共显性分子标记基因型数据转换为二元型数据的处理软件及其在研究种质资源遗传多样性中的意义

遗传多样性研究是植物种质资源有效利用和保护的重要基础.遗传多样性研究所采用的分子标记工具主要有显性和共显性两种,两种不同类型的分子标记将产生不同的数据类型.显性分子标记产生二元型数据,共显性分子标记产生基因型数据.数据形式不同给遗传多样性的分析和研究带来多方面的困难,不同类型数据之间的互相比较也需要将基因型数据进行二元型转换.本研究基于Excel平台,设计开发了将基因型数据转换成二元型数据的处理软件.该软件按照基因型数据向二元型数据转换的原理,可以将庞大的分子标记基因型数据矩阵,迅速、高效、准确地转换成二元型(0、1)数据矩阵.利用显性分子标记ISSR和共显性分子标记SSR对野生大豆居群遗传多样性的案例分析表明,将共显性分子标记的基因型数据转换为二元型数据,有利于种质资源遗传多样性研究中不同分子标记获取的遗传多样性结果之间的比较和综合分析.     

SRAP标记及其在植物遗传育种中的应用

SRAP标记是基于选择性扩增开放性阅读框的新型分子标记,具有简便、高效、重复性好、高共显性等优点,在植物育种中已经得到广泛应用.本文介绍了SRAP标记基本原理和特点,对SRAP标记在遗传多样性研究、遗传连锁图谱构建、比较基因组以及分子标记辅助选择育种等方面的应用进行了综述.     

ISSR标记技术及其在遗传多样性研究中的应用

ISSR(Inter-Simple Sequence Repeat)技术是在PCR中直接使用微卫星序列进行DNA扩增的一种DNA分子标记。章主要介绍了ISSR标记的原理、方法、特点及其在遗传多样性研究中的应用。ISSR标记方法具有无需知道任何靶标序列的微卫星背景信息、遗传多态性高、检测快速等特点,在遗传多样性研究中具有广泛的应用前景。     

微卫星DNA标记及其在鱼类遗传多样性研究中的应用

微卫星DNA作为第二代分子遗传标记是高等真核生物基因组中种类多、分布广、具有高度的多态性和杂合度的分子标记,由于其具有多态性检出率高、信息含量大、共显性标记、实验操作简单、结果稳定可靠等优点,已经成为种群遗传学研究中被广泛应用的分子遗传标记。微卫星DNA标记技术在鱼类的群体遗传结构的分析、物种遗传多样性的鉴定以及遗传基因连锁图谱的构建等方面已初步得到应用。该文就微卫星技术的原理方法,在鱼类遗传多样性研究中的应用概况以及应用范围和注意事项等方面进行综述。为微卫星技术在鱼类遗传多样性研究中应用提供了理论参考。     

SSR分子标记在作物遗传育种中的应用

SSR(simple sequence repeat)是建立在PCR技术上的一种广泛应用的分子标记,具有含量丰富、多态性高、共显性等优点。本文简要介绍了SSR分子标记技术的原理和特点,重点介绍了SSR分子标记技术在作物遗传育种中的应用,主要在作物遗传多样性、基因定位、分子辅助标记、遗传图谱构建、品种鉴定和纯度鉴定等方面进行阐述。     

栽培沉香遗传多样性的ISSR和AFLP分析比较

探讨2种分子标记技术在沉香属药用植物遗传多样性研究中的应用。用ISSR和AFLP分子标记分析了海南、云南、广东、广西等地17份沉香属植物的遗传多样性。14个ISSR引物、8对AFLP引物分别检测到119、919个位点,多态位点百分率分别为73.95%、86.94%。由于AFLP标记具有较高的多态性位点检测效率,AFLP标记分析的遗传多样性参数高于ISSR。虽然基于Nei’s遗传距离的聚类分析结果存在着一定的差异,但用Mantel检测对两种方法检测的遗传一致度进行相关性分析表明,它们之间存在着明显的相关性（r=0.7705,P=0.0003）。ISSR标记与AFLP标记均能应用于沉香属植物的遗传多样性研究。两种标记的研究结果均揭示出沉香属植物具有较高的遗传多样水平。     

ISSR分子标记在牧草研究中的应用

ISSR（inter-simple sequence repeat）是在SSR标记基础上发展起来的一类新型的分子标记技术。在比较ISSR和其它分子标记的原理和特点的基础上,主要对ISSR标记的原理、特点以及ISSR分子标记在牧草DNA指纹库的构建、遗传多样性、种质资源鉴定、遗传作图和基因定位、分子标记辅助育种等领域的研究进展进行综述,并对其应用前景进行简要概述。     

