核糖核酸酶基因超家族分子进化

核糖核酸酶基因(Ribonuclease A, RNASE A)超家族是进化生物学中研究新基因起源及新功能演变的重要模式系统之一。RNASE A超家族中的很多成员表现出基因复制的进化模式, 而且在适应性(正)选择的驱动下, 发生了功能分化。文章综述了RNASE A超家族成员在不同动物类群中进化模式的研究进展, 包括近年来越来越多在基因组水平上开展的相关研究, 显示该基因超家族可能具有比人们以往认识的更为复杂的基因进化模式。随着越来越多动物基因组数据的产生, 对更多动物代表类群进行RNASE A超家族研究, 将有望揭示新的进化机制和功能分化, 为系统认识动物适应进化的遗传机制奠定基础。     

煤污病菌表皮生态位适应性进化机制研究进展

煤污病是一类外寄生性植物真菌病害。煤污病菌在果实表面形成黑色污斑和污点,导致外观品质降低影响销售,给果农造成严重经济损失。真菌的适应性进化分子机制一直是植物病原真菌生态学领域的研究前沿。煤污病菌在进化过程中为适应寄主表面营养贫瘠、干旱、紫外线照射等非生物胁迫,以及与表面其他微生物竞争生物胁迫等极端环境,进化出一系列独特机制,从而成功定殖于植物表皮。本文从基因组结构趋同进化、致病相关基因家族收缩与扩张和胁迫响应等方面,系统综述了煤污菌群对表皮生态位的适应性进化分子机制。     

啮齿目核糖酸酶5基因(RNase5)的分子进化

RNase5是RNASE A基因超家族中的一个重要成员,是分子进化研究的理想模型之一。基于基因组水平,我们对啮齿目的3个进化枝10科17个物种开展RNase5的分子进化研究。利用TBlastN及BlastN方法鉴定每个基因组的RNase5基因,发现该基因在啮齿目的Ctenohystrica所有物种发生丢失,时间是在Ctenohystrica形成之后;邻接法和最大似然法构建的系统发育树均支持RNase5在“与小家鼠相关的进化枝”的小家鼠、褐家鼠和拉布拉多白足鼠发生三次独立基因复制事件;利用PAML软件的枝模型、位点模型及枝-位点模型计算选择压力,均检测到RNase5基因受到强烈的正选择作用。总之,我们的研究深入系统开展了RNase5在啮齿目中的分子进化,增加了该基因研究的多样性,为进一步系统认识该基因在动物的适应性进化遗传机制奠定了基础。     

酵母模型揭示胁迫因子驱动基因组变异的研究进展

基因组变异是遗传疾病发生和物种演化的分子基础，这个过程受到细胞内外源理化因子的共同作用。模式生物酿酒酵母（Saccharomyces cerevisiae）基因组小且易于开展分子遗传操作，在探究基因组变异进化调控机制的相关研究中应用广泛。本文总结了酵母模型中典型的DNA变异检测遗传体系，包括利用报告基因检测DNA突变率和红白扇形菌落筛选染色体重组子等；讨论了高通量测序技术在检测自发性和胁迫因子诱导基因组变异中的应用；综述了运用酵母模型揭示温度波动、氧化压力、抗肿瘤药物、金属离子和辐射等胁迫因子对基因组稳定性的影响及遗传机制的研究进展。酵母在多种胁迫条件下均会发生适应性进化现象，特定的染色体结构变异是适应性背后的重要遗传机制之一。在酵母中结合遗传筛选体系和高通量分析手段阐释细胞胁迫因子与基因组变异的关联机制，可为全面理解生物基因组不稳定机理和物种进化规律提供新的视角。     

《新植物学家》:喀斯特植物基因组研究取得进展

<正>近日,中科院华南植物园科学家在喀斯特植物基因组大小的进化及环境适应研究方面取得重要进展。相关研究在线发表于《新植物学家》杂志上。物种基因组大小的进化包括适应性和非适应性等多种机制,但不同机制在基因组大小进化过程中的重要性却存在争议。报春苣苔属是我国华南喀斯特地区物种多样性异常丰富的特有类群,又由于该属植物具有强烈的生境专化性,因而是一个研究基因组大小进化及环境适应的理想系统。     

《新植物学家》:喀斯特植物基因组研究取得进展

<正>近日,中科院华南植物园科学家在喀斯特植物基因组大小的进化及环境适应研究方面取得重要进展。相关研究在线发表于《新植物学家》杂志上。物种基因组大小的进化包括适应性和非适应性等多种机制,但不同机制在基因组大小进化过程中的重要性却存在争议。报春苣苔属是我国华南喀斯特地区物种多样性异常丰富的特有类群,又由于该属植物具有强烈的生境专化性,因而是一个研究基因组大小进化及环境适应的理想系统。     

