PLMT家族成员SET7/9的非组蛋白甲基化作用

SET7/9是蛋白赖氨酸甲基化转移酶（protein lysine methyltransferases,PLMTs或PKMTs）家族成员,具有SET结构域。现已发现SET7/9是一种赖氨酸单甲基化转移酶,除了能使组蛋白H3第四位赖氨酸（lysine4 of histone 3,H3K4）单甲基化外,更重要的能使一些转录因子、肿瘤抑制因子、膜相关受体等非组蛋白单甲基化,其甲基化作用主要与蛋白稳定和转录活化有关。该效应受赖氨酸特异性去甲基酶1（lysine specifcdemethylase,LSD1）的抑制。SET7/9与LSD1两者效应的平衡对维持体内活性蛋白质含量、调节基因表达具有重要意义。     

Methylation of H3 K4 and K79 is not strictly dependent on H2B K123 ubiquitylation

Covalent modifications of histone proteins have profound consequences on chromatin structure and function. Specific modification patterns constitute a code read by effector proteins. Studies from yeast found that H3 trimethylation at K4 and K79 is dependent on ubiquitylation of H2B K123, which is termed a “trans-tail pathway.” In this study, we show that a strain unable to be ubiquitylated on H2B (K123R) is still proficient for H3 trimethylation at both K4 and K79, indicating that H3 methylation status is not solely dependent on H2B ubiquitylation. However, additional mutations in H2B result in loss of H3 methylation when combined with htb1-K123R. Consistent with this, we find that the original strain used to identify the trans-tail pathway has a genomic mutation that, when combined with H2B K123R, results in defective H3 methylation. Finally, we show that strains lacking the ubiquitin ligase Bre1 are defective for H3 methylation, suggesting that there is an additional Bre1 substrate that in combination with H2B K123 facilitates H3 methylation.     

Kinetics of Re-establishing H3K79 Methylation Marks in Global Human Chromatin

We employ a stable isotope strategy wherein both histones and their methylations are labeled in synchronized human cells. This allows us to differentiate between old and new methylations on pre-existing versus newly synthesized histones. The strategy is implemented on K79 methylation in an isoform-specific manner for histones H3.1, H3.2, and H3.3. Although levels of H3.3K79 monomethylation are higher than that of H3.2/H3.1, the rate of establishing the K79 methylation is the same for all three isoforms. Surprisingly, we find that pre-existing “old” histones continue to be K79-monomethylated and -dimethylated at a rate equal to the newly synthesized histones. These observations imply that some degree of positional “scrambling” of K79 methylation occurs through the cell cycle.     

质谱检测叶酸缺乏人胚肾细胞中低组蛋白H3赖氨酸79甲基化修饰

目的:探讨叶酸(Folic acid,FA)缺乏在培养的人胚肾细胞(HEK-293)中对细胞组蛋白修饰水平的影响。方法:人胚肾细胞分两组培养,一组正常培养,一组无叶酸培养。细胞提取组蛋白后通过高效液相色谱一线性离子阱/静电场轨道阱高分辨质谱(HPLC-LTQ/Orbitrap Ms)检测组蛋白的修饰以比较叶酸缺乏对人胚肾细胞组蛋白修饰的影响。结果:用高分辨质谱方法成功检测到人胚肾细胞的五个组蛋白变体H1,H3,H4,H2a和H2b上的33个组蛋白修饰位点,其中23个修饰位点为uniprot数据库上已经报道的组蛋白修饰位点,而其余10个为未报道修饰位点。通过质谱比较正常和叶酸缺乏组人胚肾细胞修饰谱发现H3K79me1和H3K79me2在叶酸缺乏培养组中检出率较低。进一步用蛋白免疫印迹的方法也证明了在叶酸缺乏的人胚肾细胞中H3K79me1水平低于正常培养组。结论:细胞中叶酸缺乏影响组蛋白甲基化包括H3K79me2和H3K79me1修饰水平,提示细胞外营养因素叶酸水平可影响组蛋白修饰水平从而参与疾病如神经管畸形(Neural tube defect,NTD)的发生。     

