马鹿线粒体DNA研究新进展

线粒体DNA作为理想的分子遗传标记被广泛应用于马鹿进化生物学、种群遗传学和保护生物学的研究.该文阐述了mtDNA在马鹿中的研究进展,重点介绍马鹿mtDNA序列的研究概况及其多态性在马鹿物种识别、起源和进化、地理分化、遗传多样性和保护管理等方面的应用情况.     

大鸨的现状和研究动态

大鸨(Otistarda)是栖息于广阔草原的重要濒危鸟类,属国家Ⅰ级保护动物。本文根据近年国内外对该物种的研究结果,对其亚种分布、种群数量、生态生物学、种群遗传结构及组织形态学观察等方面作了综述。通过对其生存现状、受胁原因、研究动态的论述,为该物种的保护和管理提供科学的依据。     

七鳃鳗遗传多样性与演化研究进展

七鳃鳗(Petromyzonidae)是目前已知最古老的脊椎动物中惟一的幸存者.对其资源保护和演化发育生物学的研究正日益受到重视.本文从染色体、蛋白质和DNA水平总结近年来七鳃鳗遗传多样性与演化方面的研究进展.重点介绍了限制性酶切片段长度多态性、DNA随机扩增多态性、DNA扩增片段长度多态性、微卫星DNA标记等技术及线粒体DNA和功能基因研究应用于七鳃鳗种群遗传多样性、遗传分化、遗传结构、种质鉴定与渔业资源管理及系统进化等方面的新进展.     

利用非损伤性方法评估神农架保护区川金丝猴种群遗传多样性

湖北神农架国家级自然保护区是中国川金丝猴(Rhinopithecus roxellana)的重要分布区之一,为了更好地了解神农架川金丝猴种群遗传结构,并制定有效的保护对策,采集了该保护区2个川金丝猴种群126份样品,其中分布在大龙潭的人工补食种群粪便样品60份,分布在千家坪的一个小种群粪便样品63份、肌肉样品3份。通过应用线粒体DNA(mtDNA)引物和筛选出的9对近缘微卫星位点成功地进行了川金丝猴种群的遗传多样性和遗传结构分析,同时使用Y染色体相关标记方法进行性别鉴定。结果显示:在24份川金丝猴mtDNA D-loop区401bp序列中,共检测出27个变异位点,定义了20个单倍型,单倍型多样性(h)为0.9820,核苷酸多样性(π)为0.0129;其中有9对微卫星位点能够在117份粪便样品DNA中稳定扩增,2对位点可能偏离Hardy-Weinberg平衡,平均有效等位基因数(Ne)为3.85,遗传杂合度(Ho)为0.7450;多态信息含量(PIC)为0.5950。使用Y染色体标记方法,在58个特有的基因型中检测到18个雄性和40个雌性川金丝猴。微卫星标记和mtDNA D-loop区基因序列均表明神农架川金丝猴存在较丰富的遗传多样性,同时2个取样点川金丝猴种群间出现了明显的遗传分化。     

不仅仅是遗传多样性:植物保护遗传学进展

保护遗传学研究的是影响物种灭绝的遗传因素以及濒危物种的遗传管理, 以降低物种的灭绝风险。本文从遗传多样性本身及其对生态系统的影响两个方面介绍了植物保护遗传学的最新进展。根据遗传标记的功能, 保护遗传学研究可分为选择中性遗传变异研究和适应性遗传变异两个方面。对于目前主要采用的选择中性遗传标记研究, 本文着重介绍了以下方面的最新进展: (1)利用遗传标记进行个体、物种或遗传单元的鉴定, 从而有效地设计保护策略, 避免在迁地保护中混淆物种, 提高保护效率; (2)应重视由于物种自身生殖、扩散等原因造成的隐性瓶颈效应。由于选择中性遗传标记并不能准确反映物种的适应性遗传基础, 从适应性遗传变异角度研究濒危物种的进化潜力已成为保护遗传学的研究前沿。大部分相关研究还集中在利用基因组扫描检测受选择的位点, 而对功能基因的适应性研究还比较少。景观遗传学旨在解释景观和生境影响下的种群间基因流和遗传多样性格局, 这方面研究将会促进我们更多了解种群基因流的地理限制因子和不同景观基质下的种群遗传差异。遗传多样性作为物种的一种属性亦可在一定程度上反馈, 并影响生态系统。这提示我们不仅仅是濒危物种, 常见物种的遗传多样性及其保护亦很重要。最后, 我们从4个方面对保护遗传学研究进行了展望, 包括应加强将生态系统各环节联系起来研究遗传多样性, 在技术手段上利用多态性更丰富的分子标记, 同时强调了对常见物种保护遗传学研究的重要性, 并初步分析了我国保护遗传学研究与国际水平的差距, 建议加强种群遗传学和进化生物学基础理论的学习。     

