利用SSR标记与毛细管电泳对甘蔗属进行的遗传分析

为探讨甘蔗属内不同种之间的遗传多样性,利用SSR标记与毛细管电泳技术,对来自甘蔗属3个不同种的12个材料19对引物进行检测,共检测到229个DNA多态性条带,19对引物扩增的DNA条带范围集中在100～260bp之间。12个甘蔗材料的Jaccard遗传相似度,最小0.09,最大0.65,平均为0.26。通过遗传相似性系数分析,UPGMA聚类图内12个甘蔗材料可分为两个群,三个割手密种材料分为一个亚群,甘蔗栽培品种与甘蔗热带种合为一个亚群。结果表明:热带种比割手密种具有和甘蔗栽培品种更亲近的遗传关系;SSR分子标记与毛细管技术结合,相比别的分子标记技术或电泳技术,具有更准确、简便、自动化等优点。     

番茄栽培品种SSR标记和形态标记的遗传多样性分析

比较了SSR标记和形态标记在研究番茄栽培品种遗传多样性上的应用。用7对SSR引物检测了11个番茄栽培品种的遗传多样性,共得到53条带,每一个位点上扩增出2-9条带,平均为6条;品种间遗传相似系数在0.39-0.84之间,平均遗传相似系数为0.60。根据11个形态学性状表型值计算的遗传相似系数在0.27-0.72之间,平均遗传相似系数0.58。用UPGMA进行聚类分析,SSR标记和形态标记都可依果肉颜色和果实大小将供试材料分组,即黄色和红色果肉,樱桃小番茄和大、中果形的混合型;两种方法对番茄栽培品种遗传多样性的评价相近。     

29份云南甘蔗创新种质的SSR遗传多样性分析和指纹图谱构建

该研究以16份甘蔗骨干亲本为参照,对29份云南甘蔗创新种质进行SSR指纹图谱构建和遗传多样性分析,以明确创新种质与16份亲本间的遗传基础和多样性水平。结果表明:6对引物共扩增出104条带,其中101条为多态性条带,多态性条带比例为97.25%;45份材料的遗传相似性系数为0.235 3~0.891 3,平均值为0.563 3;其中16份甘蔗骨干亲本的遗传相似性系数为0.301 6~0.755 6,甘蔗创新种质与甘蔗骨干亲本的特异条带比例为14∶1,涵盖了割手密、大茎野生种、斑茅和滇蔗茅等基因源。根据骨干亲本间的相似性系数范围,在相似性系数为0.43处,可将种质分为6大类群,亲缘关系相对较远,适宜作为种质间的杂交利用。通过引物区分效率分析,6对引物扩增的多态信息量为0.967 9~0.975 8,其中MSSCIR21引物区分效率最高,利用MSSCIR21和SMC1047HA引物组合构建了云南甘蔗创新种质标准指纹图谱,在相似性系数为0.85处即可区分所有种质,图谱的鉴别准确率为100%,每份资源都有唯一的指纹图谱,可将29份创新种质和16份骨干亲本区分鉴别出来。该研究能够为后续杂交利用、种质鉴定和知识产权保护提供依据。     

