家养动物的起源与驯化研究进展

动物的驯化是新石器时代农业革命的主要内容之一, 导致了人类生活方式从狩猎向畜牧的转变。开展家养动物起源与驯化的研究, 不仅有助于了解人类社会的发展史和人工选择下动物的进化过程, 而且有助于开展家养动物的良种选育和遗传多样性保护, 因此该研究领域受到了人们的长期关注。近年来, 随着更多考古证据的发现与分子遗传学的发展, 人们对于家养动物的起源与驯化有了更深入的认识。本文对家养动物起源与驯化研究中一些基本问题的研究方法和进展进行了综述。文章第一部分介绍了家养动物的野生祖先、起源地、起源时间、建群者大小和扩散路线等问题; 第二部分则涉及家养动物驯化的条件、过程、性状改变及其遗传机制等方面。最后指出了家养动物起源与驯化研究中依然存在的问题, 并对未来研究发展的趋势进行了讨论。     

家马的驯化起源与遗传演化特征

人类文明发展历史中, 家马(Equus ferus caballus)曾是推动文化交流、促进人类社会发展的主要动力。关于家马何时、何地被驯化以及在此过程中其遗传演化如何被人类影响等一直备受关注。近年来随着遗传学技术的发展, 人们对该问题有了更为深入的理解。本文回顾了近二十年来相关研究所取得的成果, 探讨了家马的驯化起源中心和驯化过程中的遗传演化特征, 并对未来的研究方向以及遗传资源保护提出了建议。分子标记遗传学和考古学研究认为家马可能来自多个驯化起源地种群, 然而最近的古DNA研究结果表明, 现代家马的驯化起源可能比之前人们所猜测的更加复杂, 古代博泰马被认为是最早被驯化的家马, 然而最近被证实并不是现代家马的直系祖先。如此复杂的驯化问题可能从多学科的层次才能解析清楚。人类社会活动直接或间接影响了家马的演化历程, 特别是工业革命以来家马的遗传基础发生了巨大变化, 其遗传多样性开始急剧衰退, 不少地方品种正逐渐走向衰落甚至灭绝。为确保农业生态安全不受威胁, 建议加强家马遗传资源保护与动物遗传学和文化地理之间的联系研究。     

家马的起源历史与品种驯化特征

在家犬(Canis lupus familiaris)、牛(Bos taurus)、猪(Sus scrofa domesticus)、绵羊(Ovis aries)、山羊(Capra hircus)等家养动物之后,家马(Equus caballus)才被人类成功驯化。虽然驯化历史很短,但其对人类社会文明发展变革的影响却最大。家马出色的负重移动能力使人类社会由固定的农耕模式向移动分享模式过渡,使历史发展进入了快车道,因此其起源驯化历史一直备受关注。然而由于家马直系同源野生种早已灭绝,加之现代品种化培育引起遗传多样性骤减,使得相关研究长期争议不断。随着测序技术的不断发展和古代样品的逐步丰富,目前对家马起源驯化过程、群体遗传结构等方面的研究越来越深入。本文从核基因、mtDNA、Y染色体、古DNA等不同层面综述了家马起源与驯化历史方面的研究进展,从品种分化状况、群体演化特征等方面讨论了现代家马品种的群体遗传结构,最后总结了马匹毛色、速度、体型等重要表型性状的遗传基础,以期为今后家马的起源驯化研究、种质资源保护与开发、品种优化方向、现代马业发展等方面提供参考。     

长江流域野生猕猴桃遗传资源的潜在价值、现状分析与保护策略

长江流域是猕猴桃属(Actinidia)植物起源和演化的关键分布区, 富集了全世界重要的猕猴桃属野生物种资源和中华-美味猕猴桃物种复合体(Actinidia chinensis-A. deliciosa species complex)的种群遗传资源。作为水果作物, 猕猴桃在100多年前从长江流域经上海到新西兰, 通过栽培、驯化, 逐渐发展成新兴果树产业。目前, 猕猴桃植物的研究已在二倍体“红阳”中华猕猴桃(Actinidia chinensis cv. Hongyang)的基因组测序、种间关系的重测序分析和基础的分子系统发育、种群遗传结构等方面取得长足进步, 但基于最新研究成果的基本资源评价还相当匮乏, 对猕猴桃野生资源的保护与可持续利用亟待加强。本文回顾了栽培猕猴桃的驯化简史与猕猴桃属植物系统分类的研究进展, 通过与其他流域的比较, 对长江流域野生猕猴桃资源的潜在价值和现状进行分析, 阐述了该流域猕猴桃属植物的分布特点和受威胁的状况, 并针对目前存在的问题提出建立长效的保护机制、加强遗传资源的基础科研调查和系统评价, 以及健全种质资源保存规范和促进可持续利用等相应保护的策略。     

动物线粒体基因组研究进展

对动物线粒体分子生物学的最新研究进展进行了较详细的阐述.从线粒体基因组(mtDNA)的研究背景出发,重点介绍了动物线粒体基因组的组成和结构特点,以及目前动物mtDNA与核基因组的关系、线粒体基因的遗传、起源和进化研究中的热点问题.     

