用ISSR标记技术分析山药品种遗传多样性

利用ISSR标记技术对28个山药品种的遗传多样性进行分析。结果表明,从44条ISSR引物中可筛选出7条能够扩增出清晰、稳定条带的引物;这7条ISSR引物对28个山药品种扩增条带间存在较大差异,多态性条带比率为83.01%,Shannon多样性指数为0.3191;构建的分子树状图将28个山药品种划分为4组:第一组含有日本白、花山药和日本园3个品种;第二组为小叶山药;第三组为嵩野1号;其余23个品种归入第四组。而且主成分分析结果支持上述的聚类分析结果。这为利用ISSR标记技术鉴定山药品种,为有效地利用山药种质资源提供了依据。     

40个黄皮品种的ISSR分析

采用ISSR-PCR分子标记技术对40个黄皮品种的遗传多样性进行分析。从96条ISSR引物中筛选出15条引物用于PCR扩增,共扩增出165条带,其中多态性条带100条,多态性比率为60.6%。应用SPSS软件计算各品种间的Jaccard相似系数介于0.714~1.000,UPGMA法将40个品种分成5组。     

河南大豆遗传多样性的ISSR分析

用ISSR标记技术对10个大豆品种进行遗传多样性分析.从44条随机引物中筛选出8个多态性引物,共扩增出89条带,其中有55条为多态性条带,多态性比率为61.8%,条带大小为220~1 500 bp,平均每个引物可扩增出11条带.Shannon多样性指数评价结果表明,平均多样性指数为0.286 5,观察等位基因数和有效等位基因数分别为1.618和1.300 8;统计分析结果表明,10个品种间的相似系数为0.60~0.75,平均相似系数为0.69;聚类分析结果表明,10个大豆品种可聚成2组:第一组包括豫豆15、豫豆11、豫豆24、周豆12和周豆11;第二组包括豫豆22、周豆13、豫豆6、中作98-3和豫豆26;主成分分析结果支持聚类分析结果.本研究为大豆品种鉴定和种质资源利用奠定了基础.     

利用RAPD和ISSR分子标记分析地黄种质遗传多样性

用RAPD与ISSR技术对地黄的8个品种和2个脱毒品系进行了种质遗传多样性分析.分别从80条RAPD引物和44条ISSR引物中筛选出适合地黄种质分析的17条RAPD引物和10条ISSR引物用于RAPD和ISSR分析.17条RAPD引物共扩增出177条带, 多态性位点数为109; 多态性位点比率为61.58%;平均多样性指数(I)为0.3135;每个位点的有效等位基因数(Ne)是1.3641; 10条ISSR引物共扩增出110条带. 多态性位点数为79; 多态性位点比率为71.58%;平均多样性指数(I)为0.3577;每个位点的有效等位基因数(Ne)是1.4037. 基于扩增条带数据库建立了各自的Jaccard遗传相关系数矩阵,构建了相似的分子树状图,将10个供试材料分为2类:一类群含组培85.5、大田85.5、组培9302、大田9302、金状元和金白6个材料;另一类群含北京1号、大红袍、地黄9104和野生地黄4个材料.两种分子标记的分析结果呈极显著正相关(r＝0.649).结果表明,RAPD与ISSR标记适合于地黄种质遗传多样性分析,ISSR标记技术是一种多态性和重复性优于RAPD技术的实用技术.     

RAPD和ISSR分子标记对果蔗种质资源的遗传多样性研究

利用RAPD与ISSR分子标记技术对40份不同地方果蔗种质的遗传多样性进行分析。从供试材料中筛选到具有多态性的RAPD引物23条,ISSR引物28条。23条RAPD引物共扩增出250条带,多态性条带比率为70%,相似系数变化范围在0.68-1.00之间;28条ISSR引物共扩增出301条带,多态性条带比率为77.1%,相似系数变化范围在0.66-1.00之间。根据两种标记的结果,用UPGMA法对40份果蔗种质材料进行聚类分析,结果表明,RAPD和ISSR均将40份果蔗种质分为4类:第Ⅰ类为32份地方果蔗品种,包括福建、江西、浙江、广西、云南等地的品种;第Ⅱ类为外引黑皮果蔗Badila和丰城紫皮果蔗;第Ⅲ类为杂交种白鳝、歪干担、肚度、温岭果蔗以及人工杂交选育的果蔗品种474;第Ⅳ类只有广东的黄皮果蔗。这两种标记的聚类结果相关分析表明,它们存在呈极显著相关(r=0.9746)。但ISSR标记比RAPD标记可检测到更大的遗传变异。     

