食蟹猴微卫星DNA标记遗传监测及多态性分析

目的研究国内食蟹猴种群的遗传背景特性,建立食蟹猴种群遗传质量监测方法。方法采用微卫星DNA遗传标记技术对50只食蟹猴种群个体进行遗传质量监测及DNA多态性分析。结果从100个微卫星DNA位点中筛选出20个多态性高的位点,其食蟹猴种群个体的等位基因数目为5-10条,个体间均呈现高度的多态性;其观察等位基因数（Na）为5.0～10.0,有效等位基因数（Ne）为4.6118～8.3404,基因多样性（H）为0.7832～0.8801和香隆信息指数（I）为1.5651～2.1592。结论本实验有效地分析了食蟹猴种群的遗传多态性,为今后筛选特异性微卫星位点来建立食蟹猴种群遗传质量监测方法提供了理论依据。     

单根毛发具有不同的DNA分型

在DNA水平上研究遗传变异性已在基因定位和疾病诊断方面取得明显进展,并应用于法医学领域。用限制性片段长度多态性(RFLP)分析DNA时,多个位点分型需要微克量的DNA,单个位点则需数百毫微克量的DNA。象单根毛发和血斑等法医样品往往不能获得上述量的DNA。既然单个DNA分子的某一特定基因片段也能用聚合酶链反应(PCR)大量扩增,为了检测人单根毛发中的多态性DNA顺序,实验以PCR扩增毛发DNA,然后进行DNA分型。     

基于粪便DNA的岩羊微卫星引物的筛选及个体识别

贺兰山保护区岩羊Pseudois nayaur种群数量近年来增长很快,为了解贺兰山保护区的岩羊种群的遗传健康状况,从而更好地保护和管理岩羊种群,需要对岩羊种群的遗传多样性进行研究。在其近缘物种中选出36对微卫星引物对收集到的岩羊粪便DNA样品进行PCR扩增。结果发现,有9对引物在岩羊粪便DNA中扩增出了多态性位点。各位点基因杂合度介于0.26~0.95之间,平均杂合度为0.48,各位点多态信息含量介于0.23~0.68之间,平均多态性为0.48。     

华北地区大仓鼠种群的遗传变异

应用随机扩增多态性DNA(RAPD)方法对华北地区不同大仓鼠种群的遗传变异进行了研究。结果表明,大仓鼠群体内具有较丰富的遗传变异,不同地区种群的多态位点率均高于60%,Nei’s基因多样度值范围在0·204~0·326之间,Shannon信息指数为0·306~0·484;分析遗传分化指数表明,大仓鼠种群内具有潜在的遗传结构,30·9%的变异来源于种群间存在的遗传变异。结果表明,大仓鼠在不同空间分布区内存在遗传多态性差异,地区种群间已有一定程度的遗传分化,群体间有限的基因流及遗传漂变可能对大仓鼠种群的遗传分化产生了重要的作用。     

恒河猴与食蟹猴微卫星DNA多态性的比较分析

目的分析恒河猴和食蟹猴群体间的遗传多样性,确立一种对恒河猴和食蟹猴种群个体的遗传鉴别方法。方法利用聚合酶链反应（PCR）扩增技术采用15个多态性微卫星DNA位点对50只恒河猴和50只食蟹猴个体进行了DNA多态性的分析,对比两群体间等位基因数目差异。结果筛选的15个具有显著多态性的微卫星DNA位点对恒河猴和食蟹猴种群可以进行DNA多态性分析,其等位基因数目均在7个以上,且两群体间有11个位点的等位基因数存在一定的差异。结论利用这些多态性微卫星DNA位点建立一种有效鉴别恒河猴和食蟹猴种群遗传背景的方法具有一定的可行性。     

利用AFLP分子标记探讨蜡梅种质资源的遗传多样性

利用AFLP分子标记技术,对中国蜡梅种质资源7个野生种群的遗传多样性进行了研究。利用筛选出的3对引物,共扩增出253条谱带,其中218条多态带,多态位点占86.17% ;种群间的基因分化系数为0.2906,说明蜡梅基因多样性主要存在于种群内;种群总的Nei s基因多样性指数为0.2933,Shannon信息多态性指数为0.4487,蜡梅总的遗传多样性水平较高。蜡梅不同种群遗传多样性水平差异较大,种群多态位点百分率在65.44% ～87.16%之间,Nei s基因多样性指数为0.1653 ～0.4012,Shannon信息多态性指数为0.3132 ～0.5603。神农架种群(SN)和保康种群(BK)的遗传多样性水平较高。用NTSYS2.01版软件对样品进行UPGMA聚类分析,结果7个种群并没有按地理距离进行聚类。最后提出要对各蜡梅野生群体采取相应的迁地和就地保护措施。     

