微卫星DNA标记在蚌科生物多样性保护中的应用

蚌科动物是世界上最濒危的动物类群之一,对该类动物的生物多样性保护是非常有意义的。微卫星DNA标记的发展和利用将有利于蚌科动物的遗传多样性保护。从微卫星标记的特点、研究方法、研究结果等方面综述了微卫星DNA标记在蚌科动物中的研究进展,并展望了中国蚌科微卫星DNA标记的研究方向。     

基于红外相机监测的白马雪山哺乳动物资源调查

2011年10月28日至2012年3月16日,采用红外相机自动拍照技术监测了白马雪山哺乳动物资源。共获得野生动物照片1 618张,有效的兽类照片504张,监测到大、中型兽类15种。研究区内拍照率居前4位的是鬣羚、麝、毛冠鹿和斑羚,4种偶蹄类的照片数之和占到所有大中型兽类照片数的90%。对拍照率最高的4种偶蹄类动物活动规律分析表明:麝和鬣羚为典型的夜行性动物,毛冠鹿则具有晨昏活动习性,而斑羚无明显的活动高峰。生态位重叠指数分析表明,高山麝和毛冠鹿与中华鬣羚的生态位高度重叠,川西斑羚与其他3种同域分布的偶蹄类动物生态位部分重叠。4种偶蹄类动物在生境选择上存在差别。活动规律及微生境选择上的差别可能是容许4种偶蹄类物种共存的基础。     

贺兰山偶蹄类动物资源及保护现状研究

作者于１９９５－１９９６年对贺兰山的偶蹄类动物的保护现状进行了研究。涉及四个种类,盘羊已经绝迹,马麝处于濒危状态,岩羊和马鹿还有一定的数量。贺兰山马鹿,Ｃｅｒｖｕｓ ｅｌａｐｈｕｓ的一个亚种,是我国唯一境存的阿拉善马鹿亚种的有效群。对这些偶蹄类种群的最大威胁来自于非法狩猎,人为干扰和家畜数量。     

隐种及其在两栖动物中的研究进展

近年来,由于分子生物学的迅猛发展,物种内隐藏的生物多样性越来越多地被发现,由此引发的隐种问题也备受关注。隐种的存在对现有的生物多样性评估提出了挑战。在实践上,隐种的界定对于自然资源的保护和管理具有重要意义。两栖动物由于迁移能力较弱,通常具有较强的遗传分化,因而可能包含较丰富的隐种多样性。简述了隐种的概念和形成机制,归纳了国内外两栖类动物中隐种的研究进展,并着重介绍了界定两栖动物隐种的研究方法,最后,对今后两栖动物隐种的研究作了简要展望。我国两栖动物资源丰富,并具有独特的地形和气候特点,对这些物种遗传多样性和系统地理学的研究亟待开展。     

景观遗传学：概念与方法

全球变化下的物种栖息地丧失和破碎化给生物多样性保护带来了新的问题和挑战,生物多样性保护必须由单纯的物种保护上升到栖息地景观的保护。景观遗传学是定量确定栖息地景观特征对种群遗传结构影响的一门交叉学科,在生物保护及自然保护区管理方面有巨大的潜力。从生物多样性保护的角度评述了景观结构与遗传多样性的关系,介绍了景观遗传学的基本概念,研究尺度和方法,并对景观遗传学当前的研究焦点及面临的挑战做了总结。     

鸡的遗传多样性的研究方法及研究进展

遗传多样性是生物学研究中的一个重要领域,研究鸡的遗传多样性,不仅能加强生物多样性的保护。同时对起源进化、分类鉴定及遗传育种等都有重要的意义。本文对目前DNA水平鸡的遗传多样性的研究方法和研究进展进行了详细的阐述。重点介绍了DNA分子标记的特征;概括了在鸡遗传多样性分子标记的方法,包括微卫星分子标记(SSR)、扩增片段长度多态性(AFLP)、随机扩增多态性标记(RAPD)、限制性片段长度多态性标记(RFLP)和单核苷酸多态性标记(SNP)。本文综述了最近有关鸡DNA水平的遗传多样性的研究方法在系统学、遗传结构、生物地理等研究中的应用情况;提出在研究鸡遗传多样性时,可根据研究的目的,选择合适的方法。     

