西南地区野生狗牙根种质资源的SSR与AFLP联合分析

为了制定科学的资源保护策略、促进其开发利用以及新品种的选育,对西南地区55份野生狗牙根材料,联合采用 SSR 和 AFLP 方法分析其遗传多样性.通过进行引物筛选,筛选出有效引物组合18对和11对;SSR 和 AFLP 扩增总条带353和626条,多态性条带267和592条,平均每对引物扩增出多态性条带19．61和53．83条,多态性位点百分率为75．10％和94．57％.聚类分析表明 GS＝0．806时,可将所有供试材料分成6个组群,当 GS＝0．82时,可将第 VI 个组群分成4个小组,当 GS＝0．836时,第 VI 组群中第3小组的14个材料分为3个组群基于 Shannon 多样性指数,类群内的遗传变异占总变异的67．41％,类群间的遗传变异占总变异的32．59％.基于 Nei 氏无偏估计的遗传一致度的聚类分析表明,各生态地理类群间的遗传分化与其所处的生态地理环境具有一定的相关性.通过两种标记的相关性分析,表明 SSR 和 AFLP 标记之间具有显著的相关性,而且相关性较高,证明供试材料的聚类和其生态地理环境间有一定的相关性;采用 SSR 和 AFLP 两种联合分析,结果会更加合理和有效.     

野生垂穗披碱草种质的醇溶蛋白遗传多样性分析

用酸性聚丙烯酰胺凝胶电泳(A-PAGE) 对采集自中国新疆、青海、四川、西藏四省区的33份垂穗披碱草Elymus nutans材料进行醇溶蛋白分析,获得下述结果:（1）供试材料共分离出38条带纹,多态率达92.10%。4个电泳分区（α、β、γ、ω）的平均Shannon指数为0.55,Nei-Li遗传相似系数（GS）变异范围为0.36~0.93,平均值为0.63。这些结果说明供试野生垂穗披碱草材料具有较为丰富的醇溶蛋白遗传多样性。（2）对所有材料的聚类分析和主成分分析发现,在GS值为0.67的水平上供试材料可聚成7个类群,绝大部分来自于相同或相似生态地理环境的材料聚成一类,即醇溶蛋白图谱类型与材料的生态地理环境具有一定的相关性。（3）基于Shannon 多样性指数估算了5个垂穗披碱草地理类群内和类群间的遗传分化,发现类群内遗传变异占总变异的42.94 %,而类群间的遗传变异占总变异的57.06 %。这可能与该草以自花传粉为主的繁育系统有关。（4）对各地理类群基于Nei氏无偏估计的遗传一致度的聚类分析表明,各地理类群间的遗传分化与其所处的地理生态环境具有较高的相关性。 .     

基于SRAP和TRAP标记的河北野生狗牙根种质遗传多样性分析

以SRAP和TRAP 2种标记技术对36份狗牙根材料的遗传多样性及亲缘关系进行了分析,其中包含34份河北省野生狗牙根种质资源。分别由238对SRAP和85对TRAP引物组合中筛选获得具有多态性的SRAP和TRAP引物组合各10对,PCR扩增总条带分别为186和161条,多态性条带156和132条,平均每对引物扩增出多态性条带各15.6和13.2条,多态性位点比率分别为83.4%和81.0%。2种标记合并进行聚类分析,所有供试的36份狗牙根材料遗传相似系数GS=0.519~0.983,平均为0.7。当GS=0.68时,可将36份供试材料分为4个类群。本研究结果表明河北野生狗牙根种质资源存在较丰富的遗传多样性,可为种质资源保护和选育优良狗牙根新品种提供科学依据。     

中国西南区扁穗牛鞭草种质遗传多样性的SRAP分析

本研究采用SRAP标记对主要来自中国西南地区(四川,重庆,贵州和云南)的43份扁穗牛鞭草种质资源的遗传多样性进行了分析。试验筛选出了11对引物组合对43份供试材料进行扩增,共获得153条带,其中多态性条带140条,多态性条带比率为91.50%,平均每对引物扩增出条带13.91,多态性条带12.73。实验数据结果表明,43份扁穗牛鞭草材料间的遗传相似系数(GS)为0.565～0.992,平均值为0.723,表现出了丰富的遗传多样性。聚类分析结果表明,各供试材料间的聚类与其地理来源以及形态特征类型具有一定的相关性。同时,主成分分析结果能够直观的反映了各种质间的遗传关系。5个扁穗牛鞭草地理类群间的分子方差分析(AMOVA)揭示了供试的扁穗牛鞭草总遗传变异的85.99%存在于类群内,仅有14.01%的变异存在于类群之间,类群间的分化系数ΦST=0.140。本研究结果为扁穗牛鞭草种质的收集、利用及育种提供了理论依据。     

