植物同源结构域(PHD结构域)——组蛋白密码的解读器

植物同源结构域(plant homeodomain,PHD结构域),是真核生物中一种进化保守的锌指结构域.多种调控基因转录、细胞周期、凋亡的蛋白质含有PHD结构域.研究表明,PHD结构域涉及多种功能,包括蛋白质相互作用,特别是同核小体组蛋白的作用.目前认为,各种组蛋白修饰(包括甲基化、乙酰化、磷酸化、泛素化等)的模式和组合,调节染色质状态和基因转录活性,并提出了组蛋白密码理论.PHD指结构域能特异性识别组蛋白的甲基化(修饰)密码,可能是组蛋白密码的一种重要解读器.     

Homodimeric PHD Domain-containing Rco1 Subunit Constitutes a Critical Interaction Hub within the Rpd3S Histone Deacetylase Complex

Recognition of histone post-translational modifications is pivotal for directing chromatin-modifying enzymes to specific genomic regions and regulating their activities. Emerging evidence suggests that other structural features of nucleosomes also contribute to precise targeting of downstream chromatin complexes, such as linker DNA, the histone globular domain, and nucleosome spacing. However, how chromatin complexes coordinate individual interactions to achieve high affinity and specificity remains unclear. The Rpd3S histone deacetylase utilizes the chromodomain-containing Eaf3 subunit and the PHD domain-containing Rco1 subunit to recognize nucleosomes that are methylated at lysine 36 of histone H3 (H3K36me). We showed previously that the binding of Eaf3 to H3K36me can be allosterically activated by Rco1. To investigate how this chromatin recognition module is regulated in the context of the Rpd3S complex, we first determined the subunit interaction network of Rpd3S. Interestingly, we found that Rpd3S contains two copies of the essential subunit Rco1, and both copies of Rco1 are required for full functionality of Rpd3S. Our functional dissection of Rco1 revealed that besides its known chromatin-recognition interfaces, other regions of Rco1 are also critical for Rpd3S to recognize its nucleosomal substrates and functionin vivo. This unexpected result uncovered an important and understudied aspect of chromatin recognition. It suggests that precisely reading modified chromatin may not only need the combined actions of reader domains but also require an internal signaling circuit that coordinates the individual actions in a productive way.     

Insights into epigenetic patterns in mammalian early embryos

Mammalian fertilization begins with the fusion of two specialized gametes,followed by major epigenetic remodeling leading to the formation of a totipotent embryo.During the development of the pre-implantation embryo,precise reprogramming progress is a prerequisite for avoiding developmental defects or embryonic lethality,but the underlying molecular mechanisms remain elusive.For the past few years,unprecedented breakthroughs have been made in mapping the regulatory network of dynamic epigenomes during mammalian early embryo development,taking advantage of multiple advances and innovations in low-input genome-wide chromatin analysis technologies.The aim of this review is to highlight the most recent progress in understanding the mechanisms of epigenetic remodeling during early embryogenesis in mammals,including DNA methylation,histone modifications,chromatin accessibility and 3D chromatin organization.     

Unique Role of the WD-40 Repeat Protein 5 (WDR5) Subunit within the Mixed Lineage Leukemia 3 (MLL3) Histone Methyltransferase Complex

The MLL3 (mixed lineage leukemia 3) protein is a member of the human SET1 family of histone H3 lysine 4 methyltransferases and contains the conserved WDR5 interaction (Win) motif and the catalytic suppressor of variegation, enhancer of zeste, trithorax (SET) domain. The human SET1 family includes MLL1–4 and SETd1A/B, which all interact with a conserved subcomplex containing WDR5, RbBP5, Ash2L, and DPY-30 (WRAD) to form the minimal core complex required for full methyltransferase activity. However, recent evidence suggests that the WDR5 subunit may not be utilized in an identical manner within all SET1 family core complexes. Although the roles of WDR5 within the MLL1 core complex have been extensively studied, not much is known about the roles of WDR5 in other SET1 family core complexes. In this investigation, we set out to characterize the roles of the WDR5 subunit in the MLL3 core complex. We found that unlike MLL1, the MLL3 SET domain assembles with the RbBP5/Ash2L heterodimer independently of the Win motif-WDR5 interaction. Furthermore, we observed that WDR5 inhibits the monomethylation activity of the MLL3 core complex, which is dependent on the Win motif. We also found evidence suggesting that the WRAD subcomplex catalyzes weak H3K4 monomethylation within the context of the MLL3 core complex. Furthermore, solution structures of the MLL3 core complex assembled with and without WDR5 by small angle x-ray scattering show similar overall topologies. Together, this work demonstrates a unique role for WDR5 in modulating the enzymatic activity of the MLL3 core complex.     

