BRPF1及其新型转录本BRPF2与RHOX5蛋白间的相互作用

RHOX5基因是最早发现的小鼠RHOX基因簇(reproductive homeobox on the X chromosome)成员,可特异性地在生殖系统中表达.RHOX5蛋白在胚胎发育、生殖组织的发育、精子的生成和成熟等多个环节发挥作用,但其功能的发挥途径尚不明确.在前期筛选与RHOX5蛋白相互作用的分子中初步获得一个BRPF1的新型转录本BRPF2.进一步构建pGBKT7-BRPF2质粒,酵母双杂交实验确定其与RHOX5蛋白的相互作用,GST-pull down实验确定其在体外的直接结合;PCR扩增BRPF1基因,构建pGBKT7-BRPF1和pGADT7-BRPF1质粒,酵母双杂交实验和GST-pull down实验证明RHOX5蛋白亦可以直接结合BRPF1蛋白.BRPF1及其新型转录本BRPF2与RHOX5蛋白间的相互作用证实暗示了BRPF2极有可能与BRPF1竞争性结合RHOX5蛋白,为三种蛋白功能的研究提供了新的思路.     

染色质乙酰化相关BRD蛋白家族

Bromodomain结构域首先在果蝇蛋白质Brahma中发现,折叠模式独特且高度保守,是最早也是截至目前公认唯一可与乙酰化赖氨酸结合的结构域。BRD蛋白通过结合不同的蛋白质或者定位蛋白质到细胞核发挥精细调节作用。BRD蛋白复合物常特异性识别并结合到染色质组蛋白H3/H4特定的乙酰化赖氨酸残基,从而影响靶基因的转录翻译;该蛋白复合物功能异常通常与多种疾病的发生相关联,表明对转录翻译调节有重要意义。但迄今为止,BRD蛋白复合物修饰染色质机理不明,现有研究提示BRD蛋白复合物维持染色质乙酰化状态,也可以与染色质组蛋白其它位点结合,从整体水平增强组蛋白乙酰化精度和效率。     

含溴结构域蛋白2结构与功能的研究进展

含溴结构域蛋白2(bromodomain-containing protein 2,BRD2)具有两个串联的溴结构域和一个末端外结构域,是溴结构域和末端外结构域蛋白家族成员之一。BRD2蛋白能够特异性结合组蛋白乙酰化赖氨酸,参与基因的转录调控、染色质重塑和细胞增殖与凋亡等生物学活动。近年来研究表明,BRD2蛋白通过溴结构域和乙酰化组蛋白之间的表观遗传相互作用来调控基因转录和细胞周期、神经发育、炎症和脂肪生成,并且在肿瘤细胞增殖以及病毒感染和复制过程中也有着重要作用。该文主要从BRD2蛋白的结构特征、细胞功能和参与病毒复制的作用机制等方面进行综述,以期为深入研究BRD2蛋白的功能提供参考。     

BRD7结构功能域Bromodomain的研究以及一个新的BRD7交互作用蛋白的鉴定

溴区包含蛋白7(BRD7)是采用cDNA代表性差异分析方法克隆的一个新基因.研究证实了BRD7能够与乙酰化的组蛋白3结合,其识别位点在组蛋白3的14位氨基酸;并且证实了溴区结构域(Bromodomain)缺失型的BRD7突变体失去了与乙酰化组蛋白3的结合能力.Bromodomain是在进化上高度保守的功能结构域,该结构域在空间构象上具有鲜明的特征:包括4个左手、呈反向平行排列的“螺旋(αz,αA,αB,αC)”以及2个“连结环”(ZAloop,BCloop).通过生物信息学等综合分析,预测BRD7可能具有上述特征.依据上述分析结果,构建了BRD7的Bromodomain相关缺失突变体,通过肽段结合实验分析上述突变体与乙酰化组蛋白3结合的能力.结果表明,ZAloop与BCloop的完整性对于BRD7结合乙酰化的组蛋白3有着重要的意义.同时通过免疫荧光分析,证实了ZAloop与BCloop的完整性能够影响BRD7的亚细胞定位.最后,证实了BRD7与CBP可能存在交互作用.CBP不仅具有乙酰化转移酶活性(HATs),能够对组蛋白末端进行乙酰化修饰,并且作为一种重要的细胞转录因子广泛参与细胞的各种生物学活动.     

