非生物胁迫下植物表观遗传变异的研究进展

植物在整个生命过程中固着生长,不能主动躲避外界不良环境的危害,需要通过自身的防御机制来抵御和适应外界胁迫,而表观遗传修饰在调控植物应对不良环境胁迫中起重要作用。该文从DNA甲基化、组蛋白修饰、染色质重塑和非编码RNA等方面进行了综述,主要阐述了近年来国内外有关非生物胁迫下植物的表观遗传变化,以期为利用表观遗传变异提高植物的抗胁迫能力提供参考。     

高等植物中SWI/SNF染色质重塑研究的新进展

染色质重塑是真核生物表观遗传调控的重要方式．通过对染色质物理结构的调节,染色质重塑在高等动植物干细胞的自我更新及分化、器官和个体发育以及肿瘤发生等多种生物学过程中发挥重要作用．近年来,高等动植物染色质重塑方面的研究已经成为表观遗传学研究领域的热点．本综述总结近年来有关高等动植物染色质重塑的重要研究报道,介绍了染色质重塑的结构机制、分析比较了高等动植物染色质重塑复合体的组成及其生物学功能的多样性,并着重综述了高等植物SWI/SNF染色质重塑复合体各组分在调控植物发育与逆境生长等方面的功能,以期为今后植物中染色质重塑的研究提供启示．     

CHD7对发育和疾病的表观遗传调控研究进展

染色质重塑是指染色质通过其结构的动态变化影响基因组DNA的可接近性,进而影响DNA复制、转录、修复和重组的过程,属于表观遗传调控。染色质域解旋酶DNA结合蛋白7(CHD7)是一种ATP依赖的染色质重塑酶,能够调控发育过程中多种重要转录因子,广泛参与众多生理过程。本文对CHD7在发育和疾病当中的表观遗传调控作用进行简要概述。     

酿酒酵母INO80染色质重塑复合物调控基因表达的研究进展

表观遗传调控是真核生物基因表达精细调控的重要组成部分,主要包括DNA甲基化、组蛋白修饰和染色质重塑。其中,染色质重塑因子可影响组蛋白修饰酶和转录因子与特定位点的结合,在基因表达调控中占有重要地位。INO80复合物是进化上保守的染色质重塑复合物,能利用ATP水解获得的能量促进核小体的滑动和驱逐。INO80复合物除了在DNA复制、修复中发挥重要功能外,还通过改变DNA可及性调控酿酒酵母的基因表达。本文综述了染色质重塑复合物的分类及组成,重点介绍了酿酒酵母多亚基复合物INO80在基因表达调控中的重要功能,包括驱逐RNA聚合酶Ⅱ、响应信号转导途径和改变基因表达水平等,并着重总结了其在酿酒酵母环境胁迫响应机理中的研究进展。深入研究INO80染色质重塑复合物的功能,可为理解真核生物精细代谢调控的机制,并进一步开发基于染色质重塑等表观调控水平的微生物代谢工程和合成生物学改造策略,提高菌株的环境胁迫耐受性和发酵性能提供基础。     

表观遗传学与组织工程

表观遗传学是环境和遗传相互作用的一门学科,其调控方式包括DNA甲基化、组蛋白修饰、染色质重塑和非编码RNA调控等。这些调控方式的协调作用决定了细胞的发育、功能、状态和命运,因此表观遗传调控机制已经成为外界环境影响因素和基因转录调控之间的重要联系。组织工程的目标是研究和开发用于修复、维护、促进人体各种组织或器官损伤后的功能和形态的生物替代物,该领域的主要挑战之一在于寻找最佳的能够控制细胞命运和促进细胞成熟的微环境。该文综述了表观遗传的调控方式及相应研究方法、表观遗传对细胞分化和功能的影响、生物材料对表观遗传的调控,以期为组织工程研究及转化提供参考。     

表观遗传调控植物响应非生物胁迫的研究进展

植物的生长发育容易受到外界环境变化的影响。非生物胁迫发生时, 表观遗传机制对胁迫应答基因的表达调控发挥了十分重要的作用。近年来, 调控植物非生物胁迫应答的表观遗传机制研究取得了一系列重要进展, 为进一步深入解析植物响应非生物胁迫的分子机制奠定了基础。该文对DNA甲基化修饰、组蛋白修饰、染色质重塑和非编码RNA等主要表观遗传调控方式在植物响应非生物胁迫中的作用进行了简要综述。     

表观遗传修饰在作物重要性状形成中的作用

表观遗传修饰是指染色体DNA和组蛋白上的化学修饰,主要包括DNA甲基化、组蛋白修饰和非编码RNA。在不改变DNA序列的情况下,这些修饰可以通过改变染色质状态来影响遗传信息的表达,并具有可遗传性,对植物的生长发育具有重要的调控作用。当特定的表观遗传修饰发生改变时,农作物可以获得优异的表型、更强的环境适应性,因此人为改变表观遗传修饰有望获得更适于农业生产的优质种质资源。本文综述了植物表观遗传修饰的主要类型及其在作物重要性状的形成和环境胁迫响应中的相关研究进展,总结了表观遗传学应用于作物改良必须解决的主要问题,以期在表观遗传修饰层面为作物的育种改良提供新思路。     