Molecular characterization of the tobacco SET domain protein NtSET1 unravels its role in histone methylation, chromatin binding, and segregation

Plants contain a great number of genes encoding a distinctive class of SET domain proteins which harbor a plant-specific N-terminal part together with a C-terminal part showing highest sequence similarity to the catalytic domain of the yeast CLR4, the human SUV39H1 and G9a histone-methyltransferases (HMTases). Here we show that NtSET1, a representative member of this class from tobacco, methylated both K9 and K27 of histone H3 in vitro. Ectopic expression of NtSET1, by an inducible promoter, increased the amount of dimethylated H3K9 and induced chromosome-segregation defects in tobacco BY2 cells. Deletion analyses show that the HMTase activity, the association with specific chromatin regions and with condensed chromosomes, and the cellular effects largely depended on the C-terminal region including the SET domain of the protein. Nevertheless, the N-terminal part of NtSET1 was capable of targeting the green fluorescent protein to interphase chromatin. Finally, we show that NtSET1 bound LHP1, the Arabidopsis homolog of animal heterochromatin protein 1 (HP1), and that LHP1 co-localized with heterochromatin containing high amounts of dimethylated H3K9, suggesting a role for NtSET1 in heterochromatic function. Taken together, our results provide new insights into the molecular and global chromatin-binding activities of this particular class member of plant SET domain proteins.     

The fellowships of the INGs

The inhibitor of growth (ING) family of proteins is an evolutionarily conserved family, with members present from yeast to humans. The mammalian ING proteins are candidate tumor suppressor proteins and accordingly can cooperate with p53 to arrest proliferation and induce apoptosis. ING proteins are also reported to function in the promotion of cellular senescence, the regulation of DNA damage responses and the inhibition of angiogenesis. At the molecular level, ING proteins are thought to function as chromatin regulatory molecules, acting as co-factors for distinct histone and factor acetyl-transferase (H/FAT) and deacetylase (HDAC) enzyme complexes. Further, ING proteins interact with a number of additional proteins involved in the regulation of critical nuclear processes, such as gene expression and DNA replication, and also function as nuclear phosphoinositide (PtdInsP) receptors. Despite the increasing number of known molecular interacting partners for ING proteins, the specific biochemical action of mammalian ING proteins and its relationship to tumor suppression remain elusive. In this Prospect, we summarize the present understanding of the binding partners and physiologic roles of ING proteins and propose a general molecular paradigm for how ING proteins might function to prevent cancer.     

植物开花的组蛋白甲基化调控分子机理

开花是指植物从营养生长转变到生殖生长的生理过程,是植物个体发育和后代繁衍的中心环节,既受遗传基础决定,同时又受到温度和光周期等多种环境因素的调控。在拟南芥中,已经分离了大量的与开花相关的基因,从遗传学上已初步形成了一个开花调控的网络。组蛋白甲基化是植物发育过程的重要调节方式,近年来关于其参与开花调控的研究有了重要进展。本文综述了具有代表性的组蛋白H3赖氨酸甲基化修饰参与调控植物开花发育的机制,提出该研究领域的发展方向和前景。     

Structural Insights into the Induced-fit Inhibition of Fascin by a Small-Molecule Inhibitor