鹅观草种质资源醇溶蛋白遗传多样性研究

以8个地理类群的90份鹅观草野生种质材料为研究对象,采用A-PAGE(酸性聚丙烯酰胺)凝胶电泳技术进行蛋白质水平遗传多样性检测.研究结果表明,来源于不同居群的鹅观草共分离出26条谱带,每个材料可以分离出5～26条迁移率不同的谱带, 平均谱带数为16.39条,其中平均多态性谱带为12.65条,多态性比例为77.22%;基于供试材料醇溶蛋白每个位点谱带出现的频率,分别计算了地理类群内多样性指数(0.345)和总多样性指数(0.471),类群间的遗传分化系数为26.8%,表明鹅观草变异的73.2% 来源于类群内;90份供试材料醇溶蛋白的Jaccard遗传相似系数变异范围为0.133 3～1.000,平均遗传相似系数为0.395 7;利用种子醇溶蛋白可将90份材料分为12类,鹅观草种质资源之间的亲缘关系呈现出一定的地域性规律;不同地理类群间的遗传多样性指数从高到低的排列顺序依次为云南＞四川＞内蒙古＞新疆＞山西＞甘肃＞宁夏＞河北.因此在进行鹅观草种质资源收集和原地保护时,建议对云南和四川地区的鹅观草种质资源应给予极大关注.     

野生垂穗鹅观草醇溶蛋白遗传多样性研究

利用酸性聚丙烯酰胺凝胶电泳(Acid-polyacrylamidegel electrophoresis)法对来源于内蒙古、山西、甘肃、新疆、云南、四川和西藏的25份垂穗鹅观草材料进行醇溶蛋白检测。研究结果表明,供试材料可分离出30条相对迁移率不同的谱带,每份材料可电泳出11～22条谱带,其中只有1条(3.45%)带纹是25份材料共有的,其余29条谱带均具有不同程度的多态性,多态性谱带数目占分离出总条带的96.67%,说明野生垂穗鹅观草具有较丰富的遗传多样性。聚类分析发现,材料的遗传相似系数(GS)变异范围为0.111～0.9286,平均值为0.4821。在GS值为0.4821的水平上供试材料可聚为6个类群,某些具有相同地理来源的材料聚成一类或亚类,即醇溶蛋白图谱类型与材料的生态地理环境具有相关性。     

望春玉兰种质资源遗传多样性ISSR分析

利用ISSR分子标记法对陕西、河南、湖北三省共35份具有代表性的单株野生望春玉兰种质进行遗传多样性和亲缘关系分析。从100条ISSR引物中筛选出来的10条多态性引物对供试材料进行PCR扩增后共获得154条条带,其中多态性条带143条(PPB=93.5%);根据ISSR扩增结果,35份材料间的遗传相似系数(GS)为0.55~0.87;Nei’s遗传多样度(H)为0.274 7;Shannon多态信息指数(I)为0.427 4;不同地区间的遗传分化系数(Gst)为0.1291。以上说明望春玉兰种质存在较丰富的遗传多样性,不同地区间和地区内均存在遗传分化,且地区内的变异对总变异的贡献相对较大。基于UPGMA法的聚类分析将35份供试材料分为四大类,其结果呈现出一定的地域性分布规律,与花色并无绝对关联。主成分分析结果基本支持聚类分析的结果。基于遗传距离和地理距离的Mantel检测显示,望春玉兰供试材料之间的遗传关系与它们的地理来源并无严格的一致性关系。     

