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.     

云南泸定百合遗传多样性的表型与ISSR分析

用表型变异分析并结合ISSR分子标记对云南境内10个泸定百合(Lilium sargenttiae)居群进行遗传多样性分析。结果显示:(1)云南10个泸定百合居群的7个表型性状的居群间F值在3.26～19.1之间,表型的居群间差异均达到显著或极显著水平;平均表型分化系数为71.22%,居群间变异(59.92%)大于居群内变异(23.42%),说明居群间表型变异是泸定百合居群变异的主要来源。(2)13个ISSR引物共检测到248个多态位点,物种水平上多态位点率98.80%,Nei’s多样性指数和Shannon多样性指数分别为0.265 5和0.413 1;居群内基因多样度(Hs)为0.175 7,居群间基因分化系数(Gst)0.336 7,Mantel检验显示泸定百合居群在地理距离和遗传距离间具有显著相关性(r=0.804 4,P=0.009 9)。研究表明,云南泸定百合的居群间表型和分子水平均具有较高的遗传多样性,居群间的遗传分化较大,并且分化趋势具有明显的地域性。因此,可选择迁地种植对泸定百合进行有效保护。     

北沙柳种质资源居群表型多样性

该研究采用单因素方差分析、巢式方差分析、群落多样性指数分析等方法,以国家北沙柳种质资源库内13个居群的494个无性系为实验材料,通过表型性状(叶面积、叶周长、叶柄长、叶长、叶宽、长宽比、开枝角度、株高和地径)比较分析,探讨居群间和居群内表型分化程度、表型多样性和地理变异,为北沙柳种质资源遗传改良和生产提供理论依据。结果显示:(1)北沙柳表型性状变异丰富,变异系数范围为17.64%~28.79%,平均为22.53%。(2)在13个居群中,居群P2的Simpson、Shannon和Brilliouin平均多样性指数最高,居群P13最低;表型性状中分枝角度多样性指数最大,地径多样性指数最小。(3)表型性状分化系数为0.265 4,即北沙柳种质资源居群间表型变异为26.54%,居群内表型变异为73.46%。(4)主成分分析表明,叶面积、叶周长、叶长、叶柄长和叶宽对分组的贡献率较大;聚类分析将13个北沙柳居群可划分为四组;Mantel检验表明,地理距离与表型距离(欧氏距离)相关性不显著(r=0.192 3,P=0.082)。研究认为,居群内不同无性系的选育是北沙柳定向育种的主要研究方向;边缘居群的表型性状具有形成地理变异的趋势;遗传多样性高是北沙柳适应性强的物质基础。     

云南含笑天然居群的表型多样性分析

为揭示云南含笑天然居群表型变异程度和变异规律,以云南昆明地区天然分布的云南含笑为研究对象,调查了6个居群180个单株的14个表型性状,采用巢式方差分析、变异系数、相关分析、Shannon-Weaver多样性指数分析和聚类分析等方法,分析了居群间和居群内表型多样性.结果表明:(1)云南含笑表型性状在居群间和居群内存在极其丰富的多样性,14个表型性状平均表型分化系数(24.38％)小于居群内变异(75.62％),居群内变异是表型变异的主要来源;14个表型性状的变异系数(CV)在16.20％～60.11％之间,表明云南含笑居群内表型性状离散程度较高.(2)对云南含笑各居群的Shannon-Weaver指数分析表明,云南含笑各居群具有丰富的多样性,总体表型多样性指数为1.772.(3)利用居群间欧氏距离进行的UPGMA聚类分析结果表明,云南含笑6个天然居群可以聚为3类,而且表型性状并没有严格依地理距离而聚类.     

云南岩陀及其近缘种质资源群体表型多样性

为有效保护和持续利用药用植物云南岩陀及其近缘种质资源提供基础数据,采用巢式方差分析和聚类分析等方法对岩陀及其近缘种质资源共4个种(包括变种)的15个居群150个单株16种表型性状进行表型多样性分析.结果表明:不同种间表型性状变异均超过20％,变异由大到小依次为光腹鬼灯檠、岩陀、羽叶鬼灯檠、七叶鬼灯檠;居群间表型性状变异较高,其地上部分干重、单株根状茎数变异较大,变异系数均超过50％;小叶表面毛被状态变异系数为100％、小叶背沿脉柔毛色变异系数为0,因此这些性状为种和变种分类的重要依据;4个种的居群内变异系数均大于居群间,变异主要来源于居群内.种的表型多样性指数相对较高,其中根粗最高,叶表面毛被状态和叶背面沿脉柔毛色最低,总体平均多样性指数为1.39;不同种间表型多样性指数变化在1.23-1.44,岩陀最高,七叶鬼灯檠最低;通过聚类分析可将15个居群分为4类.结果暗示:岩陀及其近缘种质资源的遗传改良应适当地减少抽样居群数,增加居群内的家系数,重视居群内优良单株的选择;种质资源的保护应尽量保护一个居群的完整性.     