《遗传多样性研究的原理与方法》评介

遗传多样性是生物多样性的重要组成部分 ,是物种进化潜能的保证 ,也是人类社会赖以生存和发展的物质基础。对于遗传多样性的科学研究 ,始于 2 0世纪 30年代初 ,它是运用现代遗传学、保护生物学和稍后的分子生物学的理论和方法 ,对物种和群体的遗传性状多样性进行深入研究的基础上发展起来的一门学科。近年来在生物多样性保护研究的推动下 ,我国的遗传多样性研究取得了长足的进展。在人类社会面临着环境保护与发展的尖锐矛盾的情况下 ,深入开展遗传多样性的研究 ,对于生物多样性的保护和生物资源的可持续利用 ,都具有重要而深远的意义。《遗…     

植物保护遗传学研究进展

保护遗传学是过用遗传学的原理和研究手段,以生物多样性尤其是遗传多样性的研究和保护为核心的一门新兴学科,近几十年来,遗传学研究在生物多样性保护的理论和实践中发挥着越来越重要的作用。本文简要回顾了保护遗传学的发展历史,研究方向和涉及的概念,着重介绍了植物保护遗传学研究所取得的一些进展,包括植物系统发育重建和保护单元的确定,遗传多样性与物种和群体适应性之间的关系,群体遗传结构与保护策略的制定以及植物遗传资源的鉴定和利用等方面的内容,并强调保护遗传学研究是未来生物多样性和保护生物学研究中一个亟待加强的研究领域。     

珍稀濒危植物海南粗榧种群遗传多样性研究

利用RAPD技术对珍稀濒危植物海南粗榧（Cephalotaxus manniiHook.f.)遗传多样性水平,分布、濒危原因及物种保护等问题进行了探讨。结果表明：1、海南粗榧在海南岛的5个取样地点表现出低水平的遗传多样性,对环境变化物适应能力不强;2、海南粗榧种群内和种群间的遗传多样性所占比例有很大差异,绝大部分变异分布于种群内（DAN多样性为85.1%);种群间仅有较低程度的分化;3、人为砍伐,植被破坏,台风、被食用遗传漂变是海南粗榧遗传多样性低水平的主要原因,也是物种濒危的主要原因;4、对于呈零星分布的濒危植物海南粗榧的研究与保护,应充分考虑个体小环境之间的差异。考虑影响小种群的随机因素;5、应采取有力措施,就地保护现有种群,并寻求适当的方法迅速扩展种群,降低基因丧失率;选择遗传多样性较高且破坏相对较小的黎母岭种群作为保护重点;同时应加强对其他种群的保护与管理;6、海南粗榧种群内,种群音质遗传多样性在不同引物之间有较大差别。多态性位点百分率则是种群间的变化大于引物间的变化。     

珍稀濒危植物海南粗榧种群遗传多样性研究

利用RAPD技术对珍稀濒危植物海南粗榧(Cephalotaxus mannii Hook . f.)遗传多样性水平、分布、濒危原因及物种保护等问题进行了探讨.结果表明:1. 海南粗榧在海南岛的5个取样地点表现出低水平的遗传多样性,对环境变化的适应能力不强; 2. 海南粗榧种群内和种群间的遗传多样性所占比例有很大差异,绝大部分变异分布于种群内(DNA多样性为85.1%);种群间仅有较低程度的分化;3. 人为砍伐、植被破坏、台风、被食及遗传漂变是海南粗榧遗传多样性低水平的主要原因,也是物种濒危的主要原因;4. 对于呈零星分布的濒危植物海南粗榧的研究与保护,应充分考虑个体小环境之间的差异,考察影响小种群的随机因素;5. 应采取有力措施,就地保护现有种群,并寻求适当的方法迅速扩展种群,降低基因丧失率;选择遗传多样性较高且破坏相对较小的黎母岭种群作为保护重点;同时应加强对其他种群的保护与管理;6. 海南粗榧种群内、种群间的遗传多样性在不同引物之间有较大差别;多态性位点百分率则是种群间的变化大于引物间的变化.     