基于SSR分子标记的175份蜡梅种质遗传多样性分析和指纹图谱构建

理清蜡梅品种资源、构建指纹图谱是推动蜡梅科学研究和产业发展的重要基础。利用简单重复序列(simple sequence repeats, SSR)分子标记技术,对鄢陵地区175个蜡梅(Chimonanthus Praecox L.)品种(系)的遗传多样性进行了研究,使用NTSYSpc 2.1软件中的UPDM聚类方法分析品种间的遗传多样性。利用基于贝叶斯模型的Structure v2.3.3软件解析175份种质的遗传结构。通过一般线性模型(general linear model, GLM)对性状和标记进行关联分析。在遗传多样性分析中,平均等位基因数(number of alleles, Na)为6.857,平均期望杂合度(heterozygosity, He)为0.496 3,平均观测杂合度(observed heterozygosity, Ho)为0.503 7,蜡梅Nei’s平均基因多样性指数为0.494 9,平均Shannon信息指数为0.995 8,表明鄢陵地区蜡梅群体内具有较丰富的遗传多样性。群体结构和UPDM聚类分析均表明可将175个品种(系)分为7个类群。在GLM模型中有15个标记位点与8个表型性状显著(P<0.05)关联,表型变异解释范围为14.90%−36.03%。利用11对多态信息含量(polymorphic information content, PIC)最高的引物,构建175份蜡梅品种(系)资源SSR标记的指纹图谱。本研究综合分析了鄢陵地区蜡梅的遗传多样性与SSR分子标记,并构建了蜡梅核心种质资源库,为蜡梅新优品种选育、品种鉴定、资源保护与利用等工作提供理论支撑。     

基于SSR分子标记的地被菊遗传多样性分析和指纹图谱构建

为了从分子水平上研究地被菊(Chrysanthemum×morifolium)种质资源的遗传多样性并建立地被菊品种的指纹图谱库,筛选出多态性高的引物用于地被菊品种间鉴定、亲缘关系分析和分子标记辅助选种体系的建立,本研究利用多态性好、条带清晰、重复性好的12对引物对91份地被菊材料和14份菊属近缘种材料进行简单重复序列(simple sequence repeat,SSR)分子标记和遗传多样性分析,从12对引物中筛选出9对核心引物对受试材料进行指纹图谱构建。结果显示,在105个样品中,12对引物检测出104个等位位点,范围为2−26,平均每个点位检测出9.25个等位基因数,平均每个点位检测得到的有效等位基因数(number of effective alleles,Ne)为2.7456,范围为1.2760−4.7425;Shannon信息指数(Shannon genetic diversity index,I)变化范围是0.5133−2.2399,均值是1.2090;Nei’s基因多样性指数(Nei’s gene diversity index,H)范围是0.2163−0.7891,均值是0.5780;观测杂合度(observed heterozygosity,Ho)的范围是0.2233−0.8952,均值是0.5575;期望杂合度(expected heterozygosity,He)的范围是0.2174−0.7933,均值是0.5808;多态信息含量(polymorphism information content,PIC)值变化范围是0.2115−0.7740,均值是0.5329;遗传相似性系数(genetic similarity,GS)范围为0.2285−1.0000,均值是0.6083。聚类分析表明,在遗传距离(genetic distance,GD)=0.30时,受试材料可以分为两个类群。Structure群体结构分析将受试材料分为3个种群和1个混合种群。从12对引物中筛选出可完全区分105份受试材料的9对核心引物,构建了91份地被菊材料和14份菊属近缘种材料的指纹图谱。地被菊材料之间具有显著的遗传差异和丰富的遗传多样性,对于地被菊的园林应用和品种选育具有重要意义。地被菊品种和菊属近缘种的指纹图谱库的构建,一定程度上揭示了105份实验材料的亲缘关系,为今后地被菊品种鉴定与筛选体系的研究提供了技术支撑。     

用SSR标记分析辣椒属种质资源的遗传多样性

利用21对引物在33个辣椒材料中共检测到54个等位基因,每对SSR引物检测到2~4个等位基因变异,平均为2.6个,说明辣椒种质资源的遗传多样性相对较少。通过MVSP3.13f软件对SSR数据进行聚类分析,把33个辣椒材料分为五类,同个种的辣椒种质资源基本聚在一起,说明用SSR标记来区分辣椒种质是可行的,是研究辣椒种质资源遗传多样性的有效手段。     