利用RAPD和ISSR分子标记分析怀地黄种质遗传多样性

用RAPD与ISSR技术对怀地黄的8个品种和2个脱毒品系进行了种质遗传多样性分析。分别从80条RAPD引物和44条ISSR引物中筛选出适合怀地黄种质分析的17条RAPD引物和10条ISSR引物,用于RAPD和ISSR分析。17条RAPD引物共扩增出177条带, 多态性位点数为109; 多态性位点比率为61.58%;平均多样性指数(I)为0.3135;每个位点的有效等位基因数（Ne）是1.3641; 10条ISSR引物共扩增出110条带. 多态性位点数为79; 多态性位点比率为71.58%;平均多样性指数(I)为0.3577;每个位点的有效等位基因数（Ne）是1.4037。 基于扩增条带数据库建立了各自的Jaccard遗传相关系数矩阵,构建了相似的分子树状图,将10个供试材料分为2类:一类群含组培85.5、大田85.5、组培9302、大田9302、金状元和金白6个材料;另一类群含北京1号、大红袍、地黄9104和野生地黄4个材料。两种分子标记的分析结果呈极显著正相关(r＝0.649)。结果表明,RAPD与ISSR标记适合于怀地黄种质遗传多样性分析,ISSR标记技术是一种多态性和重复性优于RAPD技术的实用技术。     

乌塌菜种质资源遗传多样性的ISSR分析

利用ISSR技术对48份乌塌菜种质资源进行遗传多样性分析。从60条随机引物中筛选出稳定性强、条带清晰且多态性丰富的9条引物进行PCR扩增,共扩增出103条谱带,平均每个引物扩增出11.4条带,其中多态性带85条,多态性位点百分率为82.68%。不同乌塌菜种质间遗传相似系数变幅为0.59~0.97,说明ISSR标记能够揭示材料间较高的遗传多样性。利用UPGMA聚类分析,ISSR标记能将48份乌塌菜品种完全区分开,48份乌塌菜种质被划分为4个类群,聚类结果与叶片颜色相关,为乌塌菜品种资源的研究利用提供参考。     

ISSR分子标记检测大麻遗传多样性的初步分析

目的:利用ISSR分子标记技术初步检测和分析中国云南和内蒙地区毒品原植物大麻的遗传多样性。方法:用CTAR法提取大麻基因组DNA,设计10个ISSR引物,扩增产物采用6%中性聚丙烯酰胺凝胶电泳-硝酸银染色法检测,根据出现的条带数目和片段大小等分析大麻的多样性。结果:从10个ISSR引物中筛选出的4个引物用于2个地区的大麻基因组DNA扩增,PCR产物可以检测到51条重复性较好、带型清晰的DNA片段,其多态性总体比率为78.43%。云南地区和内蒙地区大麻样品可分别获得43和33条带,其中多态性条带分别为33条(76.74%)和21条(63.64%)。结论:ISSR分子标记技术揭示了大麻具有较高的遗传多样性,对于鉴别犯罪现场大麻检材的产地及种属来源具有一定的价值。     