扬子鳄的保护遗传学研究进展

保护遗传学是主要研究与灭绝风险相关的遗传因素以及如何利用遗传学管理方法降低物种灭绝风险的科学,是保护生物学和分子遗传学的交叉学科.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.本文回顾了AFLP、mtDNA D-loop、RAPD、微卫星DNA、MHC等DNA分子标记技术在扬子鳄的样品采集、生物多样性、个体鉴定、繁殖管理、野外放归等保护遗传学方面研究所取得的一些进展.对扬子鳄保护的工作提出了建议:重建扬子鳄的谱系;加大对扬子鳄的放归力度;加强饲养种群之间的基因交流;借鉴密河鳄的管理经验.     

都柳江鲤、鲫和草鱼种群mtDNA控制区及遗传多样性分析

采用PCR和DNA测序技术对贵州都柳江鲤(Cyprinus carpio)、鲫(Carassius auratus)和草鱼(Ctenopharyngodon idellus)种群的mtDNA控制区序列及遗传多样性进行了研究。获得了都柳江鲤、鲫和草鱼mtDNA控制区长度分别为899~901 bp、787 bp和901~905 bp的序列。该3种鱼类控制区碱基A、T含量较高,G含量最低。识别了该3种鱼类mtDNA控制区终止序列区、中央保守区和保守序列区等保守序列。其中,除CSB-2和CSB-3碱基组成相同外,其余核心序列碱基组成存在着差异。都柳江鲤、鲫和草鱼种群mtDNA控制区分别有24、24和11个多态位点,分属12、17和8个单倍型。都柳江鲤、鲫种群遗传多样性较高,草鱼种群遗传多样性较低。因此,有必要开展都柳江草鱼种群遗传多样性的保护。     

峨眉山藏酋猴mtDNA控制区序列变异及种群遗传多样性

为更有效地保护藏酋猴Macaca thibetana野生种群,本文测定了来自峨眉山藏酋猴8个亚群体的47个样品mtDNA控制区5'端505 bp的序列,发现了27个变异位点(5.74%),定义了4种单倍型,其单倍型多样性(h)为0.236±0.079、核苷酸多样性(π)为0.00902±0.00354,单倍型之间的序列差异平均为0.623%,平均核苷酸差异(K)为4.274,单倍型序列之间变异较大,种群中的核苷酸多样性较高;将峨眉山的藏酋猴看成一个种群与同为四川地区的马边群体及安徽的黄山群体的相应序列进行比较,结果显示峨眉山藏酋猴种群mtDNA控制区序列与马边群体间的差异性较小,而与黄山群体间的差异性较大。分子方差分析(AMOVA)表明,90.04%的遗传变异发生在种群之间,仅有9.96%的变异发生在种群内。进一步分析表明,藏酋猴各地理种群间均不同程度地存在着一定的遗传分化(Fst=0.9004,P<0.05),种群间基因交流较贫乏(Nm<1)。基于最大似然法和邻接法构建的系统发生树均支持四川地区的藏酋猴种群和安徽黄山种群分别聚为不同的类群,支持将它们归入各自的管理单元;而本研究中的四川地区藏酋猴在系统发生树上也分为2个亚支,但这2个亚支并未与地理分布成完全的对应关系,应归为一个管理单元加以保护。     