内蒙古典型草原羊草种群遗传分化的RAPD分析

运用 RAPD技术对内蒙古典型草原不同生境 8个羊草种群进行分析。采用 2 4个随机引物 (10 nt)在 8个种群中共检测到2 2 4个扩增片断 ,其中多态性片断 173个 ,总的多态位点百分率达 77.2 % ,特异性片断 2 2个 ,占 9.82 % ,平均每个引物扩增的DNA带数为 9.3 3条。利用 Nei指数和 Shannon指数估算了 8个种群的遗传多样性 ,并计算种群相似系数和遗传距离 ,运用UPGMA法进行聚类分析。结果表明 :羊草大部分的遗传变异存在于种群内 ,只有少部分的遗传变异存在于种群间 ,Nei指数和Shannon指数计算结果分别为 85.4%和 66.8% ;羊草不同种群的遗传多样性存在差异 ;8个羊草种群平均遗传距离为 0 .2 3 16,变异范围为 0 .1587～ 0 .2 70 0 ,说明 8个羊草种群间的遗传变异不大 ,即 :在较小地理范围内羊草的遗传分化程度较小 ;8个种群可聚为 3个类群 ,聚类结果显示生境相似的种群能够聚在一起 ,而地理距离最近的种群不一定归为一类 ,说明小范围内羊草种群间的遗传分化与地理距离不存在相关性 ,而与其生境间的相似度相关。影响遗传相似性的不是单一因子而是各种因子的综合作用 ,较小地理范围内羊草种群间的遗传分化主要是由环境的异质性所引起的     

鸭茅种质遗传变异及亲缘关系的SSR分析

利用SSR标记技术对来自世界5大洲的53份鸭茅(Dactylis glomerata L.)材料的遗传变异及亲缘关系进行了研究。用筛选的15对引物对53份材料的DNA进行PCR扩增, 获得下述结果: (1)15个位点共检测到127个等位基因, 每个位点等位基因变幅为5～12个, 平均为8.5个, 多态性位点率 (P)平均为95.21%; 多态性信息含量(PIC)范围为0.30(A04C24) 到 0.44 (A01F24), 平均为0.36; (2)材料间遗传相似系数(GS)范围在0.43到0.94之间; 地理类群间的GS值在0.73到0.91间, 其中亚洲(P,90.55%)和欧洲(P,86.61%)类群遗传多样性丰富, 表明供试鸭茅种质具有丰富的遗传变异; (3)根据研究结果进行聚类分析和主成分分析, 可将53份鸭茅材料分成5大类, 来自相同洲的材料能聚为一类, 呈现出一定的地域性分布规律。     

柴达木地区野生黑果枸杞种群遗传多样性的AFLP分析

采用扩增片段长度多态性(AFLP)分子标记技术对青海省柴达木地区5个野生黑果枸杞(Lycium ruthenicum)种群的120份样品的遗传多样性进行分析。结果表明: 柴达木地区野生黑果枸杞具有很高的遗传多样性, 9对选扩引物共得到1691条清晰条带, 其中多态性条带1678条, 多态性变异率为99.23%, 种群间的有效等位基因数为1.4712, Nei’s基因多样性为0.3245, Shannon信息指数为0.4367。分子方差分析(AMOVA)结果表明: 柴达木地区5个黑果枸杞种群的遗传变异主要存在于种群内部(92%), 种群间的遗传分化较小(8%, 遗传分化系数0.08)。黑果枸杞种群间的遗传相似系数介于0.9709-0.9922之间, 平均值为0.9835。种群间的聚类及Mantel检验(γ = 0.3368, p = 0.8064)均表明柴达木地区黑果枸杞种群地理距离与遗传距离之间的相关性不明显; 黑果枸杞个体间的聚类表明同一种群的个体不能完全聚在一起。对同一种源的遗传多样性分析发现, 诺木洪奥斯勒草场的种源内部的遗传变异更为丰富, 这或许可以推断诺木洪可能为柴达木地区野生黑果枸杞种质资源的中心产区。     

Diversity among Cynodon accessions and taxa based on DNA amplification fingerprinting.

The genus Cynodon (Gramineae), comprised of 9 species, is geographically widely distributed and genetically diverse. Information on the amounts of molecular genetic variation among and within Cynodon taxa is needed to enhance understanding of phylogenetic relations and facilitate germplasm management and breeding improvement efforts. Genetic relatedness among 62 Cynodon accessions, representing eight species, was assessed using DNA amplification fingerprinting (DAF). Ten 8-mer oligonucleotides were used to amplify specific Cynodon genomic sequences. The DNA amplification products of individual accessions were scored for presence (1) or absence (0) of bands. Similarity matrices were developed and the accessions were grouped by cluster (UPGMA) and principal coordinate analysis. Analyses were conducted within ploidy level (2x = 18 and 4x = 36) and over ploidy levels. Each primer revealed polymorphic loci among accessions within species. Of 539 loci (bands) scored, 496 (92%) were polymorphic. Cynodon arcuatus was clearly separated from other species by numerous monomorphic bands. The strongest species similarities were between C. aethiopicus and C. arcuatus, C. transvaalensis and C. plectostachyus, and C. incompletus and C. nlemfuensis. Intraspecific variation was least for C. aethiopicus, C. arcuatus, and C. transvaalensis, and greatest for C. dactylon. Accessions of like taxonomic classification were generally clustered, except the cosmopolitan C. dactylon var. dactylon and C. dactylon var. afganicus. Within taxa, accessions differing in chromosome number clustered in all instances indicating the 2x and 4x forms to be closely related. Little, if any, relationship was found between relatedness as indicated by the DAF profiles and previous estimates of hybridization potential between the different taxa.     