岷江柏野生居群和迁地保护居群的遗传多样性比较

通过分析岷江柏的迁地保护居群和野生居群的遗传多样性、遗传结构及居群间基因流,判断迁地保 护岷江柏居群的遗传多样性水平,为其迁地保护提供理论基础。本研究利用GBS（Genotyping-by-Sequencing） 测序技术获得的SNP位点对四川大渡河双江口岷江柏迁地保护移栽苗、苗圃播种苗及3个野生居群进行主成分分析（PCA分析）、聚类分析、分子进化树、遗传多样性和遗传结构分析。经过GBS测序共获得高质量Clean Data 118 321 514 728 bp,并开发了1947 047个tags,从中鉴定到了1 259 610个SNP位点。系统发育进化树显示大部分移栽岷江柏居群和野生岷江柏聚在一起,居群结构分析结果显示交叉验证错误率的谷值确定最优分群数为1。4个岷江柏居群的观测杂合度（H_o）、期望杂合度（H_e）、Shannon信息指数I（S_hi）、近交系数（F_is）、多态信息含量（P_ic）的值分别为0.181 5~0.272 0、0.223 2~0.300 3、0.331 0~0.464 9、0.178 0~0.246 5和0.272 2~0.309 2,说明岷江柏居群的遗传多样性水平较高。移栽岷江柏居群的H_e=0.300 3,S_hi=0.464 9,岷江柏居群迁地保护居群遗传多样性总体水平略高于野生居群。野生岷江柏居群中白湾隧道（BW）_vs_松岗镇（SA）的遗传分化指数（F_st）较大,基因流（N_m）较小（F_st=0.091,N_m=2.496）,而迁地保护的岷江柏居群与野生岷江柏居群没有明显的遗传分化,居群间的基因交流频繁（F_st<0.05,基因流N_m>4）,说明没有明显的分群现象,岷江柏居群迁地保护居群遗传多样性较高。因此,移栽濒危植物是迁地保护过程中较好的方法,本文为以后野生岷江柏迁地保护提供参考,为其他树木种质资源的保存提供理论依据。     

Molecular genetic analysis of wild soybean (Glycine soja Sieb. & Zucc.) population structure in anthropogenic and natural landscapes of Primorskii krai

The data are presented on genetic population structure of wild soybean growing in natural and anthropogenically disturbed landscapes of Primorskii krai of the Russian Federation. Comparative analysis showed that wild soybean populations exposed to anthropogenic influence exhibited lower genetic diversity than natural populations. Recommendations on conservation of the wild plant gene pools using comparative data on population genetic structures are made.     

Molecular genetic analysis of wild soybean (<Emphasis Type="Italic">Glycine soja</Emphasis> Sieb. &; Zucc.) population structure in anthropogenic and natural landscapes of Primorskii krai

The data are presented on genetic population structure of wild soybean growing in natural and anthropogenically disturbed landscapes of Primorskii krai of the Russian Federation. Comparative analysis showed that wild soybean populations exposed to anthropogenic influence exhibited lower genetic diversity than natural populations. Recommendations on conservation of the wild plant gene pools using comparative data on population genetic structures are made.     

DNA marker technology for wildlife conservation

Use of molecular markers for identification of protected species offers a greater promise in the field of conservation biology. The information on genetic diversity of wildlife is necessary to ascertain the genetically deteriorated populations so that better management plans can be established for their conservation. Accurate classification of these threatened species allows understanding of the species biology and identification of distinct populations that should be managed with utmost care. Molecular markers are versatile tools for identification of populations with genetic crisis by comparing genetic diversities that in turn helps to resolve taxonomic uncertainties and to establish management units within species. The genetic marker analysis also provides sensitive and useful tools for prevention of illegal hunting and poaching and for more effective implementation of the laws for protection of the endangered species. This review summarizes various tools of DNA markers technology for application in molecular diversity analysis with special emphasis on wildlife conservation.     