基于ISSR标记和线粒体Cyt b基因分析高原鼠兔的遗传多样性及其遗传分化

高原鼠兔(Ochotona curzoniae)是青藏高原的特有动物和关键种。本实验应用ISSR分子标记和细胞色素b(Cytochrome b,Cytb)基因序列分析了雅鲁藏布江两岸高原鼠兔4个种群的遗传多样性和遗传分化。结果显示,两种标记所得到的4个种群的遗传多样性都较高,并以Cytb基因为指标的遗传多样性水平在种群间体现出较大差异。在ISSR标记中,分子方差分析(AMOVA)表明种群间的遗传变异为13.50%,种群分化较低且UPGMA聚类时江北岸与南岸的种群有交叉;而在Cytb基因中遗传变异主要发生在种群间,占79.24%,种群间存在着显著的遗传分化,且江北岸和南岸的两个种群分别聚为一类。研究结果表明,mtDNA基因在反映种群遗传多样性和遗传分化上较ISSR分子标记相对具有优势。     

分子标记技术在烟草种质资源研究中的应用进展

DNA分子标记作为新发展起来的一种遗传标记形式,凭借其可靠有效等优点,在农业科学研究中的应用越来越广泛。综述了几种分子标记技术(RAPD、AFLP、ISSR)在烟草种资源中的应用进展,分析了分子标记技术在烟草种资源及遗传多样性研究中存在的问题及今后发展方向。     

DNA分子标记在木耳属真菌中的应用研究进展

介绍了目前已在木耳属真菌中广泛应用的几种DNA分子标记技术(RFLP、RAPD、AFLP、ISSR、SRAP、SCAR、ITS、IGS),以及这些标记在木耳属真菌系统发育、分类研究、种间和种内鉴定、遗传多样性分析等方面的应用,并展望了这些标记技术在木耳属真菌中的应用前景。     

Evaluation of genetic diversity and population structure of polygonati rhizoma germplasms: implications for better crop development and conservation of a traditional Chinese medicine

Polygonati rhizoma (PR) is an important and widely used product in Chinese traditional medicine and edible goods. The time-consuming nature of breaking dormancy in both rhizomes and seeds means that improving variety selection is limited to collection, identification, and selection of germplasms. In this study, we used two DNA-based molecular marker techniques—inter simple sequence repeat (ISSR) and start codon targeted (SCoT)—to assess the genetic diversity and population structure among PR source plants collected from 47 different regions and belonging to 12 populations (P1–P12). For molecular markers analysis, 15 ISSR and 10 SCoT markers were tested. Total number of 159 fragments (150–4000 bp) were amplified based on ISSR analysis with a range from 6 to 17 bands, 153 of them were polymorphic, ranging from 97.27 to 100%. For SCoT analysis, 164 polymorphic bands (150–5000 bp) were observed, varying from 14 to 19 bands for each primer. Nei’s genetic diversity analysis showed that the highest value was found in P11 for ISSR and P4 for SCoT markers. The highest Nei’s genetic diversity value was observed in P5 for combined markers and the low in P2. Nei’s dendrogram constructed with combined markers indicated a 75–89% of genetic similarity coefficient among populations. Population structure analysis revealed an optimum number of three groups, the same as their geographical distribution. This knowledge on PR genetic diversity can be used in future breeding programs, genetic improvement, product enhancement, and germplasms conservation.     

ISSR Markers as a Tool for the Assessment of Genetic Diversity in Passiflora

Genetic variation among sweet, purple, and yellow passion fruit accessions was assessed using inter-simple sequence repeat (ISSR) markers. Eighteen ISSR primers were used to evaluate 45 accessions. The number of polymorphic bands per primer varied from 4 to 22, with 12.4 bands per primer on average. Nei's genetic distance between accessions ranged from 0.04 to 0.35. Clustering using the neighbor-joining method resulted in the formation of 11 major clusters. It was not possible to classify the accessions according to their geographic origin, showing that there is no structure in the gene bank. The overall mean Shannon-Weaver diversity index was 0.32, indicating good resolution of genetic diversity in passion fruit germplasm using ISSR markers. Our results indicate that ISSR can be useful for genetic diversity studies, to provide practical information for parental selection and to assist breeding and conservation strategies.     