微卫星标记在种群生物学研究中的应用

微卫星是以几个碱基 (一般为 1～ 6个 )为重复单位组成的简单的串联重复序列 ,具有丰度高、多态性高、共显性标记、选择中性、可自动检测等优点。本文着重介绍了微卫星在种群生物学研究中的应用。微卫星位点可以提供具高分辨率的遗传信息 ,这一特点使微卫星既适合于个体水平上的研究 ,又适合于种群水平上的研究。在个体水平上包括个体识别、交配系统和亲本分析、基因流等研究。微卫星是常用的个体识别手段 ,但在克隆植物遗传结构研究方面的应用还很有限 ;微卫星提高了交配系统和亲本分析、基因流等研究的准确性。在种群水平上微卫星可用于遗传结构、有效种群大小、种群的系统发育重建等研究。微卫星在很多物种 (包括珍稀物种 )的遗传结构研究中得到应用 ;利用微卫星标记确定有效种群大小、检测有效种群大小的波动可以促使我们正确理解种群遗传结构动态和种群进化过程 ;微卫星在种群的系统发育重建研究方面有很大的应用潜力。然而微卫星并不是研究所有问题的唯一选择。文中还讨论了在实际工作中应如何正确利用分子标记等问题     

黄山短尾猴mtDNA控制区序列变异及种群的遗传多样性

短尾猴属灵长目(Primates)猴科(Cercopithecidae)猕猴属(Macaca),是我国特有的国家二级保护动物。为了更有效地保护其野生种群,本文研究了黄山短尾猴种群内的遗传多样性,并对黄山短尾猴与四川短尾猴种群间的遗传差异进行了分析。共测定了黄山短尾猴7个群体中的30个样本的mtDNA控制区5′端493bp的序列,只发现了7个变异位点,定义了3种单倍型,单倍型序列之间缺乏变异,种群中的核苷酸多样性很低(0.006);3种单倍型相应地将黄山种群分为了3个亚群,不同亚群之间呈现出一定的片断化分布,从分子水平上初步揭示了短尾猴黄山种群的遗传多样性。与四川短尾猴的相应序列比较,黄山短尾猴控制区序列存在很大差异,共有59个变异位点,而且存在大片段的碱基插入/缺失,有78%的遗传变异发生在两个种群之间,两个种群间的核苷酸歧异度已达8.21%。进一步分析表明,黄山短尾猴与四川短尾猴之间存在着极显著的遗传分化(FST=0.399,P<0.001),基于最大似然法和邻接法构建的系统发生树均将两者聚为不同的类群,支持将它们归入各自的管理单元。     

Conservation units based on mitochondrial and nuclear DNA variation among European bullhead populations (Cottus gobio L., 1758) from Flanders, Belgium

In this study, we aimed to delineateevolutionarily significant units (ESUs) andmanagement units (MUs) for the Europeanbullhead in Flanders (Belgium). Therefore, wedetermined the genetic interrelationshipsbetween 11 bullhead populations, using lengthvariation at 7 polymorphic microsatellite lociand sequence variation in the d-loop of themitochondrial DNA (mtDNA). Despite therelatively small geographical scale of ourstudy, the analysis of the d-loop sequencesshows that the Flemish bullhead populationscontain 3 haplotype groups, which can beassigned to 3 previously described EuropeanmtDNA clades. Because of the importantdifferences between these clades, they may bedefined as evolutionarily significant units,which should be managed separately. Analysis ofmicrosatellite data reveals very high degreesof isolation between populations, with theexception of 3 pairwise comparisons whichinvolved adjacent populations. Our data suggestthat the 3 haplotype groups probably qualify asESUs, as they show phylogeographicdifferentiation for mtDNA variants as well assignificant divergence of allele frequencies atnuclear loci. However, one of these units,limited to a single population, may be ofCentral European origin. All populations of theScheldt basin meet the criteria for MUrecognition, since significantly differentmicrosatellite allele frequencies as well asprivate alleles are found. In contrast, geneticdifferentiation among the 3 populations of theMeuse basin is very low.     

