鱼类线粒体DNA及其在分子群体遗传研究中的应用

鱼类是脊椎动物亚门中种属数量最多的类群,分布广泛,起源复杂,拥有丰富的遗传多样性.多种自然和人为因素对鱼类遗传资源存在不同程度的作用,对鱼类生存和进化有重要影响.采用分子手段探讨鱼类遗传资源现状,可为遗传育种、鱼类进化研究和遗传资源保护等提供一定科学依据.以鱼类线粒体DNA(mtDNA)为代表的分子标记技术已被用于研究鱼类群体遗传结构及其与影响因素间的关系.本文综述了鱼类mtDNA的结构特征及其在鱼类分子群体遗传研究中的应用,对了解和运用mtDNA等分子标记研究鱼类群体遗传具有一定参考价值.     

蚕类昆虫线粒体DNA研究及其在起源与进化研究中的应用

线粒体DNA(mtDNA)属母系遗传,进化速率较核基因快且基因组结构相对简单,已作为理想的分子标记广泛应用于昆虫群体遗传学及分子系统学等研究。本文对蚕类昆虫线粒体DNA在分子水平上的最新研究进展进行了较详细的阐述,重点介绍了蚕类昆虫线粒体基因组的组成及特征、mtDNA克隆与多态性及在蚕类昆虫分子系统学研究中的应用等。     

鱼类线粒体DNA研究新进展

线粒体DNA是分子生物学研究中的一个热门领域,已成为鱼类进化生物学和群体遗传学研究的重要分子遗传标记。本文对鱼类线粒体DNA分子生物学的最新研究进展进行了较详细的阐述。重点介绍鱼类线粒体DNA全序列的研究进展、组成及特征,鱼类线粒体DNA非编码区结构研究进展,鱼类线粒体DNA多态性及其主要的检测方法;综述了最近有关鱼类线粒体DNA在鱼类系统学、种间杂交渐渗、种群识别、起源和进化、地理分化等研究中的应用情况。     

线粒体基因在鳞翅目昆虫分子系统学中的研究进展

介绍近年来已测定线粒体DNA全序列的鳞翅目昆虫和其线粒体DNA结构,综述鳞翅目昆虫的分子系统学研究进展.特别对mtDNA在鳞翅目昆虫分类和界定、系统发育关系及种群遗传变异和进化等研究中的意义和存在的问题进行探讨.     

线粒体DNA序列特点与昆虫系统学研究

昆虫线粒体DNA是昆虫分子系统学研究中应用最为广泛的遗传物质之一。线粒体DNA具有进化速率较核DNA快 ,遗传过程不发生基因重组、倒位、易位等突变 ,并且遵守严格的母系遗传方式等特点。本文概述了mtDNA中的rRNA、tRNA、蛋白编码基因和非编码区的一般属性 ,分析了它们在昆虫分子系统学研究中的应用价值 ,以及应用DNA序列数据来推导分类阶 (单 )元的系统发育关系时 ,基因或DNA片段选择的重要性     

脊椎动物线粒体DNA的进化遗传学

近年来,在分子进化遗传学研究中又产生出一个新的生长点,这就是线粒体DNA(mtDNA)的进化遗传学研究。因为mtDNA结构简单,与拥有4×10~8到4×10~(11)个碱基对的多细胞动物的核基因组相比,比其最小者小25000倍;在不同物种间,mtDNA上的基因成分相对稳定,很少受到序列重排的影响;另一方面,mtDNA又具有广泛的种内和种间多态性,且为母性遗传,在亲缘关系相近的物种间其进化速度比核基因快,因而它为从分子水平上研究种群遗传学和进化遗传学提供了理想的研究对象。     

植物分子群体遗传学研究动态

分子群体遗传学是当代进化生物学研究的支柱学科, 也是遗传育种和关于遗传关联作图和连锁分析的基础理论学科。分子群体遗传学是在经典群体遗传的基础上发展起来的, 它利用大分子主要是DNA序列的变异式样来研究群体的遗传结构及引起群体遗传变化的因素与群体遗传结构的关系, 从而使得遗传学家能够从数量上精确地推知群体的进化演变, 不仅克服了经典的群体遗传学通常只能研究群体遗传结构短期变化的局限性, 而且可检验以往关于长期进化或遗传系统稳定性推论的可靠程度。同时, 对群体中分子序列变异式样的研究也使人们开始重新审视达尔文的以“自然选择”为核心的进化学说。到目前为止, 分子群体遗传学已经取得长足的发展, 阐明了许多重要的科学问题, 如一些重要农作物的DNA多态性式样、连锁不平衡水平及其影响因素、种群的变迁历史、基因进化的遗传学动力等, 更为重要的是, 在分子群体遗传学基础上建立起来的新兴的学科如分子系统地理学等也得到了迅速的发展。文中综述了植物分子群体遗传研究的内容及最新成果。     

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.     