线粒体DNA（mtDNA）多态性在动物保护生物学中的应用

本文从两个方面论述了mtDNA在动物保护生物学中的应用：一是对物种进行遗传多样性的检 测与管理,二是进行与种群统计学数据相关的遗传分析。前者与保护的长期效益（如进化） 密切相关,而后者则主要用于指导短期管理措施的制定。同时,本文重点论述了mtDNA在进 化显著单位(ESUs)和管理单位(MUs)的认定方面的作用。认定ESUs的目的是隔离管理遗传多 样性,它是一系列系统进化史独特的种群,这种独特性同时表现在mtDNA和核DNA上;MUs是 种群统计意义上的生殖隔离单位,具有独特的等位基因频率,与系统发生结构和遗传分歧水 平无关。ESUs与MUs都是保护生物学中保护与管理的重要基本单位。     

Population structure of the wild soybean (Glycine soja) in China: implications from microsatellite analyses

Background and Aims Wild soybean (Glycine soja), a native species of East Asia, is the closest wild relative of the cultivated soybean (G. max) and supplies valuable genetic resources for cultivar breeding. Analyses of the genetic variation and population structure of wild soybean are fundamental for effective conservation studies and utilization of this valuable genetic resource. Methods In this study, 40 wild soybean populations from China were genotyped with 20 microsatellites to investigate the natural population structure and genetic diversity. These results were integrated with previous microsatellite analyses for 231 representative individuals from East Asia to investigate the genetic relationships of wild soybeans from China. Key Results Analysis of molecular variance (AMOVA) revealed that 43·92 % of the molecular variance occurred within populations, although relatively low genetic diversity was detected for natural wild soybean populations. Most of the populations exhibited significant effects of a genetic bottleneck. Principal co-ordinate analysis, construction of a Neighbor-Joining tree and Bayesian clustering indicated two main genotypic clusters of wild soybean from China. The wild soybean populations, which are distributed in north-east and south China, separated by the Huang-Huai Valley, displayed similar genotypes, whereas those populations from the Huang-Huai Valley were different. Conclusions The previously unknown population structure of the natural populations of wild soybean distributed throughout China was determined. Two evolutionarily significant units were defined and further analysed by combining genetic diversity and structure analyses from Chinese populations with representative samples from Eastern Asia. The study suggests that during the glacial period there may have been an expansion route between south-east and north-east China, via the temperate forests in the East China Sea Land Bridge, which resulted in similar genotypes of wild soybean populations from these regions. Genetic diversity and bottleneck analysis supports that both extensive collection of germplasm resources and habitat management strategies should be undertaken for effective conservation studies of these important wild soybean resources.     

Evidence of parasite-mediated disruptive selection on genetic diversity in a wild fish population

Identifying the processes maintaining genetic variability in wild populations is a major concern in conservation and evolutionary biology. Parasite-mediated selection may strongly affect genetic variability in wild populations. The inbreeding depression theory predicts that directional selection imposed by parasites should act against the most inbred hosts, thus favouring genetic diversity in wild populations. We have tested this prediction by evaluating the strength and shape of the relationship between the load of a harmful fin-feeder ectoparasite ( Tracheliastes polycolpus ) and the genome-wide genetic diversity (i.e. heterozygosity measured at a set of 15 microsatellites) of its fish host, the rostrum dace ( Leuciscus leuciscus ). Contrary to expectation, we found a nonlinear relationship between host genetic diversity and ectoparasite load, with hosts that were either homozygous or heterozygous harbouring significantly fewer parasites than hosts with an intermediate level of heterozygosity. This relationship suggests that parasites could increase the variance of global heterozygosity in this host population through disruptive selection on genetic diversity. Moreover, when genetic diversity was measured at each locus separately, we found two very strong positive associations between host genetic diversity and the ectoparasite load. This latter result has three main implications: (i) genome-wide effect cannot alone explain the nonlinear relationship between global heterozygosity and ectoparasite load, (ii) negative non-additive allelic interactions (i.e. underdominance) may be a mechanism for resisting ectoparasite infection, and (iii) ectoparasites may favour homozygosity at some loci in this host population.     