用扩增片段的长度多态性分子标记探讨盾叶薯蓣的遗传多样性

用扩增片段的长度多态性(amplified fragment length polymorphism,AFLP)标记分析研究了中国5个盾叶薯蓣居群30个个体的遗传多样性。筛选出9对AFLP引物,从中检测到14698条清晰可见的条带,其中多态性带12628条,多态性比率85.92%。Shannon信息指数(I)为0.3656±0.1721,物种水平的Nei基因多样性(H)为0.2322±0.2200。遗传变异分析表明,物种水平的遗传分化系数Gst为0.4827,说明其群体间存在一定的遗传分化,居群间的基因流Nm为0.5358,居群间遗传交换较小。聚类分析结果显示5个居群盾叶薯蓣有较为丰富的遗传变异,且与地理分布有相关性。     

用ISSR标记检测黄麻野生种与栽培种遗传多样性

利用ISSR标记对黄麻属((Corchorus)10个种27份材料的遗传多样性进行分析,25个ISSR引物共扩增出283条带,平均每个引物扩增出10．48条带,多态性条带比例(PPB)为92．85％;种间遗传相似系数在0．33～0．97之间。表现出丰富的遗传多样性．系统聚类结果显示,第I、Ⅲ类群均为黄麻属8个种11份原始野生种,种间存在丰富的遗传多样性;第Ⅱ类群为黄麻两个栽培种及其近缘野生种,共16份材料。种遗传相似性较高;基因组聚类结果与经典分类相符．利用分子标记技术研究初步可以认为。荨麻叶种为最原始的黄麻野生种之一;三室种21C为三室种的一个变种;甜麻为一个尚待定性的野生种．同组材料的RAPD和ISSR分析结果,具有较高的相似性和可信度．     

中国狗牙根(Cynodon dactylon)优良选系的RAPD分析

对采自中国不同地区的6份狗牙根[Cynodon dactylon (L.) Pers.]优良选系进行了RAPD分子标记实验.选用15个引物共扩增出438条带,平均每个引物扩增出29条带,其中多态性带415条,多态性位点百分率达到59.02%～75.49%.各选系间遗传相似性系数差异较大(0.408～0.672),说明各选系间在DNA水平上存在着丰富的遗传多样性,与新品种C106(爬地青)相比,各选系还存在一定的改良空间.实验结果也表明,RAPD分子标记可成功地用于中国狗牙根优良选系遗传多样性的研究及品种鉴定.     

Analysis of the Genetic Structure of Sclerotinia sclerotiorum (Lib.) de Bary Populations from Different Regions and Host Plants by Random Amplified Polymorphic DNA Markers

The genetic diversity and genetic structure of a population of isolates of Sclerotinia sclerotiorum (Lib.) de Bary from different regions and host plants were investigated using the random amplified polymorphic DNA (RAPD) method with 20 random decamer primer pairs in order to provide some information on the phylogenetic taxa and breeding for resistance to sclerotinia stem rot. A minimum of three and a maximum of 15 unambiguously amplified bands were generated, furnishing a total of 170 bands ranging in size from 100to 3 200 bp, corresponding to an average of 8.5 bands per primer pair. One hundred and four of these 170bands (61.2%) were polymorphic, the percentage of polymorphic bands for each primer pair ranging from 0.0% to 86.7%. The genetic relationships among the isolates, based on the results of RAPD analysis, were examined. The genetic similarity of all selected isolates was quite high. At the species level, the genetic diversity estimated by Nei's gene diversity (h) was 0.197 and S hannon's index of diversity (I) was 0.300. The unweighted pair-group mean analysis (UPGMA) cluster analysis showed that most isolates from the same regions were grouped in the same cluster or a close cluster. The population of isolates from Hefei (Anhui Province, China) was more uniform and relatively distant to other populations. The Canadian population collected from carrot (Daucus carota var. sativa DC.) was relatively close to the Polish population collected from oilseed rape (Brassica napus L.) plants. There was no relationship between isolates from the same host plants. An analysis of molecular variance (AMOVA) revealed that the percentage of variance attributable to variation among and within populations was 50.62% and 49.38%, respectively. When accessions from China, Europe, and Canada were treated as three separate groups, the variance components among groups,among populations within groups, and within populations were -0.96%, 51.48%, and 49.47%, respectively.The genetic differentiations among and within populations were highly significant (P ＜ 0.001). Similarly, the coefficient of gene differentiation (Gst) in total populations calculated by population genetic analysis was 0.229 4, which indicated that the genetic variation among populations was 22.94%. The gene flow (Nm)was 1.68, which indicated that the gene permutation and interaction among populations was relatively high.     

