA-binding domain that mediates sequence-specificity of DNA binding. As we discovered, CTCF functions through two major mechanisms: either direct regulation of a gene downstream of CTSes or indirect regulation via the formation of chromatin loops. The chromatin loops, stabilized by CTCF dimerization, affect relationships among promoters, enhancers and/or ICRs. Dimerization activity of DNA-bound CTCF may potentially be at the core of its activity as a versatile chromatin-bridging and chromatin-looping agent in most cell types, underlying its core biological functions. Furthermore, the loop-forming activity of CTCF can be naturally extended to formation of localized somatic inter-chromosome pairing sites that therefore acquire potential for epigenetic co-regulation such as transcription factories, DNA replication factories, and DNA repair foci. Many other chromatin-anchored functions, such as the establishment of imprinting marks and their reading, X-chromosome inactivation, and apoptosis are regulated by CTCF. CTCF has emerged as a key facilitator of 3D organization of interphase chromatin, as well as a major player in cell proliferation control. In some cases, the loop-forming activity of CTCF was found to be accompanied/complemented by the more direct regulation of a particular gene. This mixed mode regulation is likely the most appropriate representation of a native gene regulation framework. We also identified a novel CTCF activity that directly links CTCF to transcriptional machinery binding of CTCF to Pol II. This novel pathway provides either a mechanism for opening loop-independent transcription start sites downstream of the promoter-determined +1 site (at intron/exon sequences) or may have specifically evolved to induce non-coding transcripts throughout the genome. Mechanistically, the regulated recruitment and the subsequent release of Pol II from a DNA-bound CTCF complex indicates that the CTCF site itself could act as an attenuator and/or promoter in some locations in the genome. While CTCF is mostly known as a regulator of gene expression, our data on its potential functions in heterochromatin and centrosomes, as well as its roles in mitosis and meiosis, suggested a significant housekeeping role of CTCF in genome organization and chromosome segregation. CTCF was previously shown to undergo a variety of posttranslational modifications, and we expanded these studies to characterize novel modifications. Another pathological aspect of the deregulated CTCF occupancy of promoter targets sites is aberrant DNA methylation in cancers. Both of these novel biological roles of CTCF are subjects of ongoing studies in the MPS. We previously analyzed genome-wide CTCF targets for the first time (Cell 2007, vol. 128, pp1231-1245), and the fundamental roles of CTCF in cellular functions were validated by a strong correlation of CTSs with gene positions in human genome. By virtue of having so many vital functions CTCF became an essential gene in vertebrates, as CTCF-knockout mice are non-viable (lethality at the very early embryonic stages). With respect to human disease, CTCF is a candidate tumor suppressor gene (TSG);several functional point mutations in the 11ZF DBD of CTCF have been characterized in primary cancers, in combination with the LOH of the CTCF locus. In the past year, we studied several loci in order to understand contributions of CTCF CTSes to their regulation. They included genes important for immune responses, as well as genes with a potential for the development of approaches for cancer treatment. As a general rule, we have found that if a CTCF binding site is located upstream of the transcriptional start site, it tends to play an activator role, while CTSes located downstream of (+1) usually behave as repressors. The gene for catalytic subunit of human telomerase (hTERT) is one of the most prominent genes in this study.

Project Start
Project End
Budget Start
Budget End
Support Year
12
Fiscal Year
2011
Total Cost
$868,802
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Lobanenkov, Victor V; Zentner, Gabriel E (2018) Discovering a binary CTCF code with a little help from BORIS. Nucleus 9:33-41
Teplyakov, Evgeny; Wu, Qiongfang; Liu, Jian et al. (2017) The downregulation of putative anticancer target BORIS/CTCFL in an addicted myeloid cancer cell line modulates the expression of multiple protein coding and ncRNA genes. Oncotarget 8:73448-73468
Rivero-Hinojosa, Samuel; Kang, Sungyun; Lobanenkov, Victor V et al. (2017) Corrigendum: Testis-specific transcriptional regulators selectively occupy BORIS-bound CTCF target regions in mouse male germ cells. Sci Rep 7:46891
Rivero-Hinojosa, Samuel; Kang, Sungyun; Lobanenkov, Victor V et al. (2017) Testis-specific transcriptional regulators selectively occupy BORIS-bound CTCF target regions in mouse male germ cells. Sci Rep 7:41279
Pugacheva, Elena M; Teplyakov, Evgeny; Wu, Qiongfang et al. (2016) The cancer-associated CTCFL/BORIS protein targets multiple classes of genomic repeats, with a distinct binding and functional preference for humanoid-specific SVA transposable elements. Epigenetics Chromatin 9:35
Pugacheva, Elena M; Rivero-Hinojosa, Samuel; Espinoza, Celso A et al. (2015) Comparative analyses of CTCF and BORIS occupancies uncover two distinct classes of CTCF binding genomic regions. Genome Biol 16:161
Dixon, Jesse R; Jung, Inkyung; Selvaraj, Siddarth et al. (2015) Chromatin architecture reorganization during stem cell differentiation. Nature 518:331-6
Kemp, Christopher J; Moore, James M; Moser, Russell et al. (2014) CTCF haploinsufficiency destabilizes DNA methylation and predisposes to cancer. Cell Rep 7:1020-9
Mendez-Catala, Claudia Fabiola; Gretton, Svetlana; Vostrov, Alexander et al. (2013) A Novel Mechanism for CTCF in the Epigenetic Regulation of Bax in Breast Cancer Cells. Neoplasia 15:898-912
Nakahashi, Hirotaka; Kieffer Kwon, Kyong-Rim; Resch, Wolfgang et al. (2013) A genome-wide map of CTCF multivalency redefines the CTCF code. Cell Rep 3:1678-1689

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