Tumor metastasis is responsible for ~ 90% of all cancer deaths. One of the key steps of tumor metastasis is tumor cell migration and invasion. Filopodia are cell surface extensions that are critical for tumor cell migration. Fascin protein is the main actin-bundling protein in filopodia. Small-molecule fascin inhibitors block tumor cell migration, invasion, and metastasis. Here we present the structural basis for the mechanism of action of these small-molecule fascin inhibitors. X-ray crystal structural analysis of a complex of fascin and a fascin inhibitor shows that binding of the fascin inhibitor to the hydrophobic cleft between the domains 1 and 2 of fascin induces a ~ 35^o rotation of domain 1, leading to the distortion of both the actin-binding sites 1 and 2 on fascin. Furthermore, the crystal structures of an inhibitor alone indicate that the conformations of the small-molecule inhibitors are dynamic. Mutations of the inhibitor-interacting residues decrease the sensitivity of fascin to the inhibitors. Our studies provide structural insights into the molecular mechanism of fascin protein function as well as the action of small-molecule fascin inhibitors.     

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。     

Distinct localization of histone H3 methylation in the vegetative nucleus of lily pollen

We analysed the distribution of histone H3 modifications in the nucleus of the vegetative cell (the vegetative nucleus) during pollen development in lily (Lilium longiflorum). Among the modifications specifically and/or abundantly present in the vegetative nucleus, dimethylation of histone H3 at lysine 9 (H3K9me2) and lysine 27 (H3K27me2) were found in heterochromatin, whereas trimethylation of histone H3 at lysine 27 (H3K27me3) was localized in euchromatin in the vegetative nucleus. Such unique localization of the histone H3 methylation marks, particularly of H3K27me3, within a nucleus was not observed in lily nuclei other than the vegetative nucleus. The level of H3K27me3 increased in the euchromatic region of the vegetative nucleus during pollen maturation. The results suggest that H3K27me3 controls the gene expression of the vegetative cell during pollen maturation.     

Molecular basis for chromatin assembly and modification by multiprotein complexes

Abstract: Epigenetic regulation of the chromatin landscape is often orchestrated through modulation of nucleosomes. Nucleosomes are composed of two copies each of the four core histones, H2A, H2B, H3, and H4, wrapped in ~150 bp of DNA. We focus this review on recent structural studies that further elucidate the mechanisms used by macromolecular complexes to mediate histone modification and nucleosome assembly. Nucleosome assembly, spacing, and variant histone incorporation are coordinated by chromatin remodeler and histone chaperone complexes. Several recent structural studies highlight how disparate families of histone chaperones and chromatin remodelers share similar features that underlie how they interact with their respective histone or nucleosome substrates. Post‐translational modification of histone residues is mediated by enzymatic subunits within large complexes. Until recently, relatively little was known about how association with auxiliary subunits serves to modulate the activity and specificity of the enzymatic subunit. Analysis of several recent structures highlights the different modes that auxiliary subunits use to influence enzymatic activity or direct specificity toward individual histone residues.     

Role of DNA methylation and histone modifications in structural maintenance of heterochromatin domains (chromocenters)

Effects of DNA methylation inhibitor; 5-azacytidine (5-aza-C); and histone acetylation inhibitor, trichostatine A (TSA), on the structure of pericentric heterochromatin of L929 mouse cells have been studied. 5-aza-C treatment for 48 h resulted in the transformation of ovoid chromocenters into elongated structures in 85% of cells. Hypotonic treatment of these cells reveals tandemly arranged DAPI-positive globules that are well distinguishable by light microscopy. Similar globular units can be observed in hypotonic-treated control cells. TSA treatment for 48 h causes dramatic decrease in HP1α content in cells. In 25% of treated cells chromocenters became highly decondensed and can not be reliably detected by light and electron microscopy. 85% cells demonstrate globular chromocenters with low HP1α content. Hypotonic treatment induces transformation of compact chromocenters into ring-like structures that can be either single or clustered. Rings are formed by uniform fiber in which no globular subunits are detected. The data obtained are discussed concerning several mechanisms of heterochromatin structure maintenance and the role of epigenetic factors.