两种获取鱼类线粒体DNA的方法比较

直接从鱼类组织提取线粒体DNA和先提取基因组DNA再用相应引物PCR扩增所需mtDNA某一区域序列片段是获取鱼类mtDNA切实可行的两种方法。对这两种方法在使用过程中的注意事项、各自的优缺点及应用范围进行了较为细致的比较,为更好地利用mtDNA这一重要分子标记研究鱼类mtDNA的遗传多态提供参考。     

线粒体DNA多态性在海洋动物群体遗传结构研究中的应用

线粒体DNA( mtDNA)分析在揭示物种亲缘关系、遗传比较、系统进化和遗传结构等领域的研究中得到了广泛的应用,尤其是在海洋动物的遗传结构研究中发挥了重要的作用.介绍线粒体DNA的结构特征、多态性研究方法,并对其在海洋动物群体遗传结构研究中的应用进行了综述.     

Incongruent estimates of population differentiation among brook charr, Salvelinus fontinalis, from Cape Race, Newfoundland, Canada, based upon allozyme and mitochondrial DNA variation

We determined the amount and temporal stability of genetic differentiation among brook cham sampled from five rivers on Cape Race, Newfoundland, with an electrophoretic analysis of 42 protein coding loci. Fish from four of these rivers were analysed for restriction fragment length polymorphisms in mitochondrial DNA (mtDNA). A single mtDNA clone was observed in all rivers sampled, except one, where 47% offish were from a different and relatively divergent clone (0.31 % sequence divergence). In contrast, Cape Race brook charr show large amounts of genetic differentiation at six enzyme coding loci; Nei's genetic distance ranged between 0,020 and 0.048. This differentiation is relatively stable as no significant differences in allele frequencies were detected between fish sampled from two rivers over two consecutive years. The most divergent population based on protein polymorphism is not that with two mtDNA clonal lineages. In contrast to the commonly held view, mtDNA analyses do not necessarily provide greater resolution of population structure than allozyme analyses.     

鸟类线粒体DNA结构特点及在鸟类研究中的应用

介绍了鸟类mtDNA的结构和鸟类mtDNA作为分子标记的特点,并综述了mtDNA作为分子标记在鸟类的种间系统发生关系及分类、鸟类分子钟、地理分布区的推断和种群遗传多样性的研究中应用现状.     

线粒体控制区在鱼类种内遗传分化中的意义

线粒体DNA（mtDNA）作为分子标记已被广泛应用于各物种系统发生的研究。mtDNA控制区序列（D-Loop）以其较高的突变积累对于研究物种种内的遗传分化具有重要价值。鱼类是脊椎动物中最原始但在种属数量上又最占优势的类群,其物种繁多,分布广泛,起源复杂,研究其系统发生历来是令人饶有兴趣的课题。D-Loop在研究鱼类种内遗传分化中具有多方面的重要意义。近年来,已有越来越多的研究工作将D-Loop作为分子标记来探讨各种鱼类的种内遗传分化,并且获得了许多有启发性的结果。青海湖是我国内陆最大的咸水湖,湖中主要鱼类为青海湖裸鲤（Gymnocypris przewalskii）,D-Loop分析初步结果显示青海湖及其周围河流中的裸鲤似乎没有新的种内遗传分化现象。      

The structure of human mitochondrial DNA variation

Summary Restriction analysis of mitochondrial DNA (mtDNA) of 3065 humans from 62 geographic samples identified 149 haplotypes and 81 polymorphic sites. These data were used to test several aspects of the evolutionary past of the human species. A dendrogram depicting the genetic relatedness of all haplotypes shows that the native African populations have the greatest diversity and, consistent with evidence from a variety of sources, suggests an African origin for our species. The data also indicate that two individuals drawn, at random from the entire sample will differ at approximately 0.4% of their mtDNA nucleotide sites, which is somewhat higher than previous estimates. Human mtDNA also exhibits more interpopulation heterogeneity (G_ST=0.351±0.025) than does nuclear DNA (G_ST=0.12). Moreover, the virtual absence of intermediate levels of linkage disequilibrium between pairs of sites is consistent with the absence of genetic recombination and places constraints on the rate of mutation. Tests of the selective neutrality of mtDNA variation, including the Ewens-Watterson and Tajima tests, indicate a departure in the direction consistent with purifying selection, but this departure is more likely due to the rapid growth of the human population and the geographic heterogeneity of the variation. The lack of a good fit to neutrality poses problems for the estimation of times of coalescence from human mtDNA data.     