Inferring Pongo conservation units: a perspective based on microsatellite and mitochondrial DNA analyses

In order to define evolutionarily significant and management units (ESUs and MUs) among subpopulations of Sumatran (Pongo pygmaeus abelii) and Bornean (P. p. pygmaeus) orangutans we determined their genetic relationships. We analyzed partial sequences of four mitochondrial genes and nine autosomal microsatellite loci of 70 orangutans to test two hypotheses regarding the population structure within Borneo and the genetic distinction between Bornean and Sumatran orangutans. Our data show Bornean orangutans consist of two genetic clusters—the western and eastern clades. Each taxon exhibits relatively distinct mtDNA and nuclear genetic distributions that are likely attributable to genetic drift. These groups, however, do not warrant designations as separate conservation MUs because they demonstrate no demographic independence and only moderate genetic differentiation. Our findings also indicate relatively high levels of overall genetic diversity within Borneo, suggesting that observed habitat fragmentation and erosion during the last three decades had limited influence on genetic variability. Because the mtDNA of Bornean and Sumatran orangutans are not strictly reciprocally monophyletic, we recommend treating these populations as separate MUs and discontinuing inter-island translocation of animals unless absolutely necessary.     

Delimitation of evolutionary units in Cuvier’s dwarf caiman, <Emphasis Type="Italic">Paleosuchus palpebrosus</Emphasis> (Cuvier, 1807): insights from conservation of a broadly distributed species

An important goal of evolutionary and conservation biology is the identification of units below the species level, such as Evolutionarily Significant Units (ESUs), providing objectively delimited units for species conservation and management. In this study we tested the hypothesis that Cuvier’s dwarf caiman (Paleosuchus palpebrosus)—a species broadly distributed across several biomes and watersheds of South America—is comprised of different ESUs. We analyzed mitochondrial cytochrome b sequences of 206 individuals and 532 unlinked ddRAD loci of 20 individuals chosen from amongst the mitochondrial haplogroups. Analysis of the cytochrome b sequences revealed four mitochondrial clusters, while STRUCTURE analysis of ddRAD loci detected three genomic clusters with different levels of mixture between them. Using the Adaptive Evolutionary Conservation (AEC) framework we identified three ESUs: “Amazon”, “Madeira-Bolivia” and “Pantanal”; one of them composed of two different Management Units (MUs), “Madeira” and “Bolivia”. In general, based on the comparisons with other crocodilian species, genetic diversity of each lineage was moderate however, the Madeira MU showed fivefold lower genetic diversity than other geographic groups. Considering the particularities of each Paleosuchus palpebrosus conservation unit, we recommend that the conservation status of each is evaluated separately. Tropical biodiversity is largely underestimated and in this context the broadly distributed species are the most likely candidates to harbor distinct evolutionary lineages. Thus, we suggest that conservation research should not neglect species that are generally considered of Least Concern by IUCN due to the taxon’s broad geographic distribution.     

Conservation genetics of highly isolated populations of the xerothermic beetle Crioceris quatuordecimpunctata (Chrysomelidae)

Xerothermic species are rare and threatened in central and eastern Europe. In light of the continuing loss of steppe‐like habitats due to anthropogenic fragmentation and degradation, the evaluation of genetic variation in populations inhabiting them is of immediate importance if appropriate conservation measures are to be undertaken. Here we report on the genetic diversity of the rare leaf beetle Crioceris quatuordecimpunctata, whose populations in central and eastern Europe inhabit highly geographically isolated areas. All of the studied populations (in Poland, Ukraine, and Slovakia) were differentiated at the mitochondrial marker COI. However, with respect to the nuclear marker ITS1, Polish populations were monomorphic, but distinct from all other populations. The distinctiveness of the studied populations was confirmed by Wolbachia screening, which showed that all populations carried different strains (one or two), which were probably transferred independently from other insects. On the other hand, no diversity was found in any marker within particular populations, which could be caused (at least for mtDNA) by a Wolbachia selective sweep. Crioceris quatuordecimpunctata probably consists of isolated populations, which went through narrow bottlenecks leading to a drastic reduction in their genetic diversity. As these populations are reciprocally monophyletic for mtDNA haplotypes and show a significant divergence of allele frequencies at nuclear loci, they could be classified as evolutionarily significant units (ESUs). In addition, DNA barcodes were used to identify Asparagus officinalis as the host plant for members of all studied populations. These data should be valuable in efforts to conserve populations of C. quatuordecimpunctata (e.g., for guiding reintroductions).     