云南甘蔗常用亲本资源遗传多样性的SSR分析

以63份云南育种机构常用的亲本资源为研究对象,10份原始亲本种为外群体,使用30对多态性较高,在甘蔗遗传连锁图谱上分布较为广泛的Genomic-SSR引物对云南常用亲本资源开展遗传多样性评价。结果表明：云南常用亲本在30个SSR位点上表现出丰富的多态性,共获得363个扩增条带,其中多态性条带数为352个,平均多态性条带比例和多态信息量分别为96.97%和0.9441;从常用亲本的来源地区来看,大陆亲本的多样性要高于国外亲本和台湾亲本;在Jaccard相似性系数方面,云南常用亲本材料之间的相似性系数范围在0.2804-0.7329之间,平均为0.4309,表现出较大的遗传差异,其中来自大陆地区的亲本遗传差异最大,其次为来自国外地区的亲本;UPGMA聚类分析将所有亲本材料分为一大一小两个类群, 而大类群又可分为2个亚类群,中国大陆地区一些即是主栽品种又是亲本的材料表现出较近的亲缘关系,而引自国外的大部分亲本和一些老的国内自育亲本也表现出较近的亲缘关系。以上结果将为上述亲本资源的高效利用奠定了良好的基础,并为全国育种机构在亲本选择和组合配置提供重要参考。     

无籽西瓜品种SSR指纹图谱构建及遗传多样性分析

利用SSR标记构建了27份中国无籽西瓜主栽品种的DNA指纹并进行了遗传多样性分析。24对多态性引物共扩增出66种基因型,基因型数2-5个不等,平均2.75个。平均多态性信息量(PIC)为0.37,变化范围为 0.19～0.66。有4个品种具有特征谱带。27个品种遗传相似系数变化范围为 0.7045～1.0,平均0.8683。组合24对引物,除无法区分‘郑抗无籽1号’与‘雪峰花皮无籽’,其余品种均能一一区分开。采用类平均法进行聚类分析,在相似系数0.83处,可将27个品种分为3大类。     

基于SSR分子标记的芋种遗传多样性分析

本研究利用SSR分子标记对来自于国家种质武汉水生蔬菜资源圃的110份芋种资源进行了遗传多样性分析.10对SSR引物在110份芋种资源中共扩增得到40条带,多态性百分率为100％,Shannon信息指数范围为0.390 5～1.426 8,反映了这110份芋种资源的遗传多样性程度较高.110份芋种资源遗传相似系数介于0.43～1,在遗传相似系数0.63处,聚类图将其分为6个类群.该研究结果为芋种资源的保护和利用奠定了基础.     

基于SSR标记和生物学性状进行桃遗传多样性的比较分析

利用生物学性状和SSR分子标记对50个桃品种进行遗传多样性研究,并将两种标记所得结果进行比较.14个生物学性状揭示出品种间的遗传相似系数范围为0～0.9,均值为0.4;而13对SSR引物揭示出遗传相似系数范围为0.52～0.97,均值为0.75.对两种标记进行共表型相关系数检测,结果显示两种结果无明显差异.经Mental检测,两种标记之间相关性较差,这可能与形成机理差异大有关.进行聚类和主成分分析,生物学性状方面品种主要分为3个组且与果肉性状相关,而分子方面品种主要分为2组,与地域相关.     

Genetic diversity of SSR markers in wild populations of Tapiscia sinensis,an endangered tree species

Tapiscia sinensis is a Tertiary relict and endangered tree species with unique scientific research value and great economic value. In this study, we assessed the genetic diversity of five wild T. sinensis populations from different geographical regions using 10 polymorphic simple sequence repeat (SSR) markers. Our results reveal that the natural populations of T. sinensis have rich genetic diversity (PPL = 100%, He = 0.6904, I = 1.4368), with Shannon's index indicating that the T. sinensis populations are at a relatively stable stage. Of the genetic relationships among populations, the distance between the Hunan Yanling (YL) and Guizhou Xifeng (XF) populations is the smallest (0.4829); the genetic distance between the Shaanxi Ningshan (NS) and the Guizhou Xifeng (XF) populations is the largest (0.9821). A Mantel test shows that there is no correlation among the populations between geographic distance and genetic distance. AMOVA suggest that 33.3% of the genetic variation arose among the populations, while 66.7% of the variation arose within them. The moderate gene flow among populations (Nm = 0.7274) is not sufficient to counteract genetic drift within the populations and result in significant differentiation (Fst = 0.2987). Our results will benefit the conservation and exploitation of T. sinensis and provide a theoretical basis for further study of the evolution and phylogeography of the species.     