癌变重编程的表观遗传调控机制研究进展

肿瘤发生和恶化转化过程中导致细胞的异常编程,并由此产生了肿瘤干细胞。肿瘤干细胞具有自我更新和可塑性潜能,是肿瘤起始、转移、耐药和复发的根源。因此,对肿瘤重编程和肿瘤干细胞的研究具有重大科学价值和临床意义。表观遗传调控在肿瘤重编程中发挥重要作用。染色质重塑复合物、组蛋白修饰和非编码RNA等表观遗传机制都参与了癌变重编程。这些表观遗传调控可以调控肿瘤干细胞的自我更新和分化形成新肿瘤的能力。表观遗传调控癌变重编程、肿瘤干细胞自我更新的调控以及针对肿瘤干细胞表观调控机制的靶向治疗等问题,已成为肿瘤生物学研究的重点。现就染色质重塑复合物、组蛋白修饰和非编码RNA对癌变重编程和肿瘤干细胞调控的研究进展进行了综述。     

昆虫滞育表观遗传调控的研究进展

滞育是昆虫躲避不良环境的一种策略,对延续昆虫种群具有重要意义。特别是昆虫的兼性滞育,能够受环境的周期性季节变化影响,表观遗传可能在其中扮演重要角色。表观遗传是不依赖DNA序列改变所产生的可遗传变异,包括DNA、RNA、蛋白质和染色质水平上的各种表观遗传调控过程,可能参与生物的发育可塑性。昆虫滞育表观遗传调控主要包括两个方面：一是表观遗传调控如何响应滞育诱导的环境信号;二是环境信号诱导的表观遗传调控如何作用昆虫滞育。尽管已有报道提示DNA甲基化可以响应光周期信号,组蛋白乙酰化能够耦联昆虫内分泌信号,但表观遗传调控参与昆虫滞育的具体机制尚不完全清楚。表观遗传调控昆虫滞育在不同滞育类型的昆虫中都有报道。对于同一滞育类型,不同表观遗传过程之间可能存在协同,这种协同作用如何响应环境信号,又如何精确调节昆虫滞育仍不得而知。总之,现有研究仅仅展示了表观遗传调控昆虫滞育的可能性,昆虫滞育表观遗传调控的分子机制亟待深入研究,特别是以下几个方面：(1)表观遗传响应滞育诱导环境信号的分子机制研究;(2)表观遗传耦联内分泌调控的分子机制研究;(3)介导表观遗传调控的细胞信号转导研究;(4)表观遗传的协同调控在昆虫滞育中的功能研究。     

黑色素瘤发生发展中的表观遗传学调控

人恶性黑色素瘤(malignant melanoma)是近年来高发病率和高死亡率的肿瘤之一.目前尚缺乏有效的治疗方法.而表观遗传如DNA甲基化(DNA methylation)、组蛋白修饰(histonemodification)、染色质重塑(chromatin remodeling)及RNA干扰(RNA interference,RNAi)等改变在人黑色素瘤的发生、发展和转移中有重要作用.阐明黑色素瘤发生发展的表观遗传学机制已引起了学者的普遍关注.本文综述了人类黑色素瘤发生发展中所特异的表观遗传改变:CpG岛的异常甲基化修饰、组蛋白甲基化和乙酰化修饰、染色质重塑以及microRNA在黑色素瘤发生和转移中的作用,并对应用表观遗传修饰治疗人类黑色素瘤进行了探讨.     

染色质重塑复合物SAGA及其同源物的功能

基因表达调控是生物体生长发育的一个重要环节.在这一过程中,染色质重塑复合物扮演了非常重要的作用.SAGA是一个至少由20个蛋白组成的不依赖ATP的多功能染色质重塑复合物,它通过对组蛋白H3和H2B氨基末端赖氨酸乙酰化修饰来松动染色质结构,从而促进基因转录的起始.目前,对SAGA及其同源物的研究表明,SAGA及其同源物参与了许多重要的生物学功能,如mRNA输出、DNA损伤修复、胚胎发育、细胞癌变等.     

Structures and analysis of highly homologous psychrophilic, mesophilic, and thermophilic adenylate kinases

The crystal structures of adenylate kinases from the psychrophile Bacillus globisporus and the mesophile Bacillus subtilis have been solved and compared with that from the thermophile Bacillus stearothermophilus. This is the first example we know of where a trio of protein structures has been solved that have the same number of amino acids and a high level of identity (66-74%) and yet come from organisms with different operating temperatures. The enzymes were characterized for their own thermal denaturation and inactivation, and they exhibited the same temperature preferences as their source organisms. The structures of the three highly homologous, dynamic proteins with different temperature-activity profiles provide an opportunity to explore a molecular mechanism of cold and heat adaptation. Their analysis suggests that the maintenance of the balance between stability and flexibility is crucial for proteins to function at their environmental temperatures, and it is achieved by the modification of intramolecular interactions in the process of temperature adaptation.     