稻属植物的基因组进化

水稻所在的稻属(Oryza)共有24个左右的物种。由于野生稻含有大量的优良农艺性状基因, 在水稻遗传学研究中日益受到重视。随着国际稻属基因组计划的开展, 越来越多的稻属基因组序列被测定, 稻属成为进行比较、功能和进化基因组学研究的模式系统。近期开展的一系列研究对稻属不同基因组区段以及全基因组序列的比较分析, 揭示了稻属在基因组大小、基因移动、多倍体进化、常染色质到异染色质的转化以及着丝粒区域的进化等方面的分子机制。转座子的活性以及转座子因非均等重组或非法重组而造成的删除, 对稻属基因组的扩增和收缩具有重要作用。DNA双链断裂修复介导的基因移动, 特别是非同源末端连接, 是稻属基因组非共线性基因形成的主要来源。稻属基因组从常染色质到异染色质的转换过程, 伴随着转座子的大量扩增、基因片段的区段性和串联重复以及从基因组其他位置不断捕获异染色质基因。对稻属不同物种间基因拷贝数、特异基因和重要农艺性状基因的进化等研究, 可揭示稻属不同物种间表型和适应性差异的分子基础, 将加速水稻的育种和改良。     

昆虫基因组大小及其进化

基因组是物种遗传信息的集合,其大小是研究基因组进化、结构及功能的重要参数之一。本文介绍了测定基因组大小的方法,简述了基因组大小的进化假说及分子机制,综述了近年来昆虫基因组大小的研究进展,尤其是昆虫基因组大小变化的相关影响因子。总体而言,昆虫基因组大小变化是一个复杂的过程,与转座子的活性有密切的关系,是基因组序列丢失和获得两种过程平衡的结果。基因组大小的变化仍在不断地进化中,其对生物造成的影响是剧烈的,因此对昆虫的表型特征产生了重要的影响,但影响的程度和关系在不同的类群有明显的差异,表现出一定的随机性,目前尚未总结出明显的规律。昆虫是生物多样性最为丰富的动物类群,是研究基因组大小进化的最佳材料,随着越来越多的昆虫基因组被测序公开,对昆虫基因组数据进行深入分析,有利于破解基因组大小进化的"C值之谜",可为生物基因组大小的研究提供重要参考。     

细菌CRISPR-Cas 系统功能及其与噬菌体相互作用

摘要:近来研究发现,细菌CRISPR-Cas 系统在宿主菌抵抗可移动基因元件(mobile genetic elements,MGEs)的过程中发挥重要作用。CRISPR-Cas还参与宿主菌群体行为和毒力基因调控、DNA修复和基因组进化过程。本文着重综述细菌CRISPR-Cas系统的结构、类型、作用机制及其适应性免疫之外的其他功能(如对内源性基因表达的调控、促进基因组进化、DNA修复等);概述噬菌体抵抗CRISPR-Cas系统的机制,并对噬菌体-宿主菌相互作用进行探讨和展望。     

血红蛋白与脊椎动物高海拔适应进化

高海拔环境是研究脊椎动物对极端环境适应进化过程的典型范例之一.血红蛋白在脊椎动物呼吸和氧化能量代谢中的核心作用决定了其无论在进化生物学还是高原医学研究领域都有着极其重要的意义.然而,如果不清楚研究对象的系统进化地位和机体本身的适应进化特点,就无法对各个水平的适应进化机制作出全面诠释.因此,对脊椎动物的低氧适应进化研究首先从机体生理需求的差异出发.此外,血红蛋白的功能适应性还表现在物种或种群间的空间分布差异导致不同程度的低氧需求.因此,本文从个体和系统发育水平评述了血红蛋白的分子进化及功能适应研究,深入比较了长期定居和短期移居物种间的适应机制区别,系统分析了鸟类及其他脊椎动物适应高海拔低氧环境的趋同和趋异进化特征.最后通过评价不同研究方法的优缺点,结合功能蛋白和物种进化相似的分子遗传规律,为未来高海拔低氧适应进化及高原医学研究提出一些新的思考.总之,本文支持功能验证在适应性进化相关基因研究中的必要性,强调整合分子、细胞和系统水平确定研究方案的重要性,以及系统发育背景和种群进化历史在研究对象选择中的重要意义.     