Applications of mitochondrial DNA analysis in conservation: a critical review

Patterns of variation in mitochondrial DNA (mtDNA) increasingly are being investigated in threatened or managed species, but not always with clearly defined goals for conservation. In this review I identify uses of mtDNA analysis which fall into two different areas: (i) 'gene conservation' - the identification and management of genetic diversity, and (ii) 'molecular ecology' - the use of mtDNA variation to guide and assist demographic studies of populations. These two classes of application have different conceptual bases, conservation goals and time-frames. Gene conservation makes extensive use of phylogenetic information and is, in general, most relevant to long-term planning. Appropriate uses here include identification of Evolutionarily Significant Units and assessment of conservation priority of taxa or areas from an evolutionary perspective. Less appropriate are inferences about fitness from within-population diversity and about species boundaries. Molecular ecology makes more use of allele frequencies and provides information useful for short-term management of populations. Powerful applications are to identify Management Units and to define and use naturally occurring genetic tags. Estimating demographic parameters, e.g migration rate and population size, from patterns of mtDNA diversity is fraught with difficulty, particularly where populations are fluctuating, and is unlikely to produce quantitative estimates sufficiently accurate to be useful for practical management of contemporary populations. However, through comparative studies, mtDNA analysis can provide qualitative signals of population changes, allowing efficient targeting of resource-intensive ecological studies. Thus, there are some relatively straightforward uses of mtDNA, preferably in conjunction with assays of nuclear variation, that can make a significant contribution to the long-term planning and short-term execution of species recovery plans.     

Phylogeographical population structure of tiger quolls Dasyurus maculatus (Dasyuridae: Marsupialia), an endangered carnivorous marsupial

Tiger quolls, Dasyurus maculatus, are the largest carnivorous marsupials still extant on the mainland of Australia, and occupy an important ecological niche as top predators and scavengers. Two allopatric subspecies are recognized, D.m. gracilis in north Queensland, and D.m. maculatus in the southeast of the mainland and Tasmania. D.m. gracilis is considered endangered while D.m. maculatus is listed as vulnerable to extinction; both subspecies are still in decline. Phylogeographical subdivision was examined to determine evolutionarily significant units (ESUs) and management units (MUs) among populations of tiger quolls to assist in the conservation of these taxa. Ninety-three tiger quolls from nine representative populations were sampled from throughout the species range. Six nuclear microsatellite loci and the mitochondrial DNA (mtDNA) control region (471 bp) were used to examine ESUs and MUs in this species. We demonstrated that Tasmanian tiger quolls are reciprocally monophyletic to those from the mainland using mtDNA analysis, but D.m. gracilis was not monophyletic with respect to mainland D.m. maculatus. Analysis of microsatellite loci also revealed significant differences between the Tasmanian and mainland tiger quolls, and between D.m. gracilis and mainland D.m. maculatus. These results indicate that Tasmanian and mainland tiger quolls form two distinct evolutionary units but that D.m. gracilis and mainland D.m. maculatus are different MUs within the same ESU. The two marker types used in this study revealed different male and female dispersal patterns and indicate that the most appropriate units for short-term management are local populations. A revised classification and management plan are needed for tiger quolls, particularly in relation to conservation of the Tasmanian and Queensland populations.     

Phylogeographic evidence links the threatened ‘Grampians’ Mountain Dragon (Rankinia diemensis Grampians) with Tasmanian populations: conservation implications in south-eastern Australia

The importance of protecting genetic diversity within a species is increasingly being recognised by conservation management authorities. However, discrepancies in conservation policy between authorities, such as state versus national bodies, can have significant implications for species management when they cross state boundaries. We conducted a phylogeographic study of the south-eastern Australian lizard Rankinia diemensis to identify evolutionary significant units (ESUs), including the endangered population from the Grampians National Park in western Victoria. Phylogenetic analyses of two gene regions (mtDNA: ND2; nuclear: RAG1) revealed high levels of genetic divergence between populations, indicating isolation over long evolutionary time frames. Based on criteria of genetic divergence and isolation, R. diemensis contains at least two ESUs that require specific management. We found that R. diemensis from the Grampians are closely related to Tasmanian populations, but that the divergence between these regions is great enough (3.7 % mtDNA) that they should be considered separate ESUs. However, we believe the close evolutionary ties between these two regions needs to be taken into account; yet under current practises, conservation management of subspecific ESUs relies on state-level efforts. We argue that another population that occurs on the Victorian coast also qualifies as an ESU and requires targeted conservation action. Rankinia diemensis provides a case-in-point of the discrepancy between the state-level approach of maintaining genetic variation within a species and the more conservative Commonwealth focus on conserving biodiversity at the species level.     