AFLP analysis of Cynodon dactylon (L.) Pers. var. dactylon genetic variation.

Cynodon dactylon (L.) Pers. var. dactylon (common bermudagrass) is geographically widely distributed between about lat 45 degrees N and lat 45 degrees S, penetrating to about lat 53 degrees N in Europe. The extensive variation of morphological and adaptive characteristics of the taxon is substantially documented, but information is lacking on DNA molecular variation in geographically disparate forms. Accordingly, this study was conducted to assess molecular genetic variation and genetic relatedness among 28 C. dactylon var. dactylon accessions originating from 11 countries on 4 continents (Africa, Asia, Australia, and Europe). A fluorescence-labeled amplified fragment length polymorphism (AFLP) DNA profiling method was used to detect the genetic diversity and relatedness. On the basis of 443 polymorphic AFLP fragments from 8 primer combinations, the accessions were grouped into clusters and subclusters associating with their geographic origins. Genetic similarity coefficients (SC) for the 28 accessions ranged from 0.53 to 0.98. Accessions originating from Africa, Australia, Asia, and Europe formed major groupings as indicated by cluster and principal coordinate analysis. Accessions from Australia and Asia, though separately clustered, were relatively closely related and most distantly related to accessions of European origin. African accessions formed two distant clusters and had the greatest variation in genetic relatedness relative to accessions from other geographic regions. Sampling the full extent of genetic variation in C. dactylon var. dactylon would require extensive germplasm collection in the major geographic regions of its distributional range.     

利用RAPD标记分析大麦种质资源的遗传多样性

利用RAPD标记对19份西藏近缘野生大麦材料、33份我国不同省市的地方品种以及8份国外引进大麦品种共60份大麦种质资源的遗传多样性进行检测.结果表明材料间遗传差异明显.32个RAPD引物中,有25个引物(占78.13%)可扩增出清晰且具多态性的条带,另外7个引物能扩增出1～3条清晰但无多态性的条带.每个引物可扩增出1～8条多态性带,平均为3.72条.32个引物共产生119条DNA片段,其中87条具有多态性,多态性比率(PPB)为73.11%,平均多态信息量(PIC)为0.434;每个位点平均有效等位基因数(Ne)为2.304;材料间遗传相似系数GS变化范围为0.757～0.981,平均值为0.871.19份来源于西藏的近缘野生大麦材料间GS值变幅为0.818～0.969,平均为0.892;33份我国栽培大麦地方品种间的GS值变化范围为0.783～0.981,平均为0.879;8份分别来自8个国家的栽培大麦品种间的GS值变幅为0.820～0.956,平均为0.882.根据RAPD标记分析的结果,对60份大麦种质资源进行聚类分析,在平均GS值0.871水平上60份大麦材料可聚为5类,聚类结果能在一定程度上反应材料的地理分布关系,但某些相同地理来源的材料也较分散地分布在整个聚类树中.本研究从分子水平上进一步证明了我国栽培大麦丰富的遗传多样性,是世界栽培大麦的遗传多样性中心之一.     

38份瓠瓜种质资源遗传多样性的ISSR分析

采用ISSR分子标记技术对源自中国7个省份的38份瓠瓜种质进行遗传多样性分析。12个ISSR引物共扩增出96条多态性带,平均每个引物扩增的多态性带数为8条,多态性比率平均为83.5%。聚类分析将供试的38份种质分为4个类群8组,主坐标分析将其分为4个类群10组。ISSR分子标记的分类结果与瓠瓜的农艺性状分类和地理分布有一定的相关性。