植物组蛋白赖氨酸化修饰参与基因表达调控的机理

组蛋白共价修饰作为表观遗传修饰的重要部分,主要包括乙酰化和甲酰化、甲基化、磷酸化、泛素化和SUMO化等,它们形成一个复杂的网络共同调控基因的表达,其中组蛋白甲基化修饰成为研究的热点,甲基化主要发生在赖氨酸残基上。近年来,随着有关植物组蛋白赖氨酸甲基化修饰研究的不断深入,发现其通过改变自身赖氨酸残基的甲基化状态和甲基化程度,形成转录激活或者转录抑制标记,调控基因的表达,在植物开花和逆境胁迫的响应过程中起着至关重要的作用。H3组蛋白的赖氨酸甲基化修饰能够调控FLC基因和有关抗性基因的表达,具体表现为:H3K4的三甲基化促进FLC的表达,H3K27的三甲基化则抑制FLC的表达;H3K4me3作为转录激活标记,可激活PtdIns5P基因的表达,启动响应干旱的脂质合成信号通路,响应干旱胁迫;相反,H3K27me3作为一种转录抑制标记,低水平的H3K27me3诱导COR15A和ATGOLS3基因表达,它们分别编码叶绿体低温保护蛋白Cor15am和肌醇半乳糖合成酶GOLS,以抵抗寒冷胁迫。文章主要综述了植物组蛋白赖氨酸甲基化修饰参与DNA甲基化、开花过程以及应答逆境胁迫的分子机制。     

8-氯腺苷诱导的组蛋白H3K79双甲基化促进NBS1和p21的基因转录激活

组蛋白H3第79位赖氨酸甲基化（H3K79me）修饰有单甲基、双甲基及三甲基3种形式,是常染色质的标志.然而,对于组蛋白H3K79三种甲基化各自在基因转录、DNA损伤修复中所起的作用尚不十分清楚.本研究以8-氯腺苷（8-Cl-Ado）为DNA双链断裂（DNA double-stranded breaks,DSB）诱导剂,采用Western 印迹,在人肺癌细胞H1299检测出了DNA修复分子NBS1、细胞周期检验点相关分子p21,并发现H3K79me1、H3K79me2和H3K79me3三种甲基化修饰的组蛋白明显增加;染色质免疫共沉淀结合实时定量PCR实验显示,只H3K79me2与DNA损伤检验点分子p21、DNA修复分子NBS1的启动子区域相结合,说明H3K79双甲基化修饰与这些基因的转录激活有关.结果提示,在8-氯腺苷引起 DSB时,是H3K79me2、而不是H3K79me1和H3K79me3参与NBS1和p21基因转录激活时的染色质重塑.8-氯腺苷诱导H3K79双甲基化增强、促进H3K79me2所在染色质区域的NBS1和p21基因转录激活可能是8-Cl-Ado抑制肿瘤细胞生长作用机制之一.     

组蛋白共价修饰——组蛋白H3第4赖氨酸甲基化

染色体组蛋白的共价修饰在调节染色体结构,控制基因的转录等方面发挥重要的作用。组蛋白H3第4赖氨酸的甲基化作为共价修饰的方式之一,可以调控基因的转录激活。随着对组蛋白甲基化转移酶及相关作用蛋白研究的深入,人们对组蛋白H3第4赖氨酸的甲基化的功能也有了更深的了解。目前研究发现它与癌症也有很密切的关系。     

DNA甲基化——肿瘤产生的一种表观遗传学机制

在人类基因组中,DNA甲基化是一种表观遗传修饰,它与肿瘤的发生关系密切。抑癌基因和DNA修复基因的高甲基化、重复序列DNA的低甲基化、某些印记基因的印记丢失与多种肿瘤的发生有关。目前研究发现,基因组中甲基化的水平不仅受DNA 甲基化转移酶（DNMT）的影响,还与组蛋白甲基化、叶酸摄入、RNA干扰等多种因素有关。DNA甲基化在基因转录过程中扮有重要角色,并与组蛋白修饰、染色质构型重塑共同参与转录调控。     

