遗传多样性概述

遗传多样性作为生物多样性的重要组成部分,是物种多样性、生态系统多样性和景观多样性的基础。随着研究方法和实验技术的发展,遗传多样性研究从形态学水平、细胞学（染色体）水平、生理生化水平逐渐发展到分子水平。形态标记、细胞学标记、等位酶分析、DNA多态性分析等方法,为我们研究遗传多样性提供了有效的工具。特别是DNA多态性分析是一种更为直接而有效的方法。     

基因组学技术在生物多样性保护研究中的应用

在分子生物学、细胞生物学、微生物学、遗传学等学科的推动下, 生物多样性研究从仅关注宏观表型的博物学, 迅速演化为涵盖生态系统、物种和遗传多样性等多个维度的综合性生命科学。组学技术, 尤其是DNA测序技术的更新和发展, 使获取DNA序列所需的成本大幅下降, 促进了近年来其在生物多样性研究中取得的一系列令人瞩目成就。本文将从物种水平的遗传多样性和群落水平的物种多样性两个层面总结和介绍与DNA相关的组学技术在生物多样性研究中的一些创新和应用。其中, 物种水平主要是总结单一个体的基因组和单物种多个体在时空多个维度上的群体遗传研究; 而群落水平的物种多样性层面主要总结现有的分子鉴定技术(metabarcoding, eDNA, iDNA等), 以及上述新技术在群落多样性评估、旗舰保护物种监测以及物种间相互作用关系等研究中的应用。     

植物遗传多样性与生态系统功能关系的研究进展

全球变化和人类活动导致物种生境的萎缩, 造成很多植物种群数量缩减, 遗传多样性快速丧失。对于物种多样性低的生态系统, 优势种的遗传多样性可能比物种多样性对生态系统功能产生更大的影响。因此, 了解遗传多样性和生态系统功能的关系(GD-EF)及其机制对生物多样性保护、应对环境变化和生态修复具有指导意义。该文综述了植物遗传多样性对生态系统结构(高营养级生物群落结构)和生态系统功能(初级生产力、养分循环和稳定性)的影响及机制、功能多样性对GD-EF的影响、遗传多样性效应和物种多样性效应的比较, 以及GD-EF在生态修复等实际应用的研究进展。最后指出当前研究的不足之处, 以期为后续研究提供参考: 1)还需深入研究GD-EF机制; 2)未评估遗传多样性对生态系统多功能性的影响; 3)不同遗传多样性测度对生态系统功能的影响不明确; 4)缺少长期的和多空间尺度结合的GD-EF实验; 5)遗传多样性效应相对于其他因子的作用不清楚。     

A review on the relationships between plant genetic diversity and ecosystem functioning

全球变化和人类活动导致物种生境的萎缩, 造成很多植物种群数量缩减, 遗传多样性快速丧失。对于物种多样性低的生态系统, 优势种的遗传多样性可能比物种多样性对生态系统功能产生更大的影响。因此, 了解遗传多样性和生态系统功能的关系(GD-EF)及其机制对生物多样性保护、应对环境变化和生态修复具有指导意义。该文综述了植物遗传多样性对生态系统结构(高营养级生物群落结构)和生态系统功能(初级生产力、养分循环和稳定性)的影响及机制、功能多样性对GD-EF的影响、遗传多样性效应和物种多样性效应的比较, 以及GD-EF在生态修复等实际应用的研究进展。最后指出当前研究的不足之处, 以期为后续研究提供参考: 1)还需深入研究GD-EF机制; 2)未评估遗传多样性对生态系统多功能性的影响; 3)不同遗传多样性测度对生态系统功能的影响不明确; 4)缺少长期的和多空间尺度结合的GD-EF实验; 5)遗传多样性效应相对于其他因子的作用不清楚。     