草履蚧不同寄主和地理种群遗传分化的RAPD分析

应用随机扩增多态性DNA(RAPD)技术对草履蚧保定、石家庄、邯郸16个不同寄主地理种群遗传多样性和种群分化进行研究,结果显示4个RAPD引物共扩增出41个多态性位点,多态位点比率为100%。遗传距离指数在0.701—0.4360,平均为0.2395。其中以邯郸枫杨和邯郸垂丝海棠为寄主的草履蚧种群遗传距离最小(0.0701);以石家庄紫叶李和邯郸木槿为寄主的种群遗传距离最大(0.4360)。遗传一致度系数在0.6466—0.9290。说明草履蚧不同种群遗传多样性丰富并存在遗传差异。聚类分析结果表明草履蚧种群遗传多样性同时受到寄主和地理因素的双重影响,且不同寄主草履蚧种群已产生明显的遗传分化。     

塔里木兔种群遗传结构的初步探讨

塔里木兔作为中国特有种, 其种群遗传结构直到现在还未知。我们从采自于新疆维吾尔自治区3 个种群的25 号样品中扩增得到529 bp 线粒体DNA 控制区片段, 共发现存在76 个多态性位点。全部样品中定义了19 个单倍型, 每个种群都显示了很高的单倍型多态性。进一步分析表明, 3 个种群存在明显的遗传分化和较低的基因流。通过错配分布和Fu’s 中性检验分析发现, 阿克苏(AKS) , 若羌(RQ) 和疏勒(SL) 种群相对比较稳定。     

几种杀虫药剂敏感蚊类酯酶多态性的研究

通过蚊虫酯酶蛋白的淀粉凝胶电泳分析和基因组DNA的限制性酶切片段长度多态性(RFLPs)比较, 对尖音库蚊Culex pipiens、三带喙库蚊Culex tritaeniorhynchus和中华按蚊Anopheles sinensis有机磷杀虫药剂敏感种群的酯酶蛋白和结构基因的多态性进行分析。发现在蛋白质水平上,三带喙库蚊敏感种群(n=54)在酯酶α和β位点分别存在2个和3个等位基因,在DNA水平上有2.9%的个体具有与酯酶β1¹基因1.3 kb Cdna片段同源的1.3 kb单拷贝带存在。发现中华按蚊敏感种群 (n= 50)中具有低活性的非特异性酯酶存在,在蛋白质水平上,酯酶α和β位点各有一个等位基因;在DNA水平上,通过对单个蚊虫基因组DNA的研究未发现有与酯酶β1¹基因同源的酯酶编码基因的存在。对尖音库蚊北京敏感种群(n= 64)的研究发现,在酯酶α和β位点都存在5个等位基因,在DNA水平上,使用一个限制性内切酶(EcoRI),15只蚊虫的样本在酯酶β位点发现了5个等位基因,说明在尖音库蚊北京敏感种群的酯酶β基因周围存在着较大的中性多态性,在有机磷杀虫剂的选择下,这些中性多态性可能会成为基因扩增的潜在因素。     

转Xa21基因水稻中T-DNA整合的遗传定位

利用转抗白叶枯病基因Xa21的水稻材料,通过TAIL－PCR方法扩增T－DNA整合的侧翼序列。从中筛选属于水稻基因组DNA的T－DNA整合的侧翼序列作为探针,将外源基因整合位点定位到窄叶青／京系17DH群体构建的水稻分子连锁图谱上。共获得属于水稻基因组DNA的T－DNA侧翼序列22个,其中的19个序列在定位群体的两个亲本之间显示RFLP多态性,分别定位在水稻基因组的第3,4,5,7,9,10,11和12染色体上。带有转基因Xa21的T－DNA整合的定位为研究外源基因在不同染色体位点的位置效应和稳定遗传打下基础。     

Direct amplification of length polymorphisms (DALP), or how to get and characterize new genetic markers in many species.