Anatomical diversification of a skeletal novelty in bat feet

Neomorphic, membrane‐associated skeletal rods are found in disparate vertebrate lineages, but their evolution is poorly understood. Here we show that one of these elements—the calcar of bats (Chiroptera)—is a skeletal novelty that has anatomically diversified. Comparisons of evolutionary models of calcar length and corresponding disparity‐through‐time analyses indicate that the calcar diversified early in the evolutionary history of Chiroptera, as bats phylogenetically diversified after evolving the capacity for flight. This interspecific variation in calcar length and its relative proportion to tibia and forearm length is of functional relevance to flight‐related behaviors. We also find that the calcar varies in its tissue composition among bats, which might affect its response to mechanical loading. We confirm the presence of a synovial joint at the articulation between the calcar and the calcaneus in some species, which suggests the calcar has a kinematic functional role. Collectively, this functionally relevant variation suggests that adaptive advantages provided by the calcar led to its anatomical diversification. Our results demonstrate that novel skeletal additions can become integrated into vertebrate body plans and subsequently evolve into a variety of forms, potentially impacting clade diversification by expanding the available morphological space into which organisms can evolve.     

食肉目哺乳动物的系统发育学研究概述

追溯生物界不同生物类型的起源及进化关系,即重建生物类群的系统发育树是进化生物学领域中一个十分重要的内容。食肉目哺乳动物位于食物链顶端,很多成员不仅在我国野生动物保护工作中占有重要地位,而且还是研究动物适应性进化遗传机制的重要模式生物。因而,食肉目物种作为物种资源中的一个重要类群,其系统发育学一直是国内外研究的热门课题。构建可靠的食肉目分子系统树,无疑将具有重要的进化理论意义和保护生物学价值。鉴于目前食肉目各科间系统发育关系仍然处于“广泛争论”的状态,本文将针对食肉目科水平上的系统发育学研究进展,包括来自于形态学特征、细胞学及分子生物学方面的证据,做简要概述,并提出目前研究中存在的问题。这对今后食肉目系统发育方面的进一步研究工作具有指导意义,并为以该类群作为模式生物开展适应性进化研究奠定基础。     

Evolution of evolutionary physiology

In 19th century and at the beginning 20th century, reports appeared in the field of comparative and ontogenetic physiology and the value of these methods for understanding of evolution of functions. The term "evolutionary physiology" was suggested by A. N. Severtsov in 1914. In the beginning of 30s, in the USSR, laboratories for researches in problems of evolutionary physiology were created, the results of these researches having been published. In 1956 in Leningrad, the Institute of Evolutionary Physiology was founded by L. A. Orbeli. He formulates the goals and methods of evolutionary physiology. In the following half a century, the evolutionary physiology was actively developed. The evolutionary physiology solves problems of evolution of function of functions evolution, often involving methods of adjacent sciences, including biochemistry, morphology, molecular biology.     

The causes of repeated genetic evolution

A general understanding of the evolutionary process is limited by the contingency of each evolutionary event, making it difficult, even retrospectively, to explain why things have unfolded the way they have. The repeated evolution of similar traits in organisms facing similar environmental conditions is a pervasive phenomenon, including for animal morphology, and is considered a strong evidence for adaptive evolution. Examples of repeated evolution of particular traits offer a unique opportunity to ask whether evolution has followed similar or different genetic paths. Case studies reveal that although multiple genetic paths were often possible to evolve a morphological trait, similar evolutionary trajectories have been followed repeatedly in independent lineages, suggesting that biases influence the course of genetic evolution. In the light of these examples we examine several factors influencing the genetic paths of adaptive evolution and in particular how the interplay between natural selection and genetic variations carves out predictable genetic trajectories of morphological evolution.     

The FGGY carbohydrate kinase family: insights into the evolution of functional specificities

Function diversification in large protein families is a major mechanism driving expansion of cellular networks, providing organisms with new metabolic capabilities and thus adding to their evolutionary success. However, our understanding of the evolutionary mechanisms of functional diversity in such families is very limited, which, among many other reasons, is due to the lack of functionally well-characterized sets of proteins. Here, using the FGGY carbohydrate kinase family as an example, we built a confidently annotated reference set (CARS) of proteins by propagating experimentally verified functional assignments to a limited number of homologous proteins that are supported by their genomic and functional contexts. Then, we analyzed, on both the phylogenetic and the molecular levels, the evolution of different functional specificities in this family. The results show that the different functions (substrate specificities) encoded by FGGY kinases have emerged only once in the evolutionary history following an apparently simple divergent evolutionary model. At the same time, on the molecular level, one isofunctional group (L-ribulokinase, AraB) evolved at least two independent solutions that employed distinct specificity-determining residues for the recognition of a same substrate (L-ribulose). Our analysis provides a detailed model of the evolution of the FGGY kinase family. It also shows that only combined molecular and phylogenetic approaches can help reconstruct a full picture of functional diversifications in such diverse families.     