环境DNA技术在地下生态学中的应用

地下生态过程是生态系统结构、功能和过程研究中最不确定的因素。由于技术和方法的限制,作为"黑箱"的地下生态系统已经成为限制生态学发展的瓶颈,也是未来生态学发展的主要方向。环境DNA技术,是指从土壤等环境样品中直接提取DNA片段,然后通过DNA测序技术来定性或定量化目标生物,以确定目标生物在生态系统中的分布及功能特征。环境DNA技术已成功用于地下生态过程的研究。目前,环境DNA技术在土壤微生物多样性及其功能方面的研究相对成熟,克服了土壤微生物研究中不能培养的问题,可以有效地分析土壤微生物的群落组成、多样性及空间分布,尤其是宏基因组学技术的发展,使得微生物生态功能方面的研究成为可能;而且,环境DNA技术已经在土壤动物生态学的研究中得到了初步应用,可快速分析土壤动物的多样性及其分布特征,更有效地鉴定出未知的或稀少的物种,鉴定土壤动物类群的幅度较宽;部分研究者通过提取分析土壤中DNA片段信息对生态系统植物多样性及植物分类进行了研究,其结果比传统的植物分类及物种多样性测定更精确,改变了以往对植物群落物种多样性模式的理解。同时,环境DNA技术克服传统根系研究方法中需要洗根、分根、只能测定单物种根系的局限,降低根系研究中细根区分的误差,并探索性地用于细根生物量的研究。主要综述了基于环境DNA技术的分子生物学方法在土壤微生物多样性及功能、土壤动物多样性、地下植物多样性及根系生态等地下生态过程研究中的应用进展。环境DNA技术对于以土壤微生物、土壤动物及地下植物根系为主体的地下生态学过程的研究具有革命性意义,并展现出良好的应用前景。可以预期,分子生物学技术与传统的生态学研究相结合将成为未来地下生态学研究的一个发展趋势。     

中国朱鹮DNA多态性研究进展

朱鹮是我国四大国宝之一,世界极濒危级鸟类。朱鹮的遗传多样性保护研究将成为生物多样性保护研究中的热点。本文主要介绍了朱在蛋白质多态、随机扩增多态DNA、微卫星多态性、随机扩增微卫星多态性和线粒体DNA序列多态性方面的研究结果,表明中国朱群体遗传多态性的贫乏,并据此阐述了DNA多态性保护的相关对策。     

《生物多样性》征稿简则

一、《生物多样性》是由中国科学院生物多样性委员会、中国科学院植物研究所、动物研究所、微生物研究所共同主办的生物多样性研究领域综合性学术刊物,涉及植物科学、动物科学和微生物科学在遗传多样性、物种多样性、生态系统多样性及景观多样性等多个层次上的研究,力求及时地报道生命科学各学科在生物多样性基础研究和应用研究方面具有创造性     

遗传多样性及其保存

生物多样性,包括生态系统、物种和遗传(基因)的多样性,是近年来国际社会讨论的一个热门话题。其内容涉及生物多样性的形成、现状及其评价;生物多样性消失的原因及其深远影响;生物多样性的保护和保存等。其中遗传多样性,包括微生物、植物、动物和人的遗传多样性可能是问题的核心。本文仅就动物遗传多样性研究的若干问题,结合我们的工作作一介绍。     

不同地理居群角突臂尾轮虫遗传多样性的RAPD分析

随机扩增多态DNA(Random Amplified Polymorphic DAN,RAPD)技术具有检测快速、操作简便、灵敏度高、成本低等特点, 已被广泛应用于生物遗传多样性的检测, 也曾被用于轮虫种间关系研究, 然而将RAPD 技术应用于轮虫遗传多样性和不同地理居群轮虫间的系统关系研究尚未见报道。本文以各类水体中广泛分布的、且在水产养殖上有较大应用前景的角突臂尾轮虫为对象, 运用RAPD 技术对采自广州、芜湖和青岛等地的不同地理居群轮虫进行了基因组DNA 多态性研究, 旨在从DNA 水平上探讨其遗传多样性、遗传差异及系统进化关系。       

转基因植物对农业生物多样性的影响

论述了近年来转基因植物对农业生态系统生物多样性影响的研究进展．主要在遗传多样性、物种多样性和生态系统多样性3个层次上予以评述．包括转基因植物对作物遗传多样性的影响;转基因植物的外源基因向杂草和近缘野生种转移;转基因抗虫植物对目标害虫的影响。抗除草剂转基因植物对作物和杂草的影响,抗病毒转基因植物对病毒的影响;转基因植物对非目标生物的影响,对土壤生态系统的影响等．     

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。     

藏羚Y染色体雄性特异区遗传多样性

<正>遗传多样性反映了物种应对环境变化与进化的潜力,遗传多样性越高,对环境变化的适应能力就越强(沈浩和刘登义,2001)。对于经历过人类猎杀导致种群危机的野生物种,随着短时间内大量个体的消亡,很多潜在的优良基因单倍型也会丧失,在后续种群数量恢复过程中,这些单倍型并不会随着种群个体数量的增加而迅速恢复,即遗传多样性的恢复明显滞后于种群数量的恢复(Frankham et al., 2002)。     