Population Genetic Patterns of Threatened European Mudminnow (Umbra krameri Walbaum, 1792) in a Fragmented Landscape: Implications for Conservation Management

The European mudminnow (Umbra krameri) is a Middle Danubian endemic fish species, which is characterised by isolated populations living mainly in artificial habitats in the centre of its range, in the Carpathian Basin. For their long term preservation, reliable information is needed about the structure of stocks and the level of isolation. The recent distribution pattern, and the population genetic structure within and among regions were investigated to designate the Evolutionary Significant, Conservation and Management Units (ESUs, CUs, MUs) and to explore the conservation biological value of the shrinking populations. In total, eight microsatellite loci were studied in 404 specimens originating from eight regions. The results revealed a pronounced population structure, where strictly limited gene flow was detected among regions, as well as various strengths of connections within regions. Following the results of hierarchical structure analyses, two ESUs were supposed in the Carpathian Basin, corresponding to the Danube and Tisza catchments. Our results recommend designating the borders of CUs in an 80–90km range and 16 clusters should be set up as MUs for the 33 investigated populations. How these genetic findings can be used to better allocate conservation resources for the long term maintenance of the metapopulation structure of this threathened endemic fish is discussed.     

Phylogeographic structure in the threatened Yarra pygmy perch <Emphasis Type="Italic">Nannoperca obscura</Emphasis> (Teleostei: Percichthyidae) has major implications for declining populations

Molecular genetic information should be a pre-requisite when evaluating conservation priorities in highly structured species such as freshwater fishes. Nuclear (allozyme) and mitochondrial (cytochrome b) markers were used to investigate phylogeographic structure in the Yarra pygmy perch Nannoperca obscura (Klunzinger), a threatened freshwater fish endemic to mainland south-eastern Australia. Complementary patterns of strong, geographically defined sub-structure were observed including a major east–west divergence (at the Glenelg River), four diagnosable lineages, and statistically-significant differences between most populations. Accordingly, four Evolutionarily Significant Units (ESUs) are defined and multiple, drainage-scale Management Units (MUs) suggested. Since Nannoperca obscura is a relatively poor disperser with no apparent gene flow between most populations, any regional extirpation would see the irreversible loss of genetic diversity. This is problematic, as several populations, most notably a recently discovered ESU in the Murray-Darling Basin, are feared extirpated through a combination of anthropogenic threats and severe drought. The potential loss of unique evolutionarily components within N. obscura soon after their discovery highlights with some urgency, the need to define and protect conservation units in highly modified freshwater habitats.     

Identifying evolutionarily significant units for conservation of the endangered Malus sieversii using genome‐wide RADseq data

Malus sieversii, a wild progenitor of the domesticated apple, is an endangered species and is assigned second conservation priority by the China Plant Red Data Book. It is urgent to carry out in situ conservation of this species, but previous studies have not identified evolutionarily significant units (ESUs) for conservation management. In this study, we investigated the genetic diversity and relationships of six M. sieversii populations from China using integrated analysis of microsatellite (nSSR) data, genome‐wide SNPs and previous results in order to propose a reasonable conservation management. The results showed that levels of genetic diversity were inconsistently reflected by our nSSR and previous studies, suggesting that indices of genetic diversity are not effective to identify priority conservation areas for M. sieversii. Based on the selection criteria of ESUs for endangered species conservation, ESUs should reflect lineage divergence, geographical separation and different adaptive variation. Our phylogenetic tree based on genome‐wide SNPs yielded a clear relationship of divergent lineages among M. sieversii populations, leading to new different from those of previous studies. Three independent lineages, including the pairs of populations Huocheng‐Yining, Gongliu‐Xinyuan and Tuoli‐Emin, were identified. The geographic distances between populations among the different phylogenetic lineages were much greater than those within the same phylogenetic lineage. A cluster analysis on environmental variables showed that the three independent lineages inhabit different environmental conditions, suggesting that they may have adapted to different environments. Based on the results, we propose that three independent ESUs should be recognized as conservation units for M. sieversii in China.