Direct amplification of length polymorphisms (DALP) uses an arbitrarily primed PCR (AP-PCR) to produce genomic fingerprints and to enable sequencing of DNA polymorphisms in virtually any species. Oligonucleotide pairs were designed to each produce a specific multi-banded pattern and all the fragments thus generated can be directly sequenced with the same two universal M13 sequencing primers. This strategy combines the advantages of a high resolution fingerprint technique and the possibility of characterizing the polymorphisms. The use of family members as templates in the multi-locus detection step allows a direct test of allele transmission, as well as early mapping of the markers or selection of loci associated with some traits or diseases. We used this method to detect micro-deletions/insertions and microsatellite DNA loci useful in population genetics studies, but it could be applied in many other fields of biology, such as genome mapping for definition of polymorphic sequence tagged sites, directly localized on a genetic map.     

A non-invasive technique for rapid extraction of DNA from fish scales

DNA markers are being increasingly used in studies related to population genetics and conservation biology of endangered species. DNA isolation for such studies requires a source of biological material that is easy to collect, non-bulky and reliable. Further, the sampling strategies based on non-invasive procedures are desirable, especially for the endangered fish species. In view of above, a rapid DNA extraction method from fish scales has been developed with the use of a modified lysis buffer that require about 2 hr duration. This methodology is non-invasive, less expensive and reproducible with high efficiency of DNA recovery. The DNA extracted by this technique, have been found suitable for performing restriction enzyme digestion and PCR amplification. Therefore, the present DNA extraction procedure can be used as an alternative technique in population genetic studies pertaining to endangered fish species. The technique was also found equally effective for DNA isolation from fresh, dried and ethanol preserved scales.     

AFLP标记的特点及其在昆虫学研究中的应用

扩增片段长度多态性（AFLP）是一种新兴的很有效的分子遗传标记方法, 它通过对基因组DNA限制性内切酶酶切片段进行选择性扩增而揭示多态性,具有快速、经济简便、不需要预先知道模板DNA的信息、模板需要量少、重复性高、结果可靠及具有很高的信息含量等优点。AFLP也具有缺点,主要是标记是显性的,同其他显性标记一样,不能区分杂合体和纯合体,因而不能更好地估算种群遗传的变异,对种群遗传结构的分析不能提供更多的统计信息;AFLP技术较复杂,而且经常使用放射性同位素,对模板DNA质量要求也较高。为了克服AFLP的这些缺点,人们又在其基础上发展了其他相关技术,例如AFRP、SAMPL、DALP和TE-AFLP等。目前AFLP在昆虫方面的应用还不是很多,处于初级阶段,主要应用在生态型鉴定、种群遗传分析、连锁图谱构建等方面,相信随着其技术的发展完善,必将会越来越多地应用于昆虫学的研究中。     

微卫星DNA在分子遗传标记研究中的应用

随着种群遗传学的发展 ,分子遗传标记特别是微卫星标记已经成为研究种群遗传的有力工具。本文就微卫星遗传标记的研究背景、技术应用以及优势与不足等方面进行了综述。     

Use of Random Amplified Polymorphic DNA Analysis for Economically Important Food Crops

The objective of this review is to summarize numerous studies on the use of the random amplified polymorphic DNA （RAPD） technique on rice, corn, wheat, sorghum, barley, rye, and oats to examine its feasibility and validity for assessment of genetic variation, population genetics, mapping, linkage and marker assisted selection, phylogenetic analysis, and the detection of somaclonal variation. Also we discuss the advantages and limitations of RAPD. Molecular markers have entered the scene of genetic improvement in different fields of agricultural research. The simplicity of the RAPD technique made it ideal for genetic mapping, plant and animal breeding programs, and DNA fingerprinting, with particular utility in the field of population genetics.     