中国香菇主栽品种遗传多样性的SSR分析及指纹图谱构建

【目的】香菇(Lentinulaedodes)是世界第二大食用菌,研究我国现有栽培种群体的遗传多样性和遗传构成以及准确鉴定品种是新品种开发和产业健康发展的基础。【方法】采用多态性的SSR(Simple sequence repeat)分子标记对中国历年来使用主栽品种进行遗传多样性及群体结构分析,比较其谱系来源,解析中国主栽品种的群体多样性构成,并构建指纹图谱用于品种鉴定。【结果】24对多态性SSR引物对51份香菇菌株都具有多态性。聚类分析在相似系数0.69处可将栽培种群体分为4个类群,野生种驯化或参与杂交获得的菌株位于类群Ⅲ和Ⅳ,其他菌株位于另外两个类群Ⅰ和Ⅱ。群体结构分析可将栽培群体分为6个遗传构成,显示L808、L135等代表性菌株在各自的构成中参与了其他菌株的选育过程,解释了以其为亲本的部分品种的谱系来源。依据筛选出的9对条带清晰的SSR引物组合构建了多位点SSR指纹图谱,可对45个香菇商业菌种进行辨识。【结论】我国香菇主栽品种亲缘关系较近,育种多围绕L808、L135、9015等核心代表性品种进行,本研究可为选育具有自主知识产权、适应不同栽培模式的新品种提供依据;指纹图谱的构建也能为香菇品种的准确鉴定提供保证。     

Genetic diversity and population structure of the endangered and medically important Rheum tanguticum (Polygonaceae) revealed by SSR Markers

Rheum tanguticum (Polygonaceae), an endangered plant, is endemic to the Qinghai-Tibetan Plateau. A total of 114 individual of R. tanguticum from 10 geographically separate populations were analyzed using seven pairs simple sequence repeats (SSR) markers. 102 alleles were recorded, with an average of 14.6 alleles per locus (ranging from 13 to 17) and the expected heterozygosity (H_e) ranged from 0.384 to 0.515 (average 0.459). The genetic differentiation between populations was relatively high (F_st = 0.249); the gene flow (N_m = 0.754), however, was limited, which suggested that around 21.18% of the total genetic variations occurred between populations. Our results revealed high levels of genetic variations within and between populations. The endangered status of this species is probably due to harvesting of the wild populations, rather than a lack of the genetic diversity. Anthropologic effects as well as other factors may, together, have shaped the genetic structure of this species.     

The population genetic diversity and pattern of Pteroceltis tatarinowii,a relic tree endemic to China,inferred from SSR markers

Pteroceltis tatarinowii (Cannabaceae), a relic tree endemic to China, is mainly distributed in limestone mountains and has a wide geographical range. In this study, 12 microsatellite primer pairs were assayed to analyse the genetic pattern and gene flow among 461 individuals sampled from 23 wild populations of P. tatarinowii. A high level of genetic diversity was detected based on high values of total alleles (159), the number of alleles (N_A = 6.373), expected heterozygosity (H_E = 0.696) and observed heterozygosity (H_O = 0.679). The high genetic diversity in this species may be attributed to its long‐life history, wide geographical distribution and wind dispersal. Only low genetic differentiation (G_ST = 0.137, F_ST = 0.138) was found among populations. Gene flow (migrants per generation, N_m) was estimated to be 1.56. This moderate level of gene flow possibly decrease interpopulation differentiation by buffering against genetic drift and improving gene exchange. However, spatial genetic structure was detected throughou the sampled range of the species (r = 0.311, p < 0.05) as well as in southern China (r = 0.453, p < 0.05), and may be related to terrain heterogeneity and the demographic history of P. tatarinowii. The east‐west high mountains of southern China might serve as physical barriers to seed and pollen flow. The isolation and local adaptation of different refugia may further limit gene flow. In addition, geographically remote populations might fail to effectively disperse pollen and seeds. Based on the above‐mentioned results, some suggestions for the conservation of the species are presented.     