质谱检测叶酸缺乏人胚肾细胞中低组蛋白H3赖氨酸79甲基化修饰

目的：探讨叶酸（Folic acid,FA）缺乏在培养的人胚肾细胞（HEK-293）中对细胞组蛋白修饰水平的影响。方法：人胚肾细胞分两组培养,一组正常培养,一组无叶酸培养。细胞提取组蛋白后通过高效液相色谱一线性离子阱/静电场轨道阱高分辨质谱（HPLC-LTQ/Orbitrap Ms）检测组蛋白的修饰以比较叶酸缺乏对人胚肾细胞组蛋白修饰的影响。结果：用高分辨质谱方法成功检测到人胚肾细胞的五个组蛋白变体H1,H3,H4,H2a和H2b上的33个组蛋白修饰位点,其中23个修饰位点为uniprot数据库上已经报道的组蛋白修饰位点,而其余10个为未报道修饰位点。通过质谱比较正常和叶酸缺乏组人胚肾细胞修饰谱发现H3K79me1和H3K79me2在叶酸缺乏培养组中检出率较低。进一步用蛋白免疫印迹的方法也证明了在叶酸缺乏的人胚肾细胞中H3K79me1水平低于正常培养组。结论：细胞中叶酸缺乏影响组蛋白甲基化包括H3K79me2和H3K79me1修饰水平,提示细胞外营养因素叶酸水平可影响组蛋白修饰水平从而参与疾病如神经管畸形（Neural tube defect,NTD）的发生。     

The BAH domain of Rsc2 is a histone H3 binding domain

Bromo-adjacent homology (BAH) domains are commonly found in chromatin-associated proteins and fall into two classes; Remodels the Structure of Chromatin (RSC)-like or Sir3-like. Although Sir3-like BAH domains bind nucleosomes, the binding partners of RSC-like BAH domains are currently unknown. The Rsc2 subunit of the RSC chromatin remodeling complex contains an RSC-like BAH domain and, like the Sir3-like BAH domains, we find Rsc2 BAH also interacts with nucleosomes. However, unlike Sir3-like BAH domains, we find that Rsc2 BAH can bind to recombinant purified H3 in vitro, suggesting that the mechanism of nucleosome binding is not conserved. To gain insight into the Rsc2 BAH domain, we determined its crystal structure at 2.4 Å resolution. We find that it differs substantially from Sir3-like BAH domains and lacks the motifs in these domains known to be critical for making contacts with histones. We then go on to identify a novel motif in Rsc2 BAH that is critical for efficient H3 binding in vitro and show that mutation of this motif results in defective Rsc2 function in vivo. Moreover, we find this interaction is conserved across Rsc2-related proteins. These data uncover a binding target of the Rsc2 family of BAH domains and identify a novel motif that mediates this interaction.     

Structure of the Neurospora SET domain protein DIM-5, a histone H3 lysine methyltransferase

AdoMet-dependent methylation of histones is part of the "histone code" that can profoundly influence gene expression. We describe the crystal structure of Neurospora DIM-5, a histone H3 lysine 9 methyltranferase (HKMT), determined at 1.98 A resolution, as well as results of biochemical characterization and site-directed mutagenesis of key residues. This SET domain protein bears no structural similarity to previously characterized AdoMet-dependent methyltransferases but includes notable features such as a triangular Zn3Cys9 zinc cluster in the pre-SET domain and a AdoMet binding site in the SET domain essential for methyl transfer. The structure suggests a mechanism for the methylation reaction and provides the structural basis for functional characterization of the HKMT family and the SET domain.     