Genetic diversity analysis of 60 ginger germplasm core accessions using ISSR and SSR markers

Molecular techniques play a critical role in studies of phylogeny and, thus, have been applied to understand the distribution and extent of genetic variation within and between species. In the present study, a genetic analysis was undertaken using molecular markers (9 ISSR and 13 SSR) on 60 ginger cultivars from different regions of the eastern coast of India (Odisha). The data obtained with 22 polymorphic markers revealed moderate to high diversity in the collection. Both ISSR and SSR markers were efficient in distinguishing all the 60 ginger cultivars. A total of 42 and 160 polymorphic bands were observed with ISSR and SSR markers, respectively. However, SSR markers were observed to be better at displaying average polymorphism (63.29%) than ISSR markers (55%). Analysis of molecular variance results showed that 52 and 66% of the variation occurred among different ginger populations, whereas 48 and 34% of the variation was found within populations, respectively, using ISSR and SSR markers, indicating that ginger cultivars display significant genetic diversity at the population level. Principal coordinates analysis and the dendrogram constructed out of combined data of both markers showed grouping of ginger accessions to their respective area of collection, indicating geographical closeness due to genetic similarity irrespective of the relationship that exists at the morphological level.     

Genetic diversity in european and Argentinian cultivated potatoes (Solanum tuberosum subsp. tuberosum) detected by inter-simple sequence repeats (ISSRs).

In this study, the use of inter-simple sequence repeats (ISSR) to assess genetic diversity between cultivated potatoes (Solanum tuberosum subsp. tuberosum) is reported. ISSR technology rapidly reveals high polymorphic fingerprints and thus determines the genetic diversity among potato cultivars. Nine primers were selected according to the number of amplified markers and the level of polymorphism detected. Three primers (GAG(CAA)5, CTG(AG)8, and (AG)8) were used to cluster the 28 potato accessions and 77 polymorphic markers were sufficient to identify all of the accessions. Among the 15 simple sequence repeat (SSR) motifs tested, the most abundant were CAA and AG. Argentinian- and European-grown potatoes were easily distinguished, with a higher level of genetic diversity among potatoes from Argentina. An ISSR study using a limited number of cultivars and very few primers clearly differentiated between all cultivars, thus ISSR was revealed to be a good tool for the genetic identification of potato and for future germplasm-management programs.     

ISSR分子标记及其在植物遗传学研究中的应用

ISSR分子标记是在SSR标记基础上发展起来的一种新技术,其基本原理是在SSR的5′或3′端加锚1~4个嘌呤或嘧啶碱基,然后以此为引物,对两侧具有反向排列SSR的一段基因组DNA序列进行扩增。重复序列和锚定碱基是随机选择的,扩增产物经聚丙烯酰胺或琼脂糖凝胶电泳分离后,每个引物可以产生比RAPD方法更多的扩增片段,因此,ISSR标记是一种快速、可靠、可以提供有关基因组丰富信息的DNA指纹技术。ISSR标记呈孟德尔式遗传,在多数物种中是显性的,目前已广泛用于植物品种鉴定、遗传作图、基因定位、遗传多样性、进化及分子生态学研究中。 ISSR Markers and Their Applications in Plant Genetics WANG Jian-bo Key Laboratory of MOE for Plant Developmental Biology,Wuhan University,Wuhan 430072,China Abstract:Recently,inter-simple sequence repeat (ISSR) markers have emerged as an alternative system with reliability and advantages of microsatellites (SSR).The technique involves amplification of genomic segments flanked by inversely oriented and closely spaced microsatellite sequences by a single primer or a pair of primers based on SSRs anchored 5′ or 3′ with 1-4 purine or pyramidine residues.The sequences of repeats and anchor nucleates are arbitrarily selected.Coupled with the separation of amplification products on a polyacrylamide or agarose gels,ISSR amplification can reveal a much larger number of fragments per primer than RAPD.It is concluded that ISSR technique provides a quick,reliable and highly informative system for DNA fingerprinting.ISSR markers are inherited in Mendelin mode and segregated as dominant markers.This technique has been widely used in the studies of cultivar identification,genetic mapping,gene tagging,genetic diversity,evolution and molecular ecology. Key words：molecular markers; ISSR; plant;applications     