组蛋白降解调控机制的研究进展

组蛋白是染色质的重要组成部分,其含量的高低显著影响着染色质高级结构的形成、基因表达、DNA复制等重要生命活动。蛋白质降解是组蛋白含量调控的重要机制,大量研究表明,组蛋白的降解与其氨基酸残基的修饰方式有着密不可分的联系。此外,组蛋白的降解与其泛素化、乙酰化等共价修饰密切相关。该文以组蛋白氨基酸残基翻译后修饰(PTM)为关注点,重点介绍组蛋白降解与氨基酸残基修饰之间的相互关系,并对该领域的研究进展进行综述。     

抗人Elp3 的N末端抗体制备及在染色质免疫沉淀中的应用

人 Elp3（human elongator protein 3, hElp3）具有组蛋白乙酰转移酶活性,是与延伸中的 RNA 聚合酶Ⅱ结合的 elongator 复合物的催化亚基,可参与组蛋白的乙酰化修饰与基因的转录延伸. Elp3 及其复合物功能异常与人类多种疾病相关. 为运用染色质免疫沉淀等手段深入研究 Elp3 功能,PCR 法克隆 pYES2-hElp3 质粒中编码 hElp3的N端亲水区段（1～69 氨基酸残基）,构建原核表达载体 pMXB10-hElp3-210,经 IPTG 诱导和几丁质柱纯化后,免疫兔制备多克隆抗体. ELISA 检测显示,该抗体有较高的效价(不低于1∶2　500).免疫印迹实验结果表明,该抗体可与纯化的及 HeLa 细胞中的 hElp3 蛋白特异性结合.运用该抗体对转入 elp3Δ菌株的人 Elp3 的染色质免疫沉淀实验结果表明,人 Elp3 可参与酵母 SSA3 基因的转录调控,这可能是人Elp3 能够部分补偿酵母 SSA3 基因延迟表达缺陷的原因.     

KAP-1:转录调控中的一个桥梁分子

KAP-1(又称TIF1b, TRIM28等)是一种转录中介因子, 在诸多转录调控复合体中起桥梁作用。它通过其N端RBCC结构域与含KRAB结构域的锌指蛋白、MDM2、MM1、C/EBPb等相互作用; 通过C端的PHD及BrD结构域与SETDB1、Mi-2a等分子相互作用, 参与形成具有组蛋白甲基化酶或组蛋白去乙酰化酶活性的复合体; 通过中间的HP1BD区域与HP1蛋白相互作用, 进而与组蛋白相结合。大量研究表明, KAP-1作为一个桥梁分子, 主要以共抑制因子形式参与转录抑制复合体的形成, 在某些复合体中也可作为共激活因子发挥作用。KAP-1参与形成的复合体在精细胞发育、胚胎早期发育等生理过程中发挥重要的调控作用, 这种调控属于表观遗传调控范畴。     

粉菠萝组蛋白去乙酰化酶基因AfHDI的克隆及在乙烯处理下的表达分析

组蛋白修饰在植物发育和防御反应中发挥着重要的作用。为研究组蛋白去乙酰化酶基因肋,的基本特征及其在乙烯调控凤梨科植物开花过程中的生物学功能,通过筛选粉菠萝茎尖转录组测序数据并结合RACE技术分离得到AfHDl基因cDNA全长序列。该基因的开放阅读框长为1548bp,编码516个氨基酸,其理论分子量为58．28kDa,等电点为5．23。由该基因编码的蛋白属于组蛋白去乙酰化酶RPD3／HDAl超家族成员,具有该家族特有的HDAC保守结构域,该蛋白与水稻和玉米中HDl蛋白的同源性均达到87％。实时荧光定量PCR分析表明,AfItDI基因的表达受乙烯诱导,处理后1d的表达量与0h相比,提高了4倍,推测组蛋白去乙酰化酶基因AfHDJ可能与粉菠萝的乙烯信号反应有关。     

组蛋白修饰及其生物学效应

组蛋白是染色质的主要成分之一,其氨基端的氨基酸残基可以被共价修饰,进而改变染色质构型,导致转录激活或基因沉默。组蛋白修饰除了简单地调控基因表达,更在于它可以招募蛋白复合体,影响下游蛋白,从而参与细胞分裂、细胞凋亡和记忆形成,甚至影响免疫系统和炎症反应等。不仅如此,最近的研究表明,组蛋白修饰与CTD密码、生物节律、DNA修复之间也存在一定的联系。这些发现证明了组蛋白修饰的重要性。在组蛋白的密码形成与密码破译、修饰级联与招募蛋白质过程中,蛋白复合体的特殊结构域起到的中介作用都是无法替代的。因此,这些特殊结构域将是了解"组蛋白密码"的关键。目前质谱分析等技术的广泛应用,正使得许多新的结构域不断被发现。文章旨在对组蛋白密码的基本内容作一述评,同时对可能的研究热点进行展望。     

Chromodomain蛋白在表观遗传调控中的功能

克罗莫结构域 (chromatin organization modifier domain, chromodomain)是与染色质结构相关的进化上保守的蛋白质模体。Chromodomain中芳香族氨基酸残基组成保守的疏水“box”结构与“组蛋白密码”中的二甲基或三甲基修饰的H3K9和H3K27结合, 同时chromodomain也可识别非组蛋白和特定的核酸结构。不同类型的chromodomain蛋白在基因转录调节、基因组重排修复和染色质重塑等过程中发挥重要调控作用, 从多个层次参与染色质表观遗传调节过程。本文综述chromodomain的分类和结构特征, 探讨进化中不同的chromodomain蛋白在细胞中的功能多样性, 为进一步研究chromodomain蛋白在细胞中的作用机制提供参考。     