rSac3, a new member of Sac domain phosphoinositide phosphatases family

Inositol phospholipids are concentrated in the cytosolic surface of membranes. Phosphatidylinositol （PtdIns）, the precursor of phosphoinositides, is synthesized primarily in the endoplasmic reticulum. Reversible phosphorylation in the inositol ring of PtdIns at positions 3, 4 and 5 results in the generation of seven phosphoinositide species： PtdIns（3）P, PtdIns（4）P, PtdIns（5）P, PtdIns（3,4）P2, PtdIns（3,5）P2, PtdIns（4,5）P2, PtdIns（3,4,5）P3. Phos- phoinositides can be rapidly interconverted from one species to another by strategically localized kinases and phosphatases [1]. Phosphoinositides play a fundamental role in controlling membrane-cytosol interfaces [2]. They are essential regulators of many cellular functions, including classical signal transduction, membrane trafficking, cytoskeletal organization, nuclear events, cell survival versus apoptosis, motility and the permeability and transport of membranes [1, 3].[第一段]     

Dot1-Dependent Histone H3K79 Methylation Promotes the Formation of Meiotic Double-Strand Breaks in the Absence of Histone H3K4 Methylation in Budding Yeast

Epigenetic marks such as histone modifications play roles in various chromosome dynamics in mitosis and meiosis. Methylation of histones H3 at positions K4 and K79 is involved in the initiation of recombination and the recombination checkpoint, respectively, during meiosis in the budding yeast. Set1 promotes H3K4 methylation while Dot1 promotes H3K79 methylation. In this study, we carried out detailed analyses of meiosis in mutants of the SET1 and DOT1 genes as well as methylation-defective mutants of histone H3. We confirmed the role of Set1-dependent H3K4 methylation in the formation of double-strand breaks (DSBs) in meiosis for the initiation of meiotic recombination, and we showed the involvement of Dot1 (H3K79 methylation) in DSB formation in the absence of Set1-dependent H3K4 methylation. In addition, we showed that the histone H3K4 methylation-defective mutants are defective in SC elongation, although they seem to have moderate reduction of DSBs. This suggests that high levels of DSBs mediated by histone H3K4 methylation promote SC elongation.     

SH3GLB, a new endophilin-related protein family featuring an SH3 domain

A new cDNA encoding a protein of 362 amino acids designated SH3GLB1, for SH3 domain GRB2-like endophilin B1, was identified in a yeast two-hybrid screen devoted to the identification of new partners interacting with the apoptosis inducer Bax. SH3GLB1 shows strong similarities to the SH3 domain-containing proteins of the endophilin family and presumably represents the human homologue of the potential Caenorhabditis elegans SH3 containing-protein identified by systematic translation of the C. elegans genome (GenBank Accession No. U46675). Reversing prey to bait in the yeast screen, a second protein, SH3GLB2, of 395 amino acids showing 65% identity to SH3GLB1 was identified as an interacting partner of SH3GLB1. The discovery of SH3GLB1 itself in the screening with SH3GLB1 as a bait and further mapping experiments demonstrated that a core coiled-coil-type region is required for the formation of SH3GLB homo- and/or heterodimers, whereas the SH3 domain is not involved in these interactions. Interestingly, the similarities with the endophilin proteins cover the entire sequence of the SH3GLB family, suggesting a common fold and presumably a common mode of action. Furthermore, SH3GLB members colocalize to the cytoplasmic compartment of the cell together with Bax and are excluded from the nucleus. SH3GLB1 and SH3GLB2 do not significantly influence the onset and time course of Bax-mediated apoptosis in HeLa or 293T cells.     

The active site of the SET domain is constructed on a knot

The SET domain contains the catalytic center of lysine methyltransferases that target the N-terminal tails of histones and regulate chromatin function. Here we report the structure of the SET7/9 protein in the absence and presence of its cofactor product, S-adenosyl-L-homocysteine (AdoHcy). A knot within the SET domain helps form the methyltransferase active site, where AdoHcy binds and lysine methylation is likely to occur. A structure-guided comparison of sequences within the SET protein family suggests that the knot substructure and active site environment are conserved features of the SET domain.