组蛋白翻译后修饰在卵巢功能调控中的作用

卵巢是雌性哺乳动物的生殖器官,担负着产生成熟卵子和分泌性激素的功能。卵巢的功能调控涉及细胞生长和分化相关基因的有序激活和抑制。近年研究发现组蛋白翻译后修饰因可影响DNA复制、损伤修复及基因转录活性,且一些调节组蛋白修饰的酶为转录因子相关的共激活因子或共抑制因子,在卵巢功能调控和相关疾病发生和发展中起重要作用。本文以卵泡发育和性激素分泌与作用的机制为主线,概括常见组蛋白修饰(主要是乙酰化和甲基化)在生殖周期中的动态变化规律及其对重要分子事件的基因表达调控,如组蛋白乙酰化的特殊动态变化对卵母细胞减数分裂的阻滞与恢复意义重大,而组蛋白(尤其是H3K4)甲基化通过调控卵母细胞的染色质转录活性与减数分裂进程影响其成熟,排卵前组蛋白乙酰化或甲基化亦可促进类固醇激素的合成与分泌等。最后简述了异常组蛋白翻译后修饰在两种常见卵泡发育障碍性疾病(早发性卵巢功能不全、多囊卵巢综合征)发生和发展中的作用。本综述将为理解卵巢功能的复杂调控机制和探索相关疾病的潜在治疗靶点提供有益参考。     

组蛋白H3K36甲基化修饰在DNA损伤修复中的作用

维持基因组的稳定性是保证生命活动正常进行的必要条件。内部或外界的刺激会造成DNA的损伤,引起基因组的不稳定,导致细胞死亡甚至肿瘤发生。DNA为基础的核小体上的组蛋白可以发生多种翻译后修饰,其中组蛋白H3第36位上的赖氨酸(H3K36)的甲基化修饰在抑制非正常转录起始、抑制组蛋白交换、调控RNA可变剪切中发挥重要作用。近几年来,多项研究结果也表明,H3K36修饰在双链断裂和错配修复等DNA损伤修复活动中也发挥了调控作用。因此,了解H3K36甲基化在DNA损伤修复中的作用,可为相关疾病的研究与治疗提供理论基础。     

本期重点推介

正CRISPR/Cas9是一种RNA引导的基因组靶向编辑技术,可用于基因敲除、基因修复和基因敲入等操作。组蛋白甲基化修饰属于表观调控,参与调控基因的转录表达,在多种信号通路调节中具有重要作用。为了进一步揭示组蛋白甲基化修饰对蜕皮激素20-羟基蜕皮酮(20E)信号传导的调控机理,华南师范大学生命科学学院张文豪和李康等将组蛋白甲基转移酶的sg RNA序列插入到牛津大学实验室构建的敲除载体p Ac-sg RNA-Cas9骨架中,以修饰H3K4甲基化的Trr正调控20E对Br-C的转录诱导为阳性对照,利用q RTPCR和Western blot检测在黑腹果蝇Drosophila melanogaster细胞中利用该系统敲除靶基因的有效性,并检测敲除不同的组蛋白甲基转移酶基因对20E诱导20E应答元件(Ec RE)活性的影响(pp. 549-557)。     

组蛋白H3K36甲基化与疾病

组蛋白H3K36位点可以发生甲基化修饰,其修饰状态受到H3K36甲基转移酶和去甲基化酶的动态调控。H3K36的甲基化修饰可引起多种生物学效应,如参与基因的转录激活或抑制、剂量补偿以及基因的选择性剪接等。H3K36甲基化修饰状态的异常与很多疾病相关,因此全面了解H3K36甲基化对于该类疾病的诊断和治疗具有重要意义。     

