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。     

植物细胞分化过程中DNA甲基化及组蛋白修饰调控研究

在植物发育过程中,除了遗传调控激活或抑制基因表达来促进植物发育过程中细胞分化外,表观遗传学是另外一个重要的、复杂的调控层面,在该过程中通过DNA特异位点的甲基化,组蛋白的翻译后修饰改变染色质的状态,进而时空性调控植物发育调控因子的表达。分化细胞提供了一个研究组蛋白密码如何影响细胞命运功能强大的系统。本研究重点综述了表观遗传调控中DNA甲基化、组蛋白甲基化及组蛋白乙酰化在植物细胞分化中的调控作用。     

植物胚乳发育的表观遗传学调控

被子植物的种子发育从双受精开始, 产生二倍体的胚和三倍体的胚乳。在种子发育和萌发过程中, 胚乳向胚组织提供营养物质, 因此胚乳对胚和种子的正常生长发育至关重要。开花植物发生基因组印迹的主要器官是胚乳。印迹基因的表达受表观遗传学机制的调控, 包括DNA甲基化和组蛋白H3K27甲基化修饰以及依赖于PolIV的siRNAs (p4-siRNAs)调控。基因组印迹的表观遗传学调控对胚乳的正常发育和种子育性具有不可或缺的重要作用。最新研究显示, 胚乳的整个基因组DNA甲基化水平降低, 而且去甲基化作用可能源于雌配子体的中央细胞。该文综述了种子发育的表观遗传学调控机制, 包括基因组印迹机制以及胚乳基因组DNA甲基化变化研究的最新进展。     

组蛋白甲基化修饰酶与早期胚胎发育

早期胚胎发育是胚胎发育中细胞分裂与分化最为活跃的时期,也是合子型基因大规模转录的时期,而此时组蛋白的甲基化修饰也显示出动态学的变化。这一时期,在细胞内外信号的共同调控下,经历着一系列基因的激活与抑制,许多调控机制参与其中的调控。而近年来的研究表示,表观遗传学调控显示越来越重要的作用。组蛋白甲基化修饰是表观遗传学重要调控机制之一,在胚胎的早期发育过程中扮演着重要的角色。就近年来组蛋白甲基化修饰酶在早期胚胎发育过程中的作用与功能做一简要综述。     

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。     

植物SET蛋白

SET蛋白是一类包含保守的SET结构域、与组蛋白甲基化密切相关的蛋白质。组蛋白修饰作为调控基因表达的重要因素,在植物体基因转录调控中发挥关键的作用。有关SET蛋白的研究为深入了解组蛋白修饰的机制提供了重要信息。植物SET蛋白具有保守的结构特征及进化机制,参与众多细胞核内的反应过程,如染色体的浓缩和分离,基因的转录,以及DNA的复制和修复等,调控植物基因的表达,影响植物体的发育。     

MADS-box基因控制植物成花的分子机理

植物花器官的发育和开花是植物生殖发育中最重要的过程,植物在长期的进化过程中产生了春化(低温)途径、自主途径、光周期途径以及不依赖于光温环境条件的赤霉素信号途径来适应多变的环境和调控植物开花过程。本文综述了模式植物拟南芥中由LEAFY(LFY)、CONSTANS(CO)、FLOWERING LOCUSC(FLC)、FLOW ERING LOCUS T(FT)和SUPPRESSOR OF OVEREXPRESSION OF CO1(SOC1)等基因构成的双子叶植物响应光温条件变化的开花调控网络;以及大麦、小麦中由VERNALIZATION1(VRN1)、VRN2、ODD-SOC2(OS2)和拟南芥CO、FT同源基因构成的禾本科植物开花调控网络。其中最重要的是转录调控因子MADS-box基因FLC、SOC1、VRN1和OS2,并发现组蛋白的乙酰化/脱乙酰化,赖氨酸的甲基化/脱甲基化在调控FLC、VRN1染色质活性状态及基因表达,从而产生开花控制的机理。这些研究发现将有助于对具有重要经济价值的单双子叶植物,通过生物技术手段改良其品种特性以应对非生物逆境,特别是低温胁迫的指导。     

表观遗传调控植物叶片衰老的研究进展

植物叶片衰老是一个非常重要的发育过程,涉及大分子的有序分解从而将营养物质从叶片转移到其他器官,对植物的生存和适应至关重要。叶片衰老主要受植物的发育调控,但同时也受内部和外部环境因素的影响,涉及高度复杂的基因调控网络和多层级的调控。近年来的研究表明表观遗传是调控植物叶片衰老的一种重要调控方式。该研究综述了植物叶片衰老过程中的表观遗传调控机制,包括组蛋白修饰、DNA甲基化、ATP依赖的染色质重塑和非编码RNA介导的调控,并对该领域今后的发展方向进行了展望。     

组蛋白甲基化修饰效应分子的研究进展

作为一种重要的表观遗传学调控机制,组蛋白甲基化修饰在多种生命过程中发挥了重要的作用。细胞内有多种组蛋白甲基化酶和去甲基化酶共同调节组蛋白的修饰状态,在组蛋白甲基化状态确定后,多种效应分子特异的读取修饰信息,从而参与基因转录调控过程。文章从组蛋白甲基化效应分子的作用机制方面综述了这一领域的研究进展。     

