特异AT序列结合蛋白2(SATB2)的研究进展

特异AT序列结合蛋白2(SATB2)是与核基质结合区结合的转录因子,在转录调控和染色质重组等过程中发挥重要作用。SATB2是成骨细胞分化和骨基质形成过程中的关键调控分子,其突变可导致先天性颌面部畸形的发生;SATB2是中枢神经系统发育过程中的核心分子,在胼胝体、脑桥等正常发育中起重要作用;SATB2也参与肿瘤的发生,在乳腺癌等恶性肿瘤中的表达升高。文章就上述各领域中SATB2的研究进展进行了综述。     

SATB1在基因表达调控中作用的研究进展

SATB1是一种组织特异性的核基质结合蛋白,参与了染色质高级结构的形成和组织特异性基因的表达调控,对于胸腺细胞的发育和T细胞的成熟起到了尤为重要的作用。虽然已经知道SATB1可以通过与MAR序列结合,以促进染色质重塑,调节组蛋白乙酰化和甲基化水平等多种途径对基因的表达进行调控,但是对于该过程所涉及到的分子机制仍然不是很清楚。本文对SATB1在基因表达调控方面的研究进展作一综述。     

核小体及染色质修饰的基因组分布模式和染色质状态

染色质是真核DNA的存在方式,可以通过影响DNA的可及性调节基因转录,其基本单元为核小体,系由约147 bp的DNA缠绕在组蛋白八联体上形成的结构,核小体之间以连接DNA相连．核小体组蛋白上能发生甲基化和乙酰化等化学修饰．核小体位置、DNA的甲基化和组蛋白的修饰等对染色质状态(常染色质或异染色质)及基因组之间的长程相互作用有重要影响．近年,基于高通量测序技术,核小体位置和染色质修饰在多种细胞中的基因组分布已被测定．结果显示,这些标记的分布模式具有位点特异、动态变化、相互偶联和高度复杂的特征．本文详细回顾并评述了核小体位置和染色质修饰的分布模式、对应生物学功能、修饰之间的关联、实验测定技术、染色质状态的计算分析等内容．该工作对于深入认识和理解染色质的表观遗传调节机制有重要意义．     

核基质与基因表达调控研究进展

核基质是细胞核内由一群复杂多样的非组蛋白构成的纤维网状结构。核基质蛋白具有明显的组织细胞特异性及肿瘤相关性。它作为细胞核的支架结构,在ＤＮＡ的复制、转录、ＲＮＡ加工修饰等重要的细胞内事件中起着支持和调节作用,并通过转录调节因子、核基质结合元件以及核基质蛋白与ＤＮＡ的相互作用等多种途径参与基因的表达调控     

核基质结合区结合蛋白质1--SATB1

SATB1是一种核基质结合区(MAR)结合蛋白质,以独特的模式识别并结合于MAR。近年来发现,SATB1参与了染色体的高级包装和组织特异性基因表达的负调控,敲除了SATB1基因的小鼠胸腺细胞无法正常发育,在凋亡过程中SATB1先于基因组DNA发生降解。对SATB1参与髓系细胞的分化和基因调控等方面的研究仍在进行,一般认为SATB1是通过改变染色体的高级包装行使功能。     

组蛋白泛素化修饰及其在DNA损伤应答中的作用

泛素化修饰是真核生物细胞内重要的翻译后修饰类型,通过调节蛋白质活性、稳定性和亚细胞定位广泛参与细胞内各项信号传导与代谢过程,对维持正常生命活动具有重要意义。组蛋白作为染色质中主要的蛋白成分,与DNA复制转录、修复等行为密切相关,是研究翻译后修饰的热点。DNA损伤后,组蛋白泛素化修饰通过调节核小体结构、激活细胞周期检查点、影响修复因子的招募与装配等诸多途径参与损伤应答。同时,组蛋白泛素化修饰还能调节其他位点翻译后修饰,并通过这种串扰(crosstalk)作用调节DNA损伤应答。本文介绍了组蛋白泛素化修饰的主要位点和相关组分(包括E3连接酶、去泛素化酶与效应分子),以及这些修饰作用共同编译形成的信号网络在DNA损伤应答中的作用,最后总结了目前该领域研究所面临的一些问题,以期为科研人员进一步探索组蛋白密码在DNA损伤应答中的作用提供参考。     