串珠藻目分子系统学研究进展

串珠藻目(Batrachospermales)是淡水红藻中最主要的类群。近年来, 应用DNA序列分析探讨串珠藻目的系统发育, 并与传统的形态学和生态学特征相结合, 为串珠藻目系统学研究拓展了新的思路。本文回顾了串珠藻目的建立及其所含类群的研究历史, 归纳了目前在串珠藻目系统发育与进化研究中常用的分子标记方法, 其中包括核基因组的18S rDNA、26S rDNA和ITS序列, 叶绿体基因组的rbcL序列, 线粒体基因组的cox2-3序列, 以及新兴的ISSR技术, 并对各种分子标记的特点及适用范围做了评述。结果表明, ITS序列多适用于种群分化及相近种间遗传分析, ISSR标记适用于种下分类群间及同一种群不同个体间基因多态性分析, cox2-3序列在一定程度上也可用于同一种群不同个体间的基因多态性分析, 而18S rDNA 与rbcL序列既可用于种间关系分析, 又可用于更高水平分析的构建系统树。这些分子标记已被证明在研究串珠藻目系统地理、物种起源和散布机制方面有着广泛的应用前景。同时, 本文对串珠藻目分子系统学研究的最新进展也进行了概述,并对今后的研究方向做了展望。     

串珠藻目分子系统学研究进展

串珠藻目（Batrachospermales）是淡水红藻中最主要的类群。近年来,应用DNA序列分析探讨串珠藻目的系统发育,并与传统的形态学和生态学特征相结合,为串珠藻目系统学研究拓展了新的思路。本文回顾了串珠藻目的建立及其所含类群的研究历史,归纳了目前在串珠藻目系统发育与进化研究中常用的分子标记方法,其中包括核基因组的18SrDNA、26SrDNA和ITS序列,叶绿体基因组的rbcL序列,线粒体基因组的cox9．-3序列,以及新兴的ISSR技术,并对各种分子标记的特点及适用范围做了评述。结果表明,ITS序列多适用于种群分化及相近种间遗传分析,ISSR标记适用于种下分类群间及同一种群不同个体间基因多态性分析,cox2-3序列在一定程度上也可用于同一种群不同个体间的基因多态性分析,而18SrDNA与rbcLFF列既可用于种问关系分析,又可用于更高水平分析的构建系统树。这些分子枥对己已被证明在研究串珠藻目系统地理、物种起源和散布机制方面有着广泛的应用前景。同时,本文对串珠藻目分子系统学研究的最新进展也进行了概述,并对今后的研究方向做了展望。     

松花型花椰菜主要品种鉴定的分子标记分析

利用RAPD、ISSR和SRAP 3种分子标记对我国南方地区松花型花椰菜主栽品种进行鉴定,分析了品种间的遗传多样性。3种标记共产生370条扩增带,238条为多态性条带,其多态率为64.32%。其中只有SRAP标记的引物m e1/em1可将20个品种全部鉴别。遗传相似系数分析表明,松花型花椰菜品种之间的亲缘关系较近,遗传背景比较狭窄。聚类分析表明品种间的亲缘关系与熟性、地理分布相关。研究表明,分子标记能有效地应用于花椰菜品种鉴定,且综合多种分子标记分析品种间的遗传多样性将更加准确可靠。     

不同龙眼资源遗传多样性的SCoT和ISSR 比较分析

应用SCoT和ISSR标记对36份龙眼资源和1份近缘种龙荔的遗传多样性进行分析。结果表明:12对SCoT引物共扩增出127条带,平均每条引物扩增10.58条带;15条ISSR引物共扩增出117个条带,平均扩增7.8条带。UPGMA聚类结果表明:SCoT标记和ISSR标记分别在相似系数0.672和0.685水平上,均可将37份材料分成6大类群,SCoT和ISSR标记均适用于龙眼材料的遗传多样性分析,如果将两种标记的数据进行综合分析,可以缩小单一标记的误差。研究结果为龙眼种质资源的保存和利用提供了重要的依据。     

新疆地区番茄潜叶蛾遗传多样性的ISSR分析

[目的]番茄潜叶蛾已成为世界性番茄的重要害虫,对番茄产业的发展造成了严重的威胁,研究其遗传多样性有利于揭示不同地理种群的遗传变异结构。[方法]采用ISSR分子标记技术分析了20个地理种群番茄潜叶蛾的遗传多样性和遗传结构特征。[结果]15条引物扩增出137条ISSR条带,其中多态性条带占96.35%,所有个体显示了各自独特的ISSR图谱。ISSR的标记遗传多样性结果表明,20个番茄潜叶蛾地理种群遗传距离大小范围为0.0065~0.1623,遗传一致度范围为0.8502~0.9935。种群变异来源分析表明,25.36%的遗传变异来自种群间,74.64%的变异来源于种群内部。UPGMA系统发育分析结果表明,各地理种群的聚类与地理位置无较强的关联性。[结论]番茄潜叶蛾尚处在入侵早期阶段,且具备频繁入侵和多点的特征。防控上要注意加强检疫,阻绝多点入侵来源。