组蛋白赖氨酸甲基转移酶2D调控H9c2细胞中HIF-1α/VEGF通路（英文）

组蛋白赖氨酸甲基转移酶2D (histone-lysine N-methyltransferase 2D, KMT2D)作为主要的组蛋白3第4位赖氨酸(H3K4)甲基转移酶,在调控胚胎发育、组织分化、代谢和肿瘤抑制方面发挥重要作用。在小鼠体内,敲除Kmt2d会导致严重的心脏发育缺陷最终造成胚胎期死亡。低氧诱导因子-1α(hypoxia-inducible factor 1α, HIF-1α)作为调节细胞应对低氧的关键转录因子,能够调控多种下游基因转录。有相关研究揭示,表观遗传调控者能够调节HIF-1α的稳定性和活性。同样,作为表观遗传调控者的组蛋白甲基转移酶KMT2D是否参与低氧条件下HIF-1α对下游基因的调控,目前仍未知。在本研究中,观察在Kmt2d正常或缺乏的情况下,心肌细胞H9c2对低氧环境的应答反应。结果显示,与常氧条件相比,低氧状态下HIF-1α、组蛋白乙酰化酶P300、KMT2D及其介导的H3K4一甲基化(H3K4 mono-methylation, H3K4me1)的蛋白质水平增加(P0.05);HIF-1α下游基因血管内皮生长因子(vascular endothelial growth factor, Vegf)的mRNA表达水平明显上调(P0.01)。染色质免疫共沉淀实验(chromatin immunoprecipitation assay, ChIP-qPCR)检测结果显示,H3K4me1和组蛋白3第27位赖氨酸乙酰化(histone 3 lysine 27 acetylation, H3K27ac)在Vegf基因启动子区域的结合丰度明显增加(P0.05)。低氧条件下沉默Kmt2d之后,H3K4me1蛋白水平和Vegf的mRNA表达下降(P0.05)。本研究表明,低氧条件下KMT2D参与调控HIF-1α和下游基因Vegf的表达。     

PR-SET7 and SUV4-20H regulate H4 lysine-20 methylation at imprinting control regions in the mouse

Imprinted genes are important in development and their allelic expression is mediated by imprinting control regions (ICRs). On their DNA-methylated allele, ICRs are marked by trimethylation at H3 Lys 9 (H3K9me3) and H4 Lys 20 (H4K20me3), similar to pericentric heterochromatin. Here, we investigate which histone methyltransferases control this methylation of histone at ICRs. We found that inactivation of SUV4-20H leads to the loss of H4K20me3 and increased levels of its substrate, H4K20me1. H4K20me1 is controlled by PR-SET7 and is detected on both parental alleles. The disruption of SUV4-20H or PR-SET7 does not affect methylation of DNA at ICRs but influences precipitation of H3K9me3, which is suggestive of a trans-histone change. Unlike at pericentric heterochromatin, however, H3K9me3 at ICRs does not depend on SUV39H. Our data show not only new similarities but also differences between ICRs and heterochromatin, both of which show constitutive maintenance of methylation of DNA in somatic cells.     

Degrees make all the difference: The multifunctionality of histone H4 lysine 20 methylation

Residue and degree-specific methylation of histone lysines along with other epigenetic modifications organizes chromatin into distinct domains and regulates almost every aspect of DNA metabolism. Identification of histone methyltransferases and demethylases, as well as proteins that recognize methylated lysines, has clarified the role of each methylation event in regulating different biological pathways. Methylation of histone H4 lysine 20 (H4K20me) plays critical roles in diverse cellular processes such as gene expression, cell cycle progression and DNA damage repair, with each of the three degrees of methylation (mono- di- and tri-methylation) making a unique contribution. Here we discuss recent studies of H4K20me that have greatly improved our understanding of the regulation and function of this fascinating histone modification.     

Chromatin loading of MCM hexamers is associated with di-/tri-methylation of histone H4K20 toward S phase entry

DNA replication is a key step in initiating cell proliferation. Loading hexameric complexes of minichromosome maintenance (MCM) helicase onto DNA replication origins during the G1 phase is essential for initiating DNA replication. Here, we examined MCM hexamer states during the cell cycle in human hTERT-RPE1 cells using multicolor immunofluorescence-based, single-cell plot analysis, and biochemical size fractionation. Experiments involving cell-cycle arrest at the G1 phase and release from the arrest revealed that a double MCM hexamer was formed via a single hexamer during G1 progression. A single MCM hexamer was recruited to chromatin in the early G1 phase. Another single hexamer was recruited to form a double hexamer in the late G1 phase. We further examined relationship between the MCM hexamer states and the methylation levels at lysine 20 of histone H4 (H4K20) and found that the double MCM hexamer state was correlated with di/trimethyl-H4K20 (H4K20me2/3). Inhibiting the conversion from monomethyl-H4K20 (H4K20me1) to H4K20me2/3 retained the cells in the single MCM hexamer state. Non-proliferative cells, including confluent cells or Cdk4/6 inhibitor-treated cells, also remained halted in the single MCM hexamer state. We propose that the single MCM hexamer state is a halting step in the determination of cell cycle progression.     