家蚕（Bombyx mori）5龄幼虫丝腺染色质在核基质上的组构

家蚕(Bombyx mori)5龄幼虫丝腺的染色质高度多倍化,整个基因组达10~5至10~6个拷贝。依次经低盐和高盐抽提5龄幼虫中丝腺、后丝腺和蚕体的细胞核,得到其核晕 (nuclearhalo),限制性内切酶消化后还有一部分DNA片段与核基质紧密结合在一起,说明染色质的组织与核基质有关。通过测定核基质上残留的DNA片段的平均长度及其在全基因组DNA中所占的百分比计算出,核晕上DNAloop的平均大小在中丝腺、后丝腺以及蚕体细胞中均为67kb左右。丝腺中高度多倍化的染色质与二倍体蚕体组织之间并不存在差异,它们同样被错定在核基质上而分隔成长约67kb的染色质loop,从而保证整个基因组的有序排列。以丝素基因为探针进行DNA印迹杂交发现,在5龄后丝腺中丝素基因特异性地和核基质紧密结合,说明核基质与丝素基因的组织特异性表达有关。     

核基质附着区广泛参与基因组三维结构折叠的生物信息学分析

在细胞分裂间期,每条染色质都占据着特定的染色质领域（chromosome territory,CT）。每个CT领域内进一步分成不同的拓扑学相关区域（topological associated domain,TAD）,每个TAD又由若干子TAD（sub-TAD）构成。不同的TAD相互聚集,形成基因活跃表达和不表达的A、B两种组份或区室（compartment）。然而,目前对于染色质折叠方式及维持机制的研究尚无定论。核基质附着区（matrix attachment regions,MARs）是在不同物种基因组中广泛存在的一类富含AT序列的与核基质结合的DNA元件,能够通过与CTCF、SATB1等调控蛋白质相互作用,对远距离的基因表达进行调控。本研究以染色质三维结构为背景,通过整合染色质三维结构及组蛋白修饰等组学数据,对MARs元件与染色质三维结构的关系进行研究,对MARs元件参与形成的相互作用网络的结构及功能进行探索。结果发现,MARs元件与染色质三维结构高度相关,而且在高强度相互作用中占据较大的比例,提示MARs元件在染色质折叠方面发挥作用。此外,通过拓扑结构聚类分析还首次揭示,MARs元件分为不同类型,包括维持染色质领域及空间构象等的结构单元部分,以及调控基因表达等的功能单元部分。这表明,MARs元件在基因组三维高级结构的建立、维持以及功能等方面发挥重要作用。     

DNA异常甲基化在宫颈癌中的研究进展

长期以来人们一直认为基因突变或基因缺失参与肿瘤的形成。近年来众多研究表明,表观遗传修饰对肿瘤的发展也具有非常重要的意义,它的主要表现形式有DNA甲基化、组蛋白修饰、微小RNA调节、染色质重组等。DNA异常甲基化可通过影响染色质结构、癌基因及抑癌基因表达而参与肿瘤的形成。了解目前宫颈癌中DNA甲基化的研究进展不仅有助于宫颈癌的早期诊断,对其分子靶向治疗及预后评估亦显示出良好的应用前景。     

DNA异常甲基化在宫颈癌中的研究进展

长期以来人们一直认为基因突变或基因缺失参与肿瘤的形成。近年来众多研究表明,表观遗传修饰对肿瘤的发展也具有非常重要的意义,它的主要表现形式有DNA甲基化、组蛋白修饰、微小RNA调节、染色质重组等。DNA异常甲基化可通过影响染色质结构、癌基因及抑癌基因表达而参与肿瘤的形成。了解目前宫颈癌中DNA甲基化的研究进展不仅有助于宫颈癌的早期诊断,对其分子靶向治疗及预后评估亦显示出良好的应用前景。     

SATB1 regulates β-like globin genes through matrix related nuclear relocation of the cluster