Chromatin‐based mechanisms of temperature memory in plants

For successful growth and development, plants constantly have to gauge their environment. Plants are capable to monitor their current environmental conditions, and they are also able to integrate environmental conditions over time and store the information induced by the cues. In a developmental context, such an environmental memory is used to align developmental transitions with favourable environmental conditions. One temperature‐related example of this is the transition to flowering after experiencing winter conditions, that is, vernalization. In the context of adaptation to stress, such an environmental memory is used to improve stress adaptation even when the stress cues are intermittent. A somatic stress memory has now been described for various stresses, including extreme temperatures, drought, and pathogen infection. At the molecular level, such a memory of the environment is often mediated by epigenetic and chromatin modifications. Histone modifications in particular play an important role. In this review, we will discuss and compare different types of temperature memory and the histone modifications, as well as the reader, writer, and eraser proteins involved.     

Oxygen concentration drives local adaptation in the greenlip abalone (Haliotis laevigata)

Understanding adaptation has become one of the major biological questions especially in the light of rapid environmental changes induced by climate change. Ocean temperatures are rising which triggers massive changes in water chemistry and thereby alters the living environment of all marine organisms. Studying adaptation, however, can be tricky because spatial genetic patterns might also occur due to random effects, for example, genetic drift. Genetic drift is reduced in very large and well‐connected populations, such as in broadcast marine spawning organisms. Here, spatial genetic divergence is likely to be produced by selection. In this issue of Molecular Ecology, Sandoval‐Castillo et al. (2018) investigated patterns of spatial genetic divergence and their association with environmental factors in the greenlip abalone (Haliotis laevigata). This commercially important species of mollusc is a broadcast spawner with large population sizes, rendering genetic drift an unlikely factor in the genetic divergence of wild populations. Sandoval‐Castillo et al. (2018) used a ddRAD genomic approach to test for genetic divergence between sampled populations while also measuring different environmental factors, for example, water temperature and oxygen content. The majority of identified SNPs was putatively neutral and showed only low levels of genetic divergence between field sites. However, 323 candidate adaptive markers were identified that clearly separated the individuals into five different clusters. These genetic clusters correlated with environmental clusters mainly determined by water temperature and (correlated) oxygen concentration. Gene annotation of the candidate SNPs revealed a large proportion of loci being involved in biological processes influenced by oxygen availability. The study by Sandoval‐Castillo et al. (2018) in this issue of Molecular Ecology exemplifies the benefits of combining genomic studies with ecological data. It is a great starting point for more detailed (gene function, physiology) as well as broader (biodiversity) investigations that might help us to better understand adaptation and predict ecosystems' resilience and resistance to environmental disturbances. In addition, this information can be applied to implement optimal conservation regime policies and sustainable harvesting strategies, hopefully protecting biodiversity as well as commercial interests in marine life.     

Capturing microscopic features of bone remodeling into a macroscopic model based on biological rationales of bone adaptation

To understand Wolff’s law, bone adaptation by remodeling at the cellular and tissue levels has been discussed extensively through experimental and simulation studies. For the clinical application of a bone remodeling simulation, it is significant to establish a macroscopic model that incorporates clarified microscopic mechanisms. In this study, we proposed novel macroscopic models based on the microscopic mechanism of osteocytic mechanosensing, in which the flow of fluid in the lacuno-canalicular porosity generated by fluid pressure gradients plays an important role, and theoretically evaluated the proposed models, taking biological rationales of bone adaptation into account. The proposed models were categorized into two groups according to whether the remodeling equilibrium state was defined globally or locally, i.e., the global or local uniformity models. Each remodeling stimulus in the proposed models was quantitatively evaluated through image-based finite element analyses of a swine cancellous bone, according to two introduced criteria associated with the trabecular volume and orientation at remodeling equilibrium based on biological rationales. The evaluation suggested that nonuniformity of the mean stress gradient in the local uniformity model, one of the proposed stimuli, has high validity. Furthermore, the adaptive potential of each stimulus was discussed based on spatial distribution of a remodeling stimulus on the trabecular surface. The theoretical consideration of a remodeling stimulus based on biological rationales of bone adaptation would contribute to the establishment of a clinically applicable and reliable simulation model of bone remodeling.     

Stochastic and regulatory role of chromatin silencing in genomic response to environmental changes

Phenotypic diversity and fidelity can be balanced by controlling stochastic molecular mechanisms. Epigenetic silencing is one that has a critical role in stress response. Here we show that in yeast, incomplete silencing increases stochastic noise in gene expression, probably owing to unstable chromatin structure. Telomere position effect is suggested as one mechanism. Expression diversity in a population achieved in this way may render a subset of cells to readily respond to various acute stresses. By contrast, strong silencing tends to suppress noisy expression of genes, in particular those involved in life cycle control. In this regime, chromatin may act as a noise filter for precisely regulated responses to environmental signals that induce huge phenotypic changes such as a cell fate transition. These results propose modulation of chromatin stability as an important determinant of environmental adaptation and cellular differentiation.