是金子无论在何处都发光: 玉米和水稻驯化中的趋同选择

野生植物的驯化为人类定居与文明起源奠定了重要基础。在世界范围内不同地区生活的古人类分别对当地不同的野生植物进行了驯化, 而经过驯化的作物常常表现出相似的驯化综合性状。在基因组层面上对趋同选择规律的解析, 可为作物育种提供重要信息与遗传资源。近日, 中国农业大学杨小红/李建生和华中农业大学严建兵领衔的团队从单基因和全基因组2个层次系统解析了玉米(Zea mays)和水稻(Oryza sativa)趋同选择的遗传基础, 发现玉米KRN2与水稻OsKRN2受到了趋同选择, 并通过相似的途径调控玉米与水稻的粒数与产量。他们还发现玉米与水稻在全基因组范围内存在大量趋同选择同源基因对(gene pair), 这些基因在淀粉代谢、糖及辅酶合成等途径特异富集。该研究不仅克隆了在玉米与水稻中均具有重要育种价值的趋同选择同源基因对KRN2/OsKRN2, 而且在全基因组水平上揭示了玉米与水稻趋同选择的规律, 为进一步解析驯化综合性状形成的分子机理及其在育种中的应用奠定了重要理论基础。     

绵羊遗传进化史的一次全新解析

<正>动物驯化是人类活动与自然环境互作的重要事件,也是人类文明发展的先决条件之一.绵羊(Ovis aries)作为最早被驯化的动物之一,早期的研究证据显示,现代家养绵羊驯化自亚洲摩弗伦羊(O.orientalis)[1],其驯化约在8000~11000年以前的新月沃土(fertile crescent)地区完成.驯化后的绵羊随着人类活动扩散至世界各地,在不断扩散过程中经过长期的自然选择与高强度的人工选择,形成多达1400余个绵羊品种.而在此过程中,人类活动对于品种内、种群间的遗传模式与基因交流起到了决定性作用[2].因此,对于整个欧亚大陆范围内地方绵羊品种     

牛、绵羊角的遗传定位及遗传机制研究进展

角属于动物颅骨附属物,为反刍动物所特有。牛(Bos taurus)、绵羊(Ovis aries)角的表型包括野生型两角表型、人工驯化的无角表型、畸形角等多种。牛和绵羊是阐明角的质量性状和数量性状之间的关系以及质量性状的多基因调控机制等方面的理想动物模型。近年来,对角性状研究不断深入,在阐明新器官起源进化、自然选择、性别选择和人工选择对角表型的影响等方面取得了一系列进展。本文详细介绍了角的研究概况、多角表型遗传定位、无角位点基因遗传定位和畸形角等,并对目前牛和绵羊角的遗传机制及存在的问题进行了分析,以期为反刍动物角性状和其他特异性性状遗传机制研究提供参考。     

遗传多样性上限假说所揭示的进化历程

作为生物进化的两个主流理论, 中性学说和现代达尔文进化理论相对系统地揭示了进化机理和历程, 但也都有缺陷, 比如对某些重大进化现象如遗传等距离和重叠位点(Overlap sites)的忽视, 对复杂性的视而不见, 对遗传多样性的片面解读, 以及与化石证据相悖等。遗传多样性上限假说(Maximum genetic diversity hypothesis, MGD)通过对遗传等距离现象的重新解读, 给出了复杂性的量化定义和可操作研究手段, 提出了重叠特征和遗传多样性具有上限等结论。它对人猿分类关系和现代人多地区起源的分子解读结论, 与独立的化石证据契合度较高, 重新肯定了中国在人类发展中的关键作用, 点出了流行分子结论的荒谬在于误用了极限距离。该理论同时对复杂性状和复杂疾病的遗传机制研究具有指导意义。文章对多种酵母、鱼类、灵长类的细胞色素c进行序列比对, 独立验证了MGD假说的部分论断, 并解释了重叠位点在遗传距离计算上的重要意义。MGD假说中的上限或最佳平衡概念, 与传统国学和中医阴阳中庸思想对宇宙基本规律的描述是一脉相承的。     

中国重要海洋动物遗传多样性的研究进展

海洋动物遗传多样性的研究不仅可以揭示物种的起源与进化历史,而且为遗传资源的保存、海水养殖动物育种和遗传改良及整个海洋生态环境的修复和稳定等工作提供理论依据.本文概述了近十几年来我国重要海洋动物(主要包括鱼类、虾蟹类和贝类)遗传多样性研究所取得的成果,具体阐述其在种质鉴定、系统进化、群体遗传结构分析和良种培育等方面的应用,以期进一步推动海洋动物遗传多样性研究,加快优良种质的培育,促进海水养殖业的健康发展,实现海洋生物资源的合理开发和可持续利用.     