The nuclear location and relocation of genes play crucial regulatory roles in gene expression. SATB1, a MAR-binding protein, has been found to regulate β-like globin genes through chromatin remodeling. In this study, we generated K562 cells over-expressing wild-type or nuclear matrix targeting sequences (NMTS)-deficient SATB1 and found that like wild-type SATB1, NMTS-deficient SATB1 induces out loop of β-globin cluster from its chromosome territory (CT), while it is unable to associate the cluster with the nuclear matrix as wild-type SATB1 does and had no regulatory functions to the β-globin cluster. Besides, our data showed that the transacting factor occupancies and chromatin modifications at β-globin cluster were differentially affected by wild-type and NMTS-deficient SATB1. These results indicate that SATB1 regulates β-like globin genes at the nuclear level interlaced with chromatin and DNA level, and emphasize the nuclear matrix binding activity of SATB1 to its regulatory function.     

SATB1 regulates SPARC expression in K562 cell line through binding to a specific sequence in the third intron

Special AT-rich binding protein 1 (SATB1), a cell type-specific nuclear matrix attachment region (MAR) DNA-binding protein, tethers to a specific DNA sequence and regulates gene expression through chromatin remodeling and HDAC (histone deacetylase complex) recruitment. In this study, a SATB1 eukaryotic expression plasmid was transfected into the human erythroleukemia K562 cell line and individual clones that stably over-expressed the SATB1 protein were isolated. Microarray analysis revealed that hundreds of genes were either up- or down-regulated in the SATB1 over-expressing K562 cell lines. One of these was the extra-cellular matrix glycoprotein, SPARC (human secreted protein acidic and rich in cysteine). siRNA knock-down of SATB1 also reduced SPARC expression, which was consistent with elevated SPARC levels in the SATB1 over-expressing cell line. Bioinformatics software Mat-inspector showed that a 17bp DNA sequence in the third intron of SPARC possessed a high potential for SATB1 binding; a finding confirmed by Chromatin immunoprecipitation (ChIP) with anti-SATB1 antibody. Our results show for the first time that forced-expression of SATB1 in K562 cells triggers SPARC up-regulation by binding to a 17bp DNA sequence in the third intron.     

The structural basis for the oligomerization of the N-terminal domain of SATB1

Special AT-rich sequence-binding protein 1 (SATB1) is a global chromatin organizer and gene expression regulator essential for T-cell development and breast cancer tumor growth and metastasis. The oligomerization of the N-terminal domain of SATB1 is critical for its biological function. We determined the crystal structure of the N-terminal domain of SATB1. Surprisingly, this domain resembles a ubiquitin domain instead of the previously proposed PDZ domain. Our results also reveal that SATB1 can form a tetramer through its N-terminal domain. The tetramerization of SATB1 plays an essential role in its binding to highly specialized DNA sequences. Furthermore, isothermal titration calorimetry results indicate that the SATB1 tetramer can bind simultaneously to two DNA targets. Based on these results, we propose a molecular model whereby SATB1 regulates the expression of multiple genes both locally and at a distance.     

Crystal Structure of the Ubiquitin-like Domain-CUT Repeat-like Tandem of Special AT-rich Sequence Binding Protein 1 (SATB1) Reveals a Coordinating DNA-binding Mechanism

SATB1 is essential for T-cell development and growth and metastasis of multitype tumors and acts as a global chromatin organizer and gene expression regulator. The DNA binding ability of SATB1 plays vital roles in its various biological functions. We report the crystal structure of the N-terminal module of SATB1. Interestingly, this module contains a ubiquitin-like domain (ULD) and a CUT repeat-like (CUTL) domain (ULD-CUTL tandem). Detailed biochemical experiments indicate that the N terminus of SATB1 (residues 1–248, SATB1^(1–248)), including the extreme 70 N-terminal amino acids, and the ULD-CUTL tandem bind specifically to DNA targets. Our results show that the DNA binding ability of full-length SATB1 requires the contribution of the CUTL domain, as well as the CUT1-CUT2 tandem domain and the homeodomain. These findings may reveal a multiple-domain-coordinated mechanism whereby SATB1 recognizes DNA targets.