MBTD1 is associated with Pr-Set7 to stabilize H4K20me1 in mouse oocyte meiotic maturation

H4K20me1 is a critical histone lysine methyl modification in eukaryotes. It is recognized and “read” by various histone lysine methyl modification binding proteins. In this study, the function of MBTD1, a member of the Polycomb protein family containing four MBT domains, was comprehensively studied in mouse oocyte meiotic maturation. The results showed that depletion of MBTD1 caused reduced expression of histone lysine methyl transferase Pr-Set7 and H4K20me1 as well as increased oocyte arrest at the GV stage. Increased γH2AX foci were formed, and DNA damage repair checkpoint protein 53BP1 was downregulated. Furthermore, depletion of MBTD1 activated the cell cycle checkpoint protein Chk1 and downregulated the expression of cyclin B1 and cdc2. MBTD1 knockdown also affected chromosome configuration in GV stage oocytes and chromosome alignment at the MII stage. All these phenotypes were reproduced when the H4K20 methyl transferase Pr-Set7 was depleted. Co-IP demonstrated that MBTD1 was correlated with Pr-Set7 in mouse oocytes. Our results demonstrate that MBTD1 is associated with Pr-Set7 to stabilize H4K20me1 in mouse oocyte meiotic maturation.     

Histone H4K20 tri‐methylation at late‐firing origins ensures timely heterochromatin replication

Among other targets, the protein lysine methyltransferase PR‐Set7 induces histone H4 lysine 20 monomethylation (H4K20me1), which is the substrate for further methylation by the Suv4‐20h methyltransferase. Although these enzymes have been implicated in control of replication origins, the specific contribution of H4K20 methylation to DNA replication remains unclear. Here, we show that H4K20 mutation in mammalian cells, unlike in Drosophila, partially impairs S‐phase progression and protects from DNA re‐replication induced by stabilization of PR‐Set7. Using Epstein–Barr virus‐derived episomes, we further demonstrate that conversion of H4K20me1 to higher H4K20me2/3 states by Suv4‐20h is not sufficient to define an efficient origin per se, but rather serves as an enhancer for MCM2‐7 helicase loading and replication activation at defined origins. Consistent with this, we find that Suv4‐20h‐mediated H4K20 tri‐methylation (H4K20me3) is required to sustain the licensing and activity of a subset of ORCA/LRWD1‐associated origins, which ensure proper replication timing of late‐replicating heterochromatin domains. Altogether, these results reveal Suv4‐20h‐mediated H4K20 tri‐methylation as a critical determinant in the selection of active replication initiation sites in heterochromatin regions of mammalian genomes.     

A new regulator of the cell cycle

The ability of eukaryotes to alter chromatin structure and function is modulated, in part, by histone-modifying enzymes and the post-translational modifications they create. One of these enzymes, PR-Set7/Set8/KMT5a, is the sole histone methyltransferase responsible for the monomethylation of histone H4 lysine 20 (H4K20me1) in higher eukaryotes. Both PR-Set7 and H4K20me1 were previously found to be tightly cell cycle regulated suggesting that they play an important, although unknown, role in cell cycle progression. Several recent reports reveal that PR-Set7 abundance is dynamically regulated during different cell cycle phases by distinct enzymes including cdk1/cyclinB, Cdc14, SCF^Skp2, CRL4^cdt2 and APC^cdh1. Importantly, these reports demonstrate that inappropriate levels of PR-Set7 result in profound cell cycle defects including the inability to initiate S phase, the re-replication of DNA and the improper timing of mitotic progression. Here, we summarize the significance of these new findings, raise some important questions that require further investigation and explore several possibilities of how PR-Set7 and methylated H4K20 may likely function as novel regulators of the cell cycle.