分子标记在猕猴遗传多样性研究中的应用

分子标记目前已成为研究遗传多样性的主要工具,为此,简要综述了几种常用的分子标记(RFLPs、RAPD、mtDNA、微卫星DNA、SNPs)的检测方法及其在猕猴种群遗传多样性研究中的应用,为国内猕猴遗传多样性的研究提供参考。     

The evolutionary mechanism maintaining shell shape and molecular differentiation between two ecotypes of the dogwhelk Nucella lapillus

Two ecotypes of Nucella lapillus can occur allopatrically or sympatrically, according to different degrees of wave exposure and microhabitats, on rocky shores of NW Spain. We studied differences in shell size and shape in adults and families of shelled embryos captured in the wild, and molecular variation at 9 microsatellite loci and 4 mtDNA regions. Both adults and shelled embryos of the two ecotypes showed significant differences in size and shell-shape components (the most important being size of the shell aperture). Strong among-family variation suggests that shell-shape variation has an important genetic component, and the pattern of genetic differentiation was in agreement with traits being affected by divergent natural selection. No significant overall molecular differentiation was observed between the two ecotypes for mtDNA, although we found significant genetic structure at two microsatellite loci. Microsatellite differentiation between ecotypes at these two loci was larger in sympatry than in allopatry. These results and the comparison of tenacity suggest that the two forms are distinctly adapted to differences in shore level and degree of exposure to wave action.     

Hierarchical analyses of genetic variation of samples from breeding and feeding grounds confirm the genetic partitioning of northwest Atlantic and South Atlantic populations of swordfish (Xiphias gladius L.)

In species with high migratory potential, the genetic signal revealing population differentiation is often obscured by population admixture. To our knowledge, the explicit comparison of genetic samples from known spawning and feeding areas has not been conducted for any highly migratory pelagic fish species. This study examines the geographic heterogeneity of swordfish mitochondrial DNA (mtDNA) lineages within the Atlantic Ocean using 330 base pairs of sequence of the control region from 480 individuals. Hierarchical analyses of sequence variation were conducted to test whether samples from areas identified as the corresponding spawning and feeding grounds for the northwest (NW) Atlantic (Caribbean and Georges Banks-US northeast) and the South Atlantic (Brazil-Uruguay and Gulf of Guinea), were more closely related to each other than to samples from any other region, including the Mediterranean Sea, the Indian Ocean, and the Pacific Ocean. Phylogeographic analyses reveal that swordfish mtDNA phylogeny is characterized by incomplete lineage sorting and secondary contact of two highly divergent clades. However, despite this complex phylogenetic signature, results from an analysis of nucleotide diversity and from an analysis of molecular variance (AMOVA) were for the most part concordant and indicate that NW Atlantic and South Atlantic swordfish belong to separate populations. The mtDNA distinctiveness of NW Atlantic and South Atlantic swordfish populations is indicative of philopatric behavior in swordfish towards breeding and feeding areas.     

Molecular analysis for mitochondrial DNA disorders

In this article, we review the current methodologies used for the molecular diagnosis of mitochondrial DNA defects. Definition of mitochondrial disorders at the molecular level has been difficult because of both clinical and genetic heterogeneity. Direct DNA analysis for common point mutations and large mtDNA deletions is readily performed and can be done routinely. However, a large number of patients who have the clinical manifestations and muscle pathology findings consistent with mitochondrial DNA disorders do not have detectable common mutations. Additional mutation screening methods are required for the detection of rare and previously undescribed mutations in the mitochondrial genome.     

猕猴属五个种mtDNA多态性研究

本文以10种限制性内切酶研究猕猴属5个种(Macaca mulatta.M.nemestrina.M.assemensis.M.thibetana,M arctoides)线粒体DNA进化。在13个个体中,共检出8种限制性类型。恒河猴种内存在广泛的线粒休DNA限制性片段长度多态性(RFLP)。结合日本猴(M.fuscata)的有关资料,构建了猕猴属6个种的分子系统树,并给出各个种的分化时间。结果表明,这6个种可分成4个类群,熊猴和藏酋猴、恒河猴和日本猴之间的遗传距离较近,可分别划为同一类群,红面猴与其他5种猴的遗传距离最远,在系统发生上分离最早。