14个蝴蝶兰品种遗传关系的ISSR分析

采用ISSR分子标记技术对14个蝴蝶兰品种进行品种间遗传关系的研究。利用14个筛选的引物共扩增出179条带,其中多态性条带147条,多态性条带比率（PPB）为82％。品种之间的遗传相似系数范围在0．734—0．936间,说明部分蝴蝶兰品种间存在显著的遗传分化。14个引物组合可区分所有14个品种,并且检测到20条品种特异性条带,这些品种特异条带可用来鉴定供试蝴蝶兰中的10个品种。因此,ISSR分子标记能有效地进行蝴蝶兰品种鉴定。UPGMA聚类分析表明,14个品种可聚为2类,聚类情况与花色特征比较一致,但与花色的划分结果不完全相同,这可能是由于品种间杂交引起的。本文也论讨了ISSR分析结果对蝴蝶兰育种的指导意义。     

47份水稻品种资源的ISSR遗传多样性分析

为研究广东省惠州市种植的常规水稻品种的遗传多样性,本实验利用ISSR标记对47份水稻品种资源进行遗传多样性检测.从49条引物中筛选出5条重复性好,条带清晰的引物进行PCR扩增,共扩增出53条带,每个引物可以扩增出9～13条带,平均为10.6条,其中47条具有多态性,比率为88.7%.不同水稻品种间遗传相似系数变幅为0.319～0.936,平均达0.691,说明ISSR标记能够揭示材料间较高的遗传多样性.通过聚类,从分子水平对水稻品种资源的遗传关系进行分析,并对47份水稻品种资源进行分类,ISSR标记能将47份水稻品种完全区分开,为水稻品种资源的研究利用提供参考.     

14个蝴蝶兰品种遗传关系的ISSR分析

采用ISSR分子标记技术对14个蝴蝶兰品种进行品种间遗传关系的研究。利用14个筛选的引物共扩增出179条带,其中多态性条带147条,多态性条带比率(PPB)为82%。品种之间的遗传相似系数范围在0.734~0.936间,说明部分蝴蝶兰品种间存在显著的遗传分化。14个引物组合可区分所有14个品种,并且检测到20条品种特异性条带,这些品种特异条带可用来鉴定供试蝴蝶兰中的10个品种。因此,ISSR分子标记能有效地进行蝴蝶兰品种鉴定。UPGMA聚类分析表明,14个品种可聚为2类,聚类情况与花色特征比较一致,但与花色的划分结果不完全相同,这可能是由于品种间杂交引起的。本文也论讨了ISSR分析结果对蝴蝶兰育种的指导意义。     

Genetic similarity among cultivars of Phyllostachys pubescens

Phyllostachys pubescens is the most important economic bamboo species in China, which grows widely in the South of China. There are more than ten cultivars in this species but their genetic relationship still remains unknown. We used both amplified fragment length polymorphism (AFLP) and inter-simple sequence repeat (ISSR) techniques to determine genetic similarity among ten cultivars of P. pubescens and two related species. Eight hundred and twenty seven bands, in which 495 are polymorphic, were detected using 15 pairs of AFLP primers whereas total 231 bands, in which 154 bands are polymorphic, were scored using 16 ISSR primers. Statistic analysis showed that the genetic similarity matrices obtained from these two sets of molecular markers had a significant correlation (R = 0.959, P = 0.013). The dendrogram generated with AFLP and ISSR markers could clearly genetically identify ten cultivars of P. pubescens that had high similarity with genetic distances ranging from 0.023 to 0.108, and could be divided into three groups based on their genetic variation and similarity. Our results suggest that these molecular markers are useful to genetically classify cultivars or varieties of a species, particularly a bamboo species.     

茄子耐盐种质资源遗传多样性的SRAP和ISSR分析

利用SRAP和ISSR分子标记,研究了14份耐盐茄子种质资源的遗传多样性,结果表明,2种标记均能揭示材料间较高的遗传多样性,其中ISSR标记多态性略高于SRAP标记。在SRAP分析中,每对引物组合可扩增出8-15条DNA片段,平均为12．12条：26对SRAP引物组合共扩增出315条DNA片段,其中263条具有多态性,多态性比率为83．49％;材料间遗传相似系数变化范围为0．212～0．923,平均值为0．755。在ISSR分析中,每个引物可获得5～16条DNA片段,平均为10．87条;15个ISSR引物共扩增出163条DNA片段,其中141条具有多态性,多态性比率为86．50％;材料间遗传相似系数变幅为0．333-0．957,平均值为0．736。聚类分析表明,2种标记都能将供试材料完全区分开来,聚类结果具有一定的相似性,但也存在明显差异。Mantel相关分析表明,SRAP分析与ISSR分析的相关性达到极显著性水平（r=0．904,P〈0．01）。     

