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

Recent studies have shown that the protein CTCF, which plays an important role in insulation and in large-scale organization of chromatin within the eukaryotic nucleus, depends for both activities on recruitment of the cohesin complex. We show here that the interaction of CTCF with the cohesin complex involves direct contacts between the cohesin subunit SA2 and specific regions of the C-terminal tail of CTCF. All other cohesin components are recruited through their interaction with SA2. Expression in vivo of CTCF mutants lacking the C-terminal domain, or with mutations at sites within it required for SA2 binding, disrupts the normal expression profile of the imprinted genes IGF2-H19 and also results in a loss of insulation activity. Taken together, our results demonstrate that specific sites on the C terminus of CTCF are essential for cohesin binding and insulator function. The only direct interaction between CTCF and cohesin involves contact with SA2, which is external to the cohesin ring. This suggests that in recruiting cohesin to CTCF, SA2 could bind first and the ring could assemble subsequently.     

原钙粘蛋白基因簇调控区域中成簇的CTCF结合位点分析

哺乳动物中原钙粘蛋白(Protocadherin, Pcdh)基因簇包含50多个串联排列的基因,这些基因形成3个紧密相连的基因簇(Pcdhα、Pcdhβ和Pcdhγ),所编码的原钙粘蛋白质群在神经元多样性(Neuronal diversity)和单细胞特异性(Single cell identity)以及神经突触信号转导中发挥重要作用。前期的工作已证实转录因子CTCF(CCCTC-binding factor)与CTCF结合位点(CTCF-binding site, CBS)的方向性结合能够决定增强子和启动子环化的方向以及其远距离交互作用的特异性,并进一步在Pcdh基因座(Locus)形成两个(Pcdhα和Pcdhγ)染色质拓扑结构域(CTCF/cohesin- mediated chromatin domain, CCD),而且染色质拓扑结构域对于控制基因表达调控至关重要。本文通过生物信息学方法对比人类和小鼠序列,发现Pcdhβγ染色质拓扑结构域调控区域中的DNase I超敏位点(DNase I hypersensitive sites, HSs)较为保守。染色质免疫沉淀及大规模测序实验(Chromatin immunoprecipitation and massive parallel sequencing, ChIP-Seq)揭示CBS位点在Pcdhβγ调控区域中成簇分布并且具有相同的方向。凝胶电泳迁移实验(Electrophoresis mobility shift assay, EMSA)确定Pcdhβγ调控区域内具体的42 bp CBS位点并且发现一个CTCF峰包含两个CBS位点。在全基因组范围内,运用计算生物学方法分析CTCF和增强子、启动子等调控元件的关系,发现CBS位点在调控元件附近有较多分布,推测CTCF通过介导增强子和启动子的特异性交互作用,在细胞核三维基因组内形成活性转录枢纽调控基因精准表达。     

黏着素与基因表达调控

黏着素(cohesin)是一种多亚基蛋白复合体,在进化上相当保守。在真核生物细胞中,黏着素主要功能是将复制产生的姐妹染色单体连接在一起,直到细胞分裂的后期,黏着素亚基Scc1水解最终导致染色单体的分离。但是最近研究表明,黏着素在基因表达、染色质结构变化和发育调节等方面也起着非常重要的作用,并且发现黏着素对基因的调节作用与其对染色体的黏着功能无关。在酵母中,黏着素最初定位于其装载蛋白Scc2的DNA结合位点上,但是在细胞周期的G2期,黏着素聚集于转录汇集区之间进而调控转录终止。在果蝇染色体上,黏着素与装载蛋白Scc2的同源物Nipped-B共定位,其作用是阻抑增强子和启动子的远距离接触。而在哺乳动物中,黏着素与CTCF隔离子蛋白共定位,并以依赖于CTCF的方式调控转录。本文概述了黏着素在不同真核生物染色体上的定位与分布,并对其在基因表达调控中的功能机制及其研究现状进行了重点阐述。     

On the choreography of genome folding: A grand pas de deux of cohesin and CTCF

Cohesin and CTCF are key to the 3D folding of interphase chromosomes. Cohesin forms chromatin loops via loop extrusion, a process that involves the formation and enlargement of DNA loops. The architectural protein CTCF controls this process by acting as an anchor for chromatin looping. How CTCF controls cohesin has long been a mystery. Recent work shows that CTCF dictates chromatin looping via a direct interaction of its N-terminus with cohesin. CTCF's ability to regulate chromatin looping turns out to also be partially dependent on several RNA-binding domains. In this review, we discuss recent insights and consider how cohesin and CTCF together may orchestrate the folding of the genome into chromosomal loops.     