Conservation of deer: contributions from molecular biology, evolutionary ecology, and reproductive physiology

Molecular phylogenetics, interspecific comparisons, and assisted reproductive techniques are recent approaches to understanding and facilitating conservation of endangered species. This paper reviews the contribution of these approaches to a small but well-studied group of mammals, deer, many of which are endangered in the wild. Conservation efforts require a comprehensive understanding of the biology and history of these animals. The value of assisted reproductive technologies for conservation of deer has received increased awareness especially for captive populations. Such breeding programmes are designed to assist propagation of threatened species and to maximize genetic diversity within populations through the movement of genetic material across the globe, but will only be successful if we understand the genetic and reproductive potential of various lineages. Here we discuss the phylogenetic status of deer, the distinctiveness and evolution of their reproductive patterns, and current approaches for improving the success of controlled breeding programmes for the conservation of endangered lineages. Only by combining both theoretical and practical approaches to conservation efforts can we hope to salvage the remaining organismal diversity of our planet.     

Genetic assessment of the Iberian wolf Canis lupus signatus captive breeding program

The main goal of ex situ conservation programs is to improve the chances of long term survival of natural populations by founding and managing captive colonies that can serve as a source of individuals for future reintroductions or to reinforce existing populations. The degree in which a captive breeding program has captured the genetic diversity existing in the source wild population has seldom been evaluated. In this study we evaluate the genetic diversity in wild and captive populations of the Iberian wolf, Canis lupus signatus, in order to assess how much genetic diversity is being preserved in the ongoing ex situ conservation program for this subspecies. A sample of domestic dogs was also included in the analysis for comparison. Seventy-four wolves and 135 dogs were genotyped at 13 unlinked microsatellite loci. The results show that genetic diversity in Iberian wolves is comparable in magnitude to that of other wild populations of gray wolf. Both the wild and the captive Iberian wolf populations have a similarly high genetic diversity indicating that no substantial loss of diversity has occurred in the captive-breeding program. The effective number of founders of the program was estimated as ∼ ∼16, suggesting that all founders in the studbook pedigree were genetically independent. Our results emphasize also the genetic divergence between wolves and domestic dogs and indicate that our set of 13 microsatellite loci provide a powerful diagnostic test to distinguish wolves, dogs and their hybrids.     

Decreasing genetic diversity in wild and captive populations of endangered Itasenpara bittering (Acheilognathus longipinnis) in the Himi region,central Japan,and recommendations for conservation

Biodiversity is increasingly declining as a result of direct human impact and structural alteration of ecosystems resulting from changes in human life styles. Itasenpara bittering (Acheilognathus longipinnis), which has been maintained in floodplain and paddy fields, is a threatened cyprinid fish endemic to central Japan. To aid in the preservation of this species, information on genetic diversity and demographic variables in wild and captive populations was obtained using microsatellite DNA analysis. Temporal changes in genetic diversity and effective population size (N _e) tended to be relatively stable in the wild Moo River population, although lower values were detected in the wild Busshouji River population, suggesting an extremely high risk of extinction in the latter. Captive populations derived from the Busshouji River population demonstrated significant genetic divergence even among intrapopulational cohorts, suggesting the influence of genetic drift caused by geographic isolation and small population size. Active maintenance of genetic diversity in captive population is a necessary part of conservation programs, as are continuous addition of wild individuals and replacement of individuals among captive populations. In addition, increasing or maintaining suitable floodplain areas and artificial habitats such as paddy fields might contribute to the conservation of genetic diversity in the Itasenpara bittering.