Genetic diversity analysis of Cynodon dactylon (bermudagrass) accessions and cultivars from different countries based on ISSR and SSR markers

ISSR and SSR markers were used to evaluate genetic diversity among 33 Cynodon dactylon accessions and 22 cultivars from four different countries in order to provide information on how to improve the utilization of bermudagrass germplasms. Eighty eight bands were amplified by nine SSR primer combinations and 236 bands were observed from 23 ISSR primers. The results showed that 97.7% of the SSR primers and 86.9% of the ISSR primers were polymorphic. The genetic similarity coefficients (GSC), gene diversity (He) and Shannon index (I) were 0.58–0.97, 0.27 and 0.41, respectively, for ISSR and 0.52–0.97, 0.29, and 0.43 for SSR. The UPGMA analysis clustered the 55 accessions (cultivars) into three groups. The cluster results produced by the ISSR data were close to the SSR data results. Analysis based on the combined ISSR and SSR data was more closely related to the geographical distribution of the tested germplasm.     

Molecular variation and fingerprinting of Leucadendron cultivars (Proteaceae) by ISSR markers

BACKGROUND AND AIMS: There are more than 80 species of Leucadendron and most are used as cut flowers. Currently, more than 100 cultivars are used by industry and many of them are interspecific hybrids. The origin of most cultivars is unclear and their genetic diversity and relationships have not been studied. This investigation was carried out to evaluate the genetic variation and relationships among 30 Leucadendron cultivars. METHODS: ISSR markers were applied to determine the genetic variation and to discriminate Leucadendron cultivars. Sixty-four ISSR primers were screened and 25 primers were selected for their ability to produce clear and reproducible patterns of multiple bands. KEY RESULTS: A total of 584 bands of 305-2400 bp were amplified, of which 97 % were polymorphic. A dendrogram generated using the Unweighted Pair Group Method with Arithmetic Average based on a distance measure of total character difference showed that the Leucadendron cultivars clustered into two main groups. Twenty-four of the 30 cultivars can be unequivocally differentiated, but identical profiles were observed for three cultivar pairs, 'Katie's Blush' and 'Silvan Red', 'Highlights' and 'Maui Sunset', and 'Yellow Crest' and 'Yellow Devil'. CONCLUSIONS: ISSR profiling is a powerful method for the identification and molecular classification of Leucadendron cultivars. A fingerprinting key was generated based on the banding patterns produced using two ISSR primers (UBC856 and UBC857). In addition cultivar-specific ISSR bands were obtained for 17 of the 30 Leucadendron cultivars tested.     

利用ISSR分子标记检测空间诱导罗汉果DNA突变

为探究太空环境对罗汉果造成的诱变效应,筛选罗汉果新品种培育优异种质,该研究运用ISSR分子标记技术,对28个航天诱变罗汉果及主栽品种进行了全基因组多态性检测和聚类分析。结果表明:从100个ISSR引物中筛选得到17个引物,共扩增出157个条带,其中83条具有多态性,多态条带百分率为52.87%,遗传相似系数范围为0.707~0.987。根据UPGMA聚类图,28个罗汉果样本可以分为3类:聚类Ⅰ为航天种质B6♂和B3♀;聚类Ⅱ为航天种质A1♀、A14、A18♂与主栽品种;聚类Ⅲ中都为航天罗汉果种质。上述结果暗示A1♀、A14、A18♂与其他航天种质已经产生了一定的遗传分化,具有与主栽品种相似的遗传背景,可能获得了有益突变。该研究结果为罗汉果新品种培育和杂交亲本选配提供了科学依据。     