Evolutionary domestication in Drosophila subobscura

The domestication of plants and animals is historically one of the most important topics in evolutionary biology. The evolutionary genetic changes arising from human cultivation are complex because of the effects of such varied processes as continuing natural selection, artificial selection, deliberate inbreeding, genetic drift and hybridization of different lineages. Despite the interest of domestication as an evolutionary process, few studies of multicellular sexual species have approached this topic using well-replicated experiments. Here we present a comprehensive study in which replicated evolutionary trajectories from several Drosophila subobscura populations provide a detailed view of the evolutionary dynamics of domestication in an outbreeding animal species. Our results show a clear evolutionary response in fecundity traits, but no clear pattern for adult starvation resistance and juvenile traits such as development time and viability. These results supply new perspectives on the confounding of adaptation with other evolutionary mechanisms in the process of domestication.     

ARCHAEOLOGICAL DATA REVEAL SLOW RATES OF EVOLUTION DURING PLANT DOMESTICATION

Domestication is an evolutionary process of species divergence in which morphological and physiological changes result from the cultivation/tending of plant or animal species by a mutualistic partner, most prominently humans. Darwin used domestication as an analogy to evolution by natural selection although there is strong debate on whether this process of species evolution by human association is an appropriate model for evolutionary study. There is a presumption that selection under domestication is strong and most models assume rapid evolution of cultivated species. Using archaeological data for 11 species from 60 archaeological sites, we measure rates of evolution in two plant domestication traits—nonshattering and grain/seed size increase. Contrary to previous assumptions, we find the rates of phenotypic evolution during domestication are slow, and significantly lower or comparable to those observed among wild species subjected to natural selection. Our study indicates that the magnitudes of the rates of evolution during the domestication process, including the strength of selection, may be similar to those measured for wild species. This suggests that domestication may be driven by unconscious selection pressures similar to that observed for natural selection, and the study of the domestication process may indeed prove to be a valid model for the study of evolutionary change.     

群体遗传学下动物驯化研究进展

动物驯化是将野生动物改变为能够长期稳定饲养的家养动物的过程。作为新石器时代农业革命的内容,驯化是人类社会文明进步的重要标志之一。由于和人类的密切关系,驯化不仅改变了动物的野生状态,也改变了人类的生活习性和文明进程。动物驯化研究的关键问题包含驯化祖先是谁、驯化所产生的改变及驯化时间地点等。随着高通量基因组技术和对应分析方法的发展,目前研究动物驯化一般基于群体水平,在群体遗传学的框架下研究动物驯化过程中的重要事件。本文总结了群体遗传学下动物驯化研究的相关内容,包括群体动态历史、选择信号、基因交流等,着重介绍了基因选择初始时间和基因交流时间两个新的拓展内容及分析方法,概述了家猪(Sus scrofa f. domestica)、家鸡(Gallus gallus domesticus)、绵羊(Ovis aries)和山羊(Caprine hircus)等几种主要农业动物近期驯化研究的进展,以期为动物驯化研究提供了新的方向和视角。     

Comparison of genetic diversity at microsatellite loci and quantitative traits in hatchery populations of Japanese flounder Paralichthys olivaceus

Relationships of genetic diversity at microsatellite loci and quantitative traits were examined in hatchery-produced populations of Japanese flounder using a relatively straightforward experiment. Five hatchery populations produced by wild-caught and domesticated broodstocks were used to examine the effects of different levels (one to three generations) of domestication on the genetic characteristics of hatchery populations. Allelic richness at seven microsatellite loci in all hatchery populations was lower than that in a wild population. Genetic variation measured by allelic richness and heterozygosity tended to decrease with an increase in generations of domestication. In addition, the degree of genetic differentiation from a wild population increased with an increase in generations of domestication. Significant differences in three morphometric traits (dorsal and anal fin ray counts and vertebral counts) and three physiological traits (high temperature, salinity and formalin tolerance) were observed among the hatchery populations. The degree of phenotypic difference among populations was larger in morphometric traits than in physiological traits. The divergence pattern of some quantitative traits was similar to that observed at microsatellite loci, suggesting that domestication causes the decrease of genetic variation and the increase of genetic differentiation for some quantitative traits concomitantly with those for microsatellite loci. Significant positive correlation was observed between F _ST and the degree of phenotypic difference in the three morphometric traits and formalin tolerance, indicating that genetic variation at microsatellite loci predicts the degree of phenotypic divergence in some quantitative traits.     