松属植物遗传多样性研究进展

研究松属遗传多样性的方法涉及表型、同工酶、染色体、DNA等多层面。 松树表型性状变异广泛,其不同树种不同性状的遗传力（或遗传率）均存在差异。到目前为止,同工酶仍是检测松树遗传多样性的最常用方法,一般而言,松属树种群体内等位酶多样性程度高,群体间分化较低,但各树种的情形也不尽相同。松属树种染色体水平的变异很低,其核型高度一致。核DNA组较一般阔叶树大,遗传多样性丰富,但叶绿体等质体DNA则多样性较低。影响遗传多样性的因素很多,其中自身的交配系统和外部的生长环境是影响它的两个主要因素。最后,回顾了松树的起源及其遗传多样性保护策略等方面的研究。 Abstract:The ways of probing genetic diversity of pines involve many aspects,such as morphology,chromosome,isozyme,DNA,etc.The phenotypic characteristics in pines vary widely and the differences of inheritability(h2) are obvious among characteristics and among species.Up to now,isozyme is still the most common means to measure genetic diversity of pines.Generally,there are high allozyme diversity within populations and low differentiation coefficient among populations,but differences exist between species in Pinus.The variations of chromosome among pines are very low and the karyotypes of pines are consentaneous,but the genomes of pines in cell nucleus are much larger than that of broadleaves.Diversity of pines are abundant at nucleus DNA level but are poor at plastid DNA level,such as ctDNA.There are many factors that will affect genetic diversity of pines,in which mating system and environment are two main factors.Finally,we reviewed the research on origin of Pinus and conservation strategy of genetic diversity,etc.     

植物遗传多样性及保护研究进展

根据国内外最近资料和作者的研究体会,综述目前生物多样性的概念、研究方法和研究动态,文章比较了应用形态、分类、同功酶、ＲＦＬＰ和ＲＡＰＤ方法研究栎树的最新结果,介绍了研究目标和采用方法的相互关系,分子生物学方法在生物多样性,尤其是遗传多样性研究中的应用。结合概念、方法和结果的讨论,文章最后介绍一些有关生物多样性保护方面的理论和方法以及国际国内生物多样性保护研究的发展动态。     

Biodiversity of 52 chicken populations assessed by microsatellite typing of DNA pools

In a project on the biodiversity of chickens funded by the European Commission (EC), eight laboratories collaborated to assess the genetic variation within and between 52 populations from a wide range of chicken types. Twenty-two di-nucleotide microsatellite markers were used to genotype DNA pools of 50 birds from each population. The polymorphism measures for the average, the least polymorphic population (inbred C line) and the most polymorphic population (Gallus gallus spadiceus) were, respectively, as follows: number of alleles per locus, per population: 3.5, 1.3 and 5.2; average gene diversity across markers: 0.47, 0.05 and 0.64; and proportion of polymorphic markers: 0.91, 0.25 and 1.0. These were in good agreement with the breeding history of the populations. For instance, unselected populations were found to be more polymorphic than selected breeds such as layers. Thus DNA pools are effective in the preliminary assessment of genetic variation of populations and markers. Mean genetic distance indicates the extent to which a given population shares its genetic diversity with that of the whole tested gene pool and is a useful criterion for conservation of diversity. The distribution of population-specific (private) alleles and the amount of genetic variation shared among populations supports the hypothesis that the red jungle fowl is the main progenitor of the domesticated chicken.     

Traditional home-garden conserving genetic diversity: a case study of Acacia pennata in southwest China

Conserving biodiversity in human-dominated systems requires research into mechanisms that can maintain biodiversity in fragmented landscapes. Home-garden as traditional agroforestry system in many regions has shown great value in maintaining a wide range of species. Here we show that home-garden populations are also capable of maintaining high level of genetic variation. Using six polymorphic microsatellite DNA markers, we have genotyped 260 individuals of Acacia pennata, a popular wild vegetable in the tropical region of southeast Asia. Samples were collected from home-gardens and wild populations in Xishuangbanna, southwest China. Microsatellite DNA diversity in planted populations were compared with that in geographically nearby wild populations with similar population size. Over 90?% of microsatellite genetic variation in wild populations was also present in planted populations. Pairwise comparison of planted and adjacent wild population showed no significant difference in allelic diversity and heterozygosity. Analysis revealed no significant genetic differences between wild and planted populations, while four home-garden populations showed sign of bottleneck. We conclude that home-gardens show great promise in maintaining genetic diversity, and that these managed patches could be of significant conservation value in tropical regions.     