Genetic variation and cultivar identification in Cymbidium ensifolium

As a popular flowering species with many cultivars, Cymbidium ensifolium (L.) is commercially important in horticulture. However, so far little has been known about genetic diversity and conservation genetics of this species. Understanding of the genetic variation and relationships in cultivars of C.?ensifolium is a prerequisite for development of future germplasm conservation and cultivar improvement. Here we report assessment of genetic variations in C.?ensifolium cultivars using the DNA fingerprinting technique of inter-simple sequence repeats (ISSR). A total of 239 ISSR loci were identified and used for evaluation of genetic variation with a selection of 19 ISSR primers. Among these ISSR loci, 99.16% were polymorphic with wide genetic variation as shown by Nei??s gene diversity (H?=?0.2431) among 85 tested cultivars. ISSR fingerprinting profiles showed that each cultivar had its characteristic DNA pattern, indicating unequivocal cultivar identification at molecular level. Eighteen cultivar-specific ISSR markers were identified in seven cultivars. The cultivar Sijiwenhan was confirmed as hybrid by four ISSR primers. Several cultivars with same name but different geographical origins were distinguished based on their ISSR profiles. A dendrogram generated with ISSR markers could group 73 of 85 cultivars into four major clusters. Further analysis of ISSR variation revealed that about 69% of total genetic variation in this species is due to genetic divergence inside geographical groups. Our results suggest that both germplasm collection and in?situ conservation are important for future planning of C.?ensifolium species conservation.     

Molecular Characterization of Brinjal (Solanum melongena L) Cultivars using RAPD and ISSR Markers

Molecular characterization of 19 advanced cultivars and landraces of brinjal was carried out using RAPD and ISSR markers. Twenty-nine RAPD primers generated a total of 240 amplified fragments, while 23 anchored and non-anchored ISSR primers produced 299 fragments. Of these, 66 (27.5%) RAPD and 56 (18.73%) ISSR fragments were polymorphic. All the cultivars could be distinguished based on RAPD and/or ISSR profiles. A set of two RAPD primers, OPW 11 and OPX 07, was adequate to distinguish all the 19 cultivars. On the other hand, a minimum of ten ISSR primers were required to achieve the same result. Eleven cultivars could be identified by the unique presence or absence of one to four markers. The correlation between primer Rp and the number of cultivars distinguished by RAPD was r = 0.873, while that for ISSR it was r = 0.327. The correlation between PIC of primer and the number of cultivars distinguished was r = 0.324 for RAPD, while for ISSR primers it was r = ? 0.066. The probability of chance identity between two cultivars for RAPD and ISSR markers was calculated as 8.94×10^?4 and 2.25×10^?2, respectively. The average Jaccard’s similarity coefficient between cultivars based on combined RAPD and ISSR data was estimated to be 0.919. The UPGMA analysis grouped the cultivars into three main clusters with significant bootstrap support. While the cultivars bred at Indian Agricultural Research Institute, New Delhi formed one sub-cluster; others did not show a prominent region-based clustering.     

Efficiency of Inter Simple Sequence Repeat (ISSR) markers for the assessment of genetic diversity of Moroccan pomegranate (Punica granatum L.) cultivars

Genetic diversity of 27 Moroccan pomegranate cultivars from three geographical regions of Morocco was screened using 61 Inter-Simple Sequence Repeat (ISSR) markers. Eight tested ISSR primers generated 70 bands of which 61 are polymorphic (87.14%). Nei's genetic distance ranged from (0.12 to 1) with a mean of 0.67. Nei genetic diversity parameters were 0.35 and 0.32 for H_t and H_s, respectively. Our results show considerable gene flow within and among pomegranate groups and a limited differentiation among groups as suggested by values of G_st (0.08) and N_m (5.80) parameters. The Unweighted Pair Group Method with Arithmetic Mean dendrogram and Principal Component Analysis clustered the pomegranate studied into two main clusters and did not show any relationships with the geographical origins of cultivars. Our results showed that ISSR markers can be a useful tool for detecting molecular polymorphism and studying the genetic diversity of pomegranate genotypes.