高粱抗旱种质筛选及遗传多样性的SSR分析

对61份高粱育种材料进行了抗旱性鉴定,旨在筛选既有较好抗旱性能又具较高丰产性能的高粱种质供育种利用。本研究筛选出抗旱性3级以上的材料14份,其中1级抗旱材料2份。选用109对SSR引物对61份高粱种质进行了遗传多样性分析,结果表明51对引物有较好的多态性,共扩增到508个等位变异片段,平均每个标记获得10个等位基因,多态性信息量(PIC)值平均为0.6615,变幅0.0322~0.9134。聚类分析结果表明,61份高粱材料聚成4类,聚类结果与根据地理来源、遗传背景的分类结果基本一致。中国高粱恢复系之间的遗传距离较近,说明我国目前的恢复系材料遗传基础狭窄,应在育种中拓宽恢复系的遗传基础。     

Development of EST-derived SSR markers using next-generation sequencing to reveal the genetic diversity of 50 chrysanthemum cultivars

Chrysanthemum plants are popular worldwide as cut flowers, potted, and in gardens. Several hundred cultivars have been commercialized, indicating that there is substantial genetic variations that can be manipulated under cultivations to produce a wide array of phenotypic variation. To study the genetic diversity of chrysanthemum cultivars in Korea, we first identified simple sequence repeats from chrysanthemum expressed sequence tags generated by FLX 454 sequencing. A total of 1109 ESTs out of 18,226 chrysanthemum ESTs were identified to carry SSRs. A total of 16 out of 46 primer pairs exhibited several polymorphisms among 50 chrysanthemum cultivars. The number of alleles per locus varied from 1 to 15, with an average of 6.25 alleles. The expected heterozygosity ranged from 0 to 0.8958, whereas polymorphism information content ranged from 0 to 0.8872. Based on polymorphisms using 16 SSR markers, a phylogenetic tree was generated revealing four groups within the 50 cultivars showing various levels of genetic diversity. The 16 polymorphic chrysanthemum SSR markers generated in this study would be useful for studies of the genetic conservation, diversity, and population structure of commercial chrysanthemum cultivars as well as closely related species.     

山杨杂种无性系的SSR分子标记遗传多样性

采用5对SSR引物对52个山杨杂种无性系进行了遗传多样性检测,结果表明在研究的5个位点上SSR标记多态位点百分率为100%,平均等位基因数为4.4个,有效等位基因数最多的位点是PTR7,最少的位点为PTR12;欧美山杨杂种的遗传多样性最丰富,相比之下,中美山杨杂种遗传变异最低;聚类分析表明,在一定的遗传距离基础上,欧美山杨杂种和欧洲山杨首先聚为一类,然后又与中美山杨杂种聚类,最后是中国山杨。研究表明来自芬欧美山杨杂种具有较高的遗传多样性,这对我国山杨遗传资源的扩大,以及未来山杨杂交育种,杂种优势的利用都是重要的。     

半野生大豆种质资源SSR位点遗传多样性分析

利用12对SSR引物对67份半野生大豆种质进行了遗传多样性的检测分析,结果表明,12个位点共检测到184个等位基因变异,平均每个位点等位基因数目为15．41个,平均多态性信息量,平均遗传多样性指数,平均遗传距离分别为0．849,0．706,0．118,根据SSR分析结果,按欧式距离将67份半野生大豆种质聚类并划分为5个组群。