Population genetics of a marine bivalve, Pinctada maxima, throughout the Indo-Australian Archipelago shows differentiation and decreased diversity at range limits

Intraspecific genetic diversity governs the potential of species to prevail in the face of environmental or ecological challenges; therefore, its protection is critical. The Indo-Australian Archipelago (IAA) is a significant reservoir of the world's marine biodiversity and a region of high conservation priority. Yet, despite indications that the IAA may harbour greater intraspecific variation, multiple-locus genetic diversity data are limited. We investigated microsatellite DNA variation in Pinctada maxima populations from the IAA to elucidate potential factors influencing levels of genetic diversity in the region. Results indicate that genetic diversity decreases as the geographical distance away from central Indonesia increases, and that populations located towards the centre of P. maxima 's range are more genetically diverse than those located peripherally ( P <  0.01). Significant partitioning of genetic variation was identified ( F _ST = 0.027; R _ST = 0.023, P  < 0.001) and indicates that historical biogeographical episodes or oceanographic factors have shaped present population genetic structure. We propose that the genetic diversity peak in P. maxima populations may be due to (i) an abundance of suitable habitat within the IAA, meaning larger, more temporally stable populations can be maintained and are less likely to encounter genetic bottlenecks; and/or (ii) the close proximity of biogeographical barriers around central Indonesia results in increased genetic diversity in the region because of admixture of genetically divergent populations. We encourage further genetic diversity studies of IAA marine biota to confirm whether this region has a significant role in maintaining intraspecific diversity, which will greatly assist the planning and efficacy of future conservation efforts.     

Genetic diversity is overlooked in international conservation policy implementation

The importance of genetic variation for maintaining biological diversity and evolutionary processes has been recognized by researchers for decades. This realization has prompted agreements by world leaders to conserve genetic diversity, and this is an explicit goal of the Convention on Biological Diversity (CBD). Nevertheless, very limited action has been taken to protect genetic diversity on a global scale. International conservation efforts to halt biodiversity loss focus on habitats and species, whereas little or no attention is paid to gene level variation. By this year, 2010, world leaders have agreed that a significant reduction of the rate of biodiversity loss should have been achieved. However, gene level diversity is still not monitored, indicators that can help identify threats to genetic variation are missing, and there is no strategy for how genetic aspects can be included in biodiversity targets beyond 2010. Important findings and conclusions from decades of conservation genetic research are not translated into concrete conservation action in the arena of international policy development. There is an urgent need for conservation geneticists worldwide to become involved in policy and practical conservation work beyond the universities and research institutions.     

Allozyme and RAPD analysis of the genetic diversity and geographic variation in wild populations of the American chestnut (Fagaceae)

Genetic variation among 12 populations of the American chestnut (Castanea dentata) was investigated. Population genetic parameters estimated from allozyme variation suggest that C. dentata at both the population and species level has narrow genetic diversity as compared to other species in the genus. Average expected heterozygosity was relatively low for the population collected in the Black Rock Mountain State Park, Georgia (He = 0.096 +/- 0.035), and high for the population in east central Alabama (He = 0.196 +/- 0.048). Partitioning of the genetic diversity based on 18 isozyme loci showed that ~10% of the allozyme diversity resided among populations. Cluster analysis using unweighted pair-group method using arithmetric averages of Rogers' genetic distance and principal components analysis based on allele frequencies of both isozyme and RAPD loci revealed four groups: the southernmost population, south-central Appalachian populations, north-central Appalachian populations, and northern Appalachian populations. Based on results presented in this study, a conservation strategy and several recommendations related to the backcross breeding aimed at restoring C. dentata are discussed.     

Genetic diversity of an Italian Rhizobium meliloti population from different Medicago sativa varieties.

We investigated the genetic diversity of 96 Rhizobium meliloti strains isolated from nodules of four Medicago sativa varieties from distinct geographic areas and planted in two different northern Italian soils. The 96 isolates, which were phenotypically indistinguishable, were analyzed for DNA polymorphism with the following three methods: (i) a randomly amplified polymorphic DNA (RAPD) method, (ii) a restriction fragment length polymorphism (RFLP) analysis of the 16S-23S ribosomal operon spacer region, and (iii) an RFLP analysis of a 25-kb region of the pSym plasmid containing nod genes. Although the bacteria which were studied constituted a unique genetic population, a considerable level of genetic diversity was found. The new analysis of molecular variance (AMOVA) method was used to estimate the variance among the RAPD patterns. The results indicated that there was significant genetic diversity among strains nodulating different varieties. The AMOVA method was confirmed to be a useful tool for investigating the genetic variation in an intraspecific population. Moreover, the data obtained with the two RFLP methods were consistent with the RAPD results. The genetic diversity of the population was found to reside on the whole bacterial genome, as suggested by the RAPD analysis results, and seemed to be distributed on both the chromosome and plasmid pSym.