组蛋白去甲基化酶在发育和再生医学的研究

表观遗传学调控在器官发育以及再生医学中是重要的研究内容,而组蛋白的甲基化修饰属于表观遗传学调控机制之一并且成为近年来研究的热点内容。处于不同甲基化状态下的组蛋白,能影响多种分子对其的识别和结合,在转录起始、转录效率和转录后加工等多个层面调控相关基因的表达。而哺乳动物的器官发育与细胞重编程都与基因选择性表达密切相关,因此组蛋白甲基化状态在基因选择性表达中扮演着重要角色。本文概述了组蛋白去甲基化酶的分类以及组蛋白不同甲基化状态下对于基因的表达的调控,同时总结了组蛋白去甲基化酶在维持胚胎干细胞的多分化潜能和IPS细胞重编程效率方面的作用以及组蛋白去甲基化酶基因的缺失与相关器官发育的影响。最后探讨了组蛋白甲基化修饰酶在推动发育生物学与再生医学研究进展方面的潜能。     

NATURAL VARIATION IN EPIGENETIC GENE REGULATION AND ITS EFFECTS ON PLANT DEVELOPMENTAL TRAITS

In plants, epigenetic variation contributes to phenotypic differences in developmental traits. At the mechanistic level, this variation is conferred by DNA methylation and histone modifications. We describe several examples in which changes in gene expression caused by variation in DNA methylation lead to alterations in plant development. In these examples, the presence of repeated sequences or transposons within the promoters of the affected genes are associated with DNA methylation and gene inactivation. Small interfering RNAs expressed from these sequences recruit DNA methylation to the gene. Some of these methylated alleles are unstable giving rise to revertant sectors during mitosis and to progeny in which the methylated state is lost. However, others are stable for many generations and persist through speciation. These examples indicate that although DNA methylation influences gene expression, this is frequently dependent on classical changes to DNA sequence such as transposon insertions. By contrast, forms of histone methylation cause repression of gene expression that is stably inherited through mitosis but that can also be erased over time or during meiosis. A striking example involves the induction of flowering by exposure to low winter temperatures in Arabidopsis thaliana and its relatives. Histone methylation participates in repression of expression of an inhibitor of flowering during cold. In annual, semelparous species such as A. thaliana, this histone methylation is stably inherited through mitosis after return from cold to warm temperatures allowing the plant to flower continuously during spring and summer until it senesces. However, in perennial, iteroparous relatives the histone modification rapidly disappears when temperatures rise, allowing expression of the floral inhibitor to increase and limiting flowering to a short interval. In this case, epigenetic histone modifications control a key adaptive trait, and their pattern changes rapidly during evolution associated with life‐history strategy. We discuss these examples of epigenetic developmental traits with emphasis on the underlying mechanisms, their stability, and adaptive value.     

DNA methylation dynamics during germline development

DNA methylation plays essential homeostatic functions in eukaryotic genomes. In animals, DNA methylation is also developmentally regulated and, in turn, regulates development. In the past two decades, huge research effort has endorsed the understanding that DNA methylation plays a similar role in plant development, especially during sexual reproduction. The power of whole-genome sequencing and cell isolation techniques, as well as bioinformatics tools, have enabled recent studies to reveal dynamic changes in DNA methylation during germline development. Furthermore, the combination of these technological advances with genetics, developmental biology and cell biology tools has revealed functional methylation reprogramming events that control gene and transposon activities in flowering plant germlines. In this review, we discuss the major advances in our knowledge of DNA methylation dynamics during male and female germline development in flowering plants.     

DNA methylation, a key regulator of plant development and other processes

Recent research has demonstrated that DNA methylation plays an integral role in regulating the timing of flowering and in endosperm development. The identification of key genes controlling these processes, the expression of which is altered in plants with low methylation, opens the way to understanding how DNA methylation regulates plant development.     

The function of histone lysine methylation related SET domain group proteins in plants

Histone methylation, which is mediated by the histone lysine (K) methyltransferases (HKMTases), is a mechanism associated with many pathways in eukaryotes. Most HKMTases have a conserved SET (Su(var) 3‐9,E(z),Trithorax) domain, while the HKMTases with SET domains are called the SET domain group (SDG) proteins. In plants, only SDG proteins can work as HKMTases. In this review, we introduced the classification of SDG family proteins in plants and the structural characteristics of each subfamily, surmise the functions of SDG family members in plant growth and development processes, including pollen and female gametophyte development, flowering, plant morphology and the responses to stresses. This review will help researchers better understand the SDG proteins and histone methylation in plants and lay a basic foundation for further studies on SDG proteins.     

Plant chromatin: development and gene control

It is increasingly clear that chromatin is not just a device for packing DNA within the nucleus but also a dynamic material that changes as cellular environments alter. The precise control of chromatin modification in response to developmental and environmental cues determines the correct spatial and temporal expression of genes. Here, we review exciting discoveries that reveal chromatin participation in many facets of plant development. These include: chromatin modification from embryonic and meristematic development to flowering and seed formation, the involvement of DNA methylation and chromatin in controlling invasive DNA and in maintenance of epigenetic states, and the function of chromatin modifying and remodeling complexes such as SWI/SNF and histone acetylases and deacetylases in gene control. Given the role chromatin structure plays in every facet of plant development, chromatin research will undoubtedly be integral in both basic and applied plant biology.     

Epigenetic gene regulation by plant Jumonji group of histone demethylase

Histone methylation plays an important role in epigenetic regulation of gene expression. Reversible methylation/demethylation of several histone lysine residues is mediated by distinct histone methyltransferases and histone demethylases. Jumonji proteins have been characterized to be involved in histone demethylation. Plant Jumonji homologues are found to have important functions in epigenetic processes, gene expression and plant development and to play an essential role in interplay between histone modifications and DNA methylation. This article is part of a Special Issue entitled: Epigenetic Control of cellular and developmental processes in plants.