Sequence-tagged-sites (STSs) of cDNA clones in Cryptomeria japonica and their evaluation as molecular markers in conifers

 We have generated 66 sequence-tagged-site (STS) markers from cDNA clones of Cryptomeria japonica, and 60% of them have already been mapped into C. japonica linkage groups. All of the STS markers showed a single fragment following polymerase chain reaction (PCR) amplification. We investigated by polymorphism of these STS markers in a mapped F₂ population and 15 plus trees by means of a restriction endonuclease analysis. Polymorphism levels were 10.6% and 22.7% in the F₂ population and the 15 plus trees, respectively. PCR amplification levels of the 66 STS markers in 14 conifer species varied depending on their genetic relationship with C. japonica. Taxodium, which is closely related to C. japonica, had the most amplifications (31.82%), followed by Sequoiadendron giganteum, which is of the same family. The average proportion of PCR amplifications in each family gradually declined in the following order: from Taxodiaceae to Cuppresaceae, Sciadopityaceae, Pinaceae, and Taxaceae. These results are in general agreement with a molecular phylogenetic relationship based on chloroplast DNA. The 66 STS markers will be useful as on anchor point for genome mapping and population genetics, and some of them will also be useful when studying other conifers. Received: 8 September 1996 / Accepted: 8 November 1996     

Start Codon Targeted (SCoT) Polymorphism: A Simple,Novel DNA Marker Technique for Generating Gene-Targeted Markers in Plants

Random amplified polymorphic DNA (RAPD) markers have been used for numerous applications in plant molecular genetics research despite having disadvantages of poor reproducibility and not generally being associated with gene regions. A novel method for generating plant DNA markers was developed based on the short conserved region flanking the ATG start codon in plant genes. This method uses single 18-mer primers in single primer polymerase chain reaction (PCR) and an annealing temperature of 50°C. PCR amplicons are resolved using standard agarose gel electrophoresis. This method was validated in rice using a genetically diverse set of genotypes and a backcross population. Reproducibility was evaluated by using duplicate samples and conducting PCR on different days. Start codon targeted (SCoT) markers were generally reproducible but exceptions indicated that primer length and annealing temperature are not the sole factors determining reproducibility. SCoT marker PCR amplification profiles indicated dominant marker like RAPD markers. We propose that this method could be used in conjunction with these markers for applications such as genetic analysis, bulked segregant analysis, and quantitative trait loci mapping, especially in laboratories with a preference for agarose gel electrophoresis.     

Phylogenetic distribution and genetic mapping of a (GGC)n microsatellite from rice (Oryza sativa L.)

DNA microsatellites are ubiquitously present in eukaryotic genomes [30] and represent a vast source of highly informative markers [30, 33, 34, 2]. We describe in this article a (GGC)_n microsatellite which is widely distributed in eukaryotic genomes. Using polymerase chain reaction (PCR) techniques and DNA sequencing, we demonstrated for the first time in plant species that a (GGC)_n microsatellite locus is moderately polymorphic. Six alleles are present at this locus in rice and length polymorphisms are caused by variation in the number of tandem GGC repeats. By scoring a backcross mapping population, we were able to demonstrate that this locus is stably inherited and does not link to any known RFLP markers on the rice RFLP map. Our results suggest that DNA microsatellites should be useful in plants for construction of genetic linkage maps, extension of the existing genetic linkage maps, linkage analysis of disease and pest resistance genes, and the study of population genetics.     

Mitochondrial COI gene transfers to the nuclear genome of Dendroctonus valens and its implications

Mitochondrial gene transfer to the nuclear genome could affect the accuracy of results in population genetics and evolutionary studies using mitochondrial gene markers. In a population genetics study of the red turpentine beetle (Dendroctonus valens), an invasive species in China, we found numerous ambiguous sites existing in the Cytochrome Oxidase I (COI) gene sequences obtained directly from polymerase chain reaction (PCR) products amplified from total genomic DNA using universal primers. By comparing the profiles of restriction endonuclease digestions and the sequences of PCR products amplified from mitochondrial DNA and nuclear DNA of the same individuals, we confirmed it was a phenomenon of mitochondrial gene transfer to the nuclear genome. Large numbers of COI pseudogenes were detected in this species. According to different levels of condon position bias and phylogenetic analysis, these should have originated from independent integration events. The impact of nuclear mitochondrial DNA sequences on population genetics analyses was discussed.     

DNA polymorphism in population genetics

In the review, the literature evidence on DNA polymorphism obtained in the last 10-15 years using various molecular-genetic methods is summarized. All main types of DNA variation are considered but attention is focused on those extensively used in population genetics. The areas of using DNA markers are outlined and the limitations of their potential in analyzing genetic processes in populations are discussed. Particular emphasis is placed on the relationship between the earlier developed biochemical genetics based on protein polymorphism analysis and modern molecular population genetics based on DNA polymorphism. The possible role of selection in maintaining DNA variation is considered.