The use of the method of principal components for phenogenetic analysis of the integral domestication trait

In the course of long-term experiment on domestication of silver fox, it was necessary to determine the most important behavioral features, selection for which would give domestication effect. The mathematical method of principal components was used for the analysis of 20 fox behavior traits. The combination of the initial traits which reflected the structure of the integral trait, i.e. domesticated type of behavior, was determined. The practical use of this combination seems to more adequately estimate the level of domestication of a given animal, which is indispensable for subsequent effective selection.     

Genetic basis of kernel nutritional traits during maize domestication and improvement

The nutritional traits of maize kernels are important for human and animal nutrition, and these traits have undergone selection to meet the diverse nutritional needs of humans. However, our knowledge of the genetic basis of selecting for kernel nutritional traits is limited. Here, we identified both single and epistatic quantitative trait loci (QTLs) that contributed to the differences of oil and carotenoid traits between maize and teosinte. Over half of teosinte alleles of single QTLs increased the values of the detected oil and carotenoid traits. Based on the pleiotropism or linkage information of the identified single QTLs, we constructed a trait–locus network to help clarify the genetic basis of correlations among oil and carotenoid traits. Furthermore, the selection features and evolutionary trajectories of the genes or loci underlying variations in oil and carotenoid traits revealed that these nutritional traits produced diverse selection events during maize domestication and improvement. To illustrate more, a mutator distance–relative transposable element (TE) in intron 1 of DXS2, which encoded a rate‐limiting enzyme in the methylerythritol phosphate pathway, was identified to increase carotenoid biosynthesis by enhancing DXS2 expression. This TE occurs in the grass teosinte, and has been found to have undergone selection during maize domestication and improvement, and is almost fixed in yellow maize. Our findings not only provide important insights into evolutionary changes in nutritional traits, but also highlight the feasibility of reintroducing back into commercial agricultural germplasm those nutritionally important genes hidden in wild relatives.     

Documenting domestication: the intersection of genetics and archaeology

Domestication, a process of increasing mutual dependence between human societies and the plant and animal populations they target, has long been an area of interest in genetics and archaeology. Geneticists seek out markers of domestication in the genomes of domesticated species, both past and present day. Archaeologists examine the archaeological record for complementary markers--evidence of the human behavior patterns that cause the genetic changes associated with domestication, and the morphological changes in target species that result from them. In this article, we summarize the recent advances in genetics and archaeology in documenting plant and animal domestication, and highlight several promising areas where the complementary perspectives of both disciplines provide reciprocal illumination.     

Patterns and processes in crop domestication: an historical review and quantitative analysis of 203 global food crops

CONTENTS: Summary 29 I. Introduction 30 II. Key concepts and definitions 30 III. Methods of review and analysis 35 IV. Trends identified from the review of 203 crops 37 V. Life cycle 38 VI. Ploidy level 40 VII. Reproductive strategies 42 VIII. The domestication syndrome 42 IX. Spatial and temporal trends 42 X. Utilization of plant parts 44 XI. Conclusions 44 Acknowledgements 45 References 45 SUMMARY: Domesticated food crops are derived from a phylogenetically diverse assemblage of wild ancestors through artificial selection for different traits. Our understanding of domestication, however, is based upon a subset of well-studied 'model' crops, many of them from the Poaceae family. Here, we investigate domestication traits and theories using a broader range of crops. We reviewed domestication information (e.g. center of domestication, plant traits, wild ancestors, domestication dates, domestication traits, early and current uses) for 203 major and minor food crops. Compiled data were used to test classic and contemporary theories in crop domestication. Many typical features of domestication associated with model crops, including changes in ploidy level, loss of shattering, multiple origins, and domestication outside the native range, are less common within this broader dataset. In addition, there are strong spatial and temporal trends in our dataset. The overall time required to domesticate a species has decreased since the earliest domestication events. The frequencies of some domestication syndrome traits (e.g. nonshattering) have decreased over time, while others (e.g. changes to secondary metabolites) have increased. We discuss the influences of the ecological, evolutionary, cultural and technological factors that make domestication a dynamic and ongoing process.