Cohesin mediates chromatin interactions that regulate mammalian β-globin expression

The β-globin locus undergoes dynamic chromatin interaction changes in differentiating erythroid cells that are thought to be important for proper globin gene expression. However, the underlying mechanisms are unclear. The CCCTC-binding factor, CTCF, binds to the insulator elements at the 5' and 3' boundaries of the locus, but these sites were shown to be dispensable for globin gene activation. We found that, upon induction of differentiation, cohesin and the cohesin loading factor Nipped-B-like (Nipbl) bind to the locus control region (LCR) at the CTCF insulator and distal enhancer regions as well as at the specific target globin gene that undergoes activation upon differentiation. Nipbl-dependent cohesin binding is critical for long-range chromatin interactions, both between the CTCF insulator elements and between the LCR distal enhancer and the target gene. We show that the latter interaction is important for globin gene expression in vivo and in vitro. Furthermore, the results indicate that such cohesin-mediated chromatin interactions associated with gene regulation are sensitive to the partial reduction of Nipbl caused by heterozygous mutation. This provides the first direct evidence that Nipbl haploinsufficiency affects cohesin-mediated chromatin interactions and gene expression. Our results reveal that dynamic Nipbl/cohesin binding is critical for developmental chromatin organization and the gene activation function of the LCR in mammalian cells.     

Histone tail-independent chromatin binding activity of recombinant cohesin holocomplex

Cohesin, an SMC (structural maintenance of chromosomes) protein-containing complex, governs several important aspects of chromatin dynamics, including the essential chromosomal process of sister chromatid cohesion. The exact mechanism by which cohesin achieves the bridging of sister chromatids is not known. To elucidate this mechanism, we reconstituted a recombinant cohesin complex and investigated its binding to DNA fragments corresponding to natural chromosomal sites with high and low cohesin occupancy in vivo. Cohesin displayed uniform but nonspecific binding activity with all DNA fragments tested. Interestingly, DNA fragments with high occupancy by cohesin in vivo showed strong nucleosome positioning in vitro. We therefore utilized a defined model chromatin fragment (purified reconstituted dinucleosome) as a substrate to analyze cohesin interaction with chromatin. The four-subunit cohesin holocomplex showed a distinct chromatin binding activity in vitro, whereas the Smc1p-Smc3p dimer was unable to bind chromatin. Histone tails and ATP are dispensable for cohesin binding to chromatin in this reaction. A model for cohesin association with chromatin is proposed.     

How DNA loop extrusion mediated by cohesin enables V(D)J recombination

‘Structural maintenance of chromosomes’ (SMC) complexes are required for the folding of genomic DNA into loops. Theoretical considerations and single-molecule experiments performed with the SMC complexes cohesin and condensin indicate that DNA folding occurs via loop extrusion. Recent work indicates that this process is essential for the assembly of antigen receptor genes by V(D)J recombination in developing B and T cells of the vertebrate immune system. Here, I review how recent studies of the mouse immunoglobulin heavy chain locus Igh have provided evidence for this hypothesis and how the formation of chromatin loops by cohesin and regulation of this process by CTCF and Wapl might ensure that all variable gene segments in this locus (V_H segments) participate in recombination with a re-arranged DJ_H segment, to ensure generation of a maximally diverse repertoire of B-cell receptors and antibodies.     

Quantitative analysis of cohesin complex stoichiometry and SMC3 modification-dependent protein interactions

Cohesin is a protein complex that plays an essential role in pairing replicated sister chromatids during cell division. The vertebrate cohesin complex consists of four core components including structure maintenance of chromosomes proteins SMC1 and SMC3, RAD21, and SA2/SA1. Extensive research suggests that cohesin traps the sister chromatids by a V-shaped SMC1/SMC3 heterodimer bound to the RAD21 protein that closes the ring. Accordingly, the single "ring" model proposes that two sister chromatids are trapped in a single ring that is composed of one molecule each of the 4 subunits. However, evidence also exists for alternative models. The hand-cuff model suggests that each sister chromatid is trapped individually by two rings that are joined through the shared SA1/SA2 subunit. We report here the determination of cohesin subunit stoichiometry of endogenous cohesin complex by quantitative mass spectrometry. Using qConCAT-based isotope labeling, we show that the cohesin core complex contains equimolar of the 4 core components, suggesting that each cohesin ring is closed by one SA1/SA2 molecule. Furthermore, we applied this strategy to quantify post-translational modification-dependent cohesin interactions. We demonstrate that quantitative mass spectrometry is a powerful tool for measuring stoichiometry of endogenous protein core complex.