中国兽类遗传与进化研究进展与展望

中国兽类物种丰富,且具有150个特有种。本文综述了60年来中国兽类遗传与进化的研究进展,内容涵盖系统发育关系重建、遗传多样性评估、种群遗传结构、适应性进化以及趋同进化的分子机制。本文重点概述了食肉目（大、小熊猫）、有蹄类、翼手目、灵长目、小型兽类以及海兽类等重要类群的研究进展,为中国兽类的物种保护提供了重要资料。另外,本文还对中国兽类遗传与进化研究未来的研究方向提出几点建议,包括运用各种组学技术、筛选新型遗传标记和候选基因（调控序列）、结合表观遗传学并借助进化发育生物学研究方法,以期全面深入地理解中国兽类分类地位、起源以及特异表型产生和独特适应的发育遗传学机制等,进而实现“天人合一”保护生物学的新理念和新愿景。     

Development and function of the thymus in teleosts

The thymus plays a pivotal role in the development of the adaptive immune system, an important factor that separates higher vertebrates from the rest of the animal phyla. The development of functional T-cells from thymocytes is a crucial step in the development of a functional vertebrate immune system and whilst recent advances in molecular and developmental biology have advanced our understanding of T-cell development, they have also provided potential model species across the vertebrate phyla including the zebrafish (Danio rerio). However, this species is one of more than 20,000 species of fish that could assist in elucidating the development of the vertebrate thymus and, consequently, the evolution of the vertebrate immune response. In this paper we review the knowledge of the teleost thymus through the organogenesis and development studies in teleosts together with advances in molecular and functional approaches. Where necessary we will combine this knowledge with that obtained in higher vertebrates.     

随机进化稳定性研究进展

在过去的三十多年, 演化博弈理论及其进化稳定对策的概念不仅被广泛地应用于解释动物行为的进化, 而且也被成功地应用于分子生物学、经济学、政治学和社会学等诸多学科。然而, 在随机波动环境中演化博弈动态的随机动力学性质始终没有被清晰地认识, 并且这是一个极具挑战性的理论问题。本文简单介绍了我们最近所提出的随机进化稳定性(stochastic evolutionary stability, SES)的概念。随机进化稳定性不仅是经典进化稳定对策(evolutionarily stably strategy, ESS)概念在随机环境下的自然扩展, 而且为揭示在随机环境中动物行为的演化动态提供一个基本的理论框架。     

Evolutionary Connectionism: Algorithmic Principles Underlying the Evolution of Biological Organisation in Evo-Devo,Evo-Eco and Evolutionary Transitions

The mechanisms of variation, selection and inheritance, on which evolution by natural selection depends, are not fixed over evolutionary time. Current evolutionary biology is increasingly focussed on understanding how the evolution of developmental organisations modifies the distribution of phenotypic variation, the evolution of ecological relationships modifies the selective environment, and the evolution of reproductive relationships modifies the heritability of the evolutionary unit. The major transitions in evolution, in particular, involve radical changes in developmental, ecological and reproductive organisations that instantiate variation, selection and inheritance at a higher level of biological organisation. However, current evolutionary theory is poorly equipped to describe how these organisations change over evolutionary time and especially how that results in adaptive complexes at successive scales of organisation (the key problem is that evolution is self-referential, i.e. the products of evolution change the parameters of the evolutionary process). Here we first reinterpret the central open questions in these domains from a perspective that emphasises the common underlying themes. We then synthesise the findings from a developing body of work that is building a new theoretical approach to these questions by converting well-understood theory and results from models of cognitive learning. Specifically, connectionist models of memory and learning demonstrate how simple incremental mechanisms, adjusting the relationships between individually-simple components, can produce organisations that exhibit complex system-level behaviours and improve the adaptive capabilities of the system. We use the term “evolutionary connectionism” to recognise that, by functionally equivalent processes, natural selection acting on the relationships within and between evolutionary entities can result in organisations that produce complex system-level behaviours in evolutionary systems and modify the adaptive capabilities of natural selection over time. We review the evidence supporting the functional equivalences between the domains of learning and of evolution, and discuss the potential for this to resolve conceptual problems in our understanding of the evolution of developmental, ecological and reproductive organisations and, in particular, the major evolutionary transitions.