Structural insights into recognition of acetylated histone ligands by the BRPF1 bromodomain

Bromodomain-PHD finger protein 1 (BRPF1) is part of the MOZ HAT complex and contains a unique combination of domains typically found in chromatin-associated factors, which include plant homeodomain (PHD) fingers, a bromodomain and a proline-tryptophan-tryptophan-proline (PWWP) domain. Bromodomains are conserved structural motifs generally known to recognize acetylated histones, and the BRPF1 bromodomain preferentially selects for H2AK5ac, H4K12ac and H3K14ac. We solved the X-ray crystal structures of the BRPF1 bromodomain in complex with the H2AK5ac and H4K12ac histone peptides. Site-directed mutagenesis on residues in the BRPF1 bromodomain-binding pocket was carried out to investigate the contribution of specific amino acids on ligand binding. Our results provide critical insights into the molecular mechanism of ligand binding by the BRPF1 bromodomain, and reveal that ordered water molecules are an essential component driving ligand recognition.     

Bivalent interaction of the PZP domain of BRPF1 with the nucleosome impacts chromatin dynamics and acetylation

BRPF1 (bromodomain PHD finger 1) is a core subunit of the MOZ histone acetyltransferase (HAT) complex, critical for normal developmental programs and implicated in acute leukemias. BRPF1 contains a unique assembly of zinc fingers, termed a PZP domain, the physiological role of which remains unclear. Here, we elucidate the structure-function relationship of this novel epigenetic reader and detail the biological and mechanistic consequences of its interaction with nucleosomes. PZP has a globular architecture and forms a 2:1 stoichiometry complex with the nucleosome, bivalently interacting with histone H3 and DNA. This binding impacts the nucleosome dynamics, shifting the DNA unwrapping/rewrapping equilibrium toward the unwrapped state and increasing DNA accessibility. We demonstrate that the DNA-binding function of the BRPF1 PZP domain is required for the MOZ-BRPF1-ING5-hEaf6 HAT complex to be recruited to chromatin and to acetylate nucleosomal histones. Our findings reveal a novel link between chromatin dynamics and MOZ-mediated acetylation.     

BRPF3‐HBO1 regulates replication origin activation and histone H3K14 acetylation

During DNA replication, thousands of replication origins are activated across the genome. Chromatin architecture contributes to origin specification and usage, yet it remains unclear which chromatin features impact on DNA replication. Here, we perform a RNAi screen for chromatin regulators implicated in replication control by measuring RPA accumulation upon replication stress. We identify six factors required for normal rates of DNA replication and characterize a function of the bromodomain and PHD finger‐containing protein 3 (BRPF3) in replication initiation. BRPF3 forms a complex with HBO1 that specifically acetylates histone H3K14, and genomewide analysis shows high enrichment of BRPF3, HBO1 and H3K14ac at ORC1‐binding sites and replication origins found in the vicinity of TSSs. Consistent with this, BRPF3 is necessary for H3K14ac at selected origins and efficient origin activation. CDC45 recruitment, but not MCM2‐7 loading, is impaired in BRPF3‐depleted cells, identifying a BRPF3‐dependent function of HBO1 in origin activation that is complementary to its role in licencing. We thus propose that BRPF3‐HBO1 acetylation of histone H3K14 around TSS facilitates efficient activation of nearby replication origins.     

Structural and histone binding ability characterizations of human PWWP domains

Background

The PWWP domain was first identified as a structural motif of 100–130 amino acids in the WHSC1 protein and predicted to be a protein-protein interaction domain. It belongs to the Tudor domain ‘Royal Family’, which consists of Tudor, chromodomain, MBT and PWWP domains. While Tudor, chromodomain and MBT domains have long been known to bind methylated histones, PWWP was shown to exhibit histone binding ability only until recently.

Methodology/Principal Findings

The PWWP domain has been shown to be a DNA binding domain, but sequence analysis and previous structural studies show that the PWWP domain exhibits significant similarity to other ‘Royal Family’ members, implying that the PWWP domain has the potential to bind histones. In order to further explore the function of the PWWP domain, we used the protein family approach to determine the crystal structures of the PWWP domains from seven different human proteins. Our fluorescence polarization binding studies show that PWWP domains have weak histone binding ability, which is also confirmed by our NMR titration experiments. Furthermore, we determined the crystal structures of the BRPF1 PWWP domain in complex with H3K36me3, and HDGF2 PWWP domain in complex with H3K79me3 and H4K20me3.

Conclusions

PWWP proteins constitute a new family of methyl lysine histone binders. The PWWP domain consists of three motifs: a canonical β-barrel core, an insertion motif between the second and third β-strands and a C-terminal α-helix bundle. Both the canonical β-barrel core and the insertion motif are directly involved in histone binding. The PWWP domain has been previously shown to be a DNA binding domain. Therefore, the PWWP domain exhibits dual functions: binding both DNA and methyllysine histones.

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