贵州核桃种质资源表型性状多样性研究

该研究以贵州省内的3个山脉(乌蒙山、苗岭山和武陵山)、19个核桃和泡核桃实生居群、245棵实生单株为研究材料,对坚果表型性状29个指标的多样性、相关性、聚类及变异进行分析,以揭示贵州核桃资源的表型遗传多样性水平,为贵州核桃资源的保存与利用及核心种质构建提供依据。结果显示：(1)核桃和泡核桃实生居群245份种质资源的18个表型质量性状Simpson指数为0.26～0.82,Shannon-Wiener指数为0.12～1.79;核桃小叶形状多样,易发生顶叶退化,坚果核壳表面特征、坚果形状及核仁皮色多样性丰富。(2)坚果表型变异系数为3.32%～47.67%,平均为21.28%且差异显著(P<0.05),居群间变异系数为9.42%～31.61%且差异显著(P<0.05);居群内和居群间变异均是核桃表型多样性的来源,但坚果性状在居群间差异显著性均高于居群内,说明居群间变异是该区域坚果表型变异的主要来源。(3)3个山脉区域核桃表型均有不同程度变异,其中,苗岭山核桃表型变异程度低,乌蒙山核桃表型变异程度高;UPGMA聚类结果显示,19个核桃实生居群依据贵州山脉区域划分为三类,表明贵州核...     

云南南部野生大叶千斤拔资源遗传多样性的ISSR分析

应用ISSR分子标记技术,对云南南部7个地区的野生大叶千斤拔( Flemingia macrophylla)居群进行了遗传多样性分析。结果表明：云南野生大叶千斤拔具有较高的遗传多样性。在物种水平上,平均每个位点的多态位点百分率(PPL)为94.85％,有效等位基因数(Ne)为1.4627,Nei’s基因多样性指数(He)为0.2815, Shannon’s多样性信息指数(Ho)为0.4337;在居群水平上,PPL ＝43.44％,Ne ＝1.2981,He ＝0.1704,Ho ＝0.2499。基于Nei’ s遗传多样性分析可得出,居群间的遗传分化系数( Gst)为0.3975,表明居群内的遗传变异为60.25％,居群间的遗传变异为39.75％,这说明居群间的遗传分化要低于居群内的遗传分化。根据遗传多样性分析和聚类结果,应在大叶千金拔遗传多样性较高的勐腊易武( MY)、丘北( QB)和宁洱( NE)地区,设立保护点对其进行就地保护。     

普通野生稻（Oryza rufipogon Griff．）的SSR遗传多样性研究

利用SSR标记对分布在我国7个省的17个居群普通野生稻(Oryza rufipogon Griff．)的种质资源进行研究,结果表明：17个居群普通野生稻的遗传多样性有着显著的差异,从UPGMA聚类结果可以看出普通野生稻的遗传多样性与其生态地理分布有显著的相关性,遗传多样性指数高的地区极有可能是栽培稻的起源中心;用筛选出的7对SSR引物对336份：DNA样品进行扩增,得到60条特异条带,在分子水平上进一步证明普通野生稻的起源为两广地区;本研究也表明SSR是进行遗传资源多样性研究的一种切实有效的研究方法。     

珍稀濒危植物金毛狗的SRAP分析

利用SRAP分子标记技术,对7个居群79株金毛狗进行遗传多样性分析。结果表明:10对SRAP引物组合共得到107条扩增条带,多态性条带比率为85.98%,Nei’s基因多样性指数为0.229 6,Shannon’s多样性指数为0.358 6,表明金毛狗居群水平具有较高的遗传多样性;金毛狗7个居群的总基因多样度为0.229 6,居群内遗传多样度为0.135 4,居群间的遗传分化指数为0.410 6,表明有41.06%的变异存在于居群间,有58.94%的变异存在于居群内;居群间基因流为0.717 8,表明居群间基因交流频率较低;遗传一致度和UPGMA聚类分析结果显示,生境条件相似的居群优先聚集,说明金毛狗种质亲缘关系与地理分布相关性不显著。     

灯盏花种质资源群体表型多样性研究

以采集自云南和贵州的21份灯盏花种质资源为材料,观测了它们的群体表型性状特征,并分析了这些表型性状的遗传多样性.结果表明:灯盏花种质资源的表型质量性状在居群内外均有丰富变异,不同质量性状的频率不同,并以多叶型的植株、绿色的茎、疏的茎毛、倒披针型的基生叶、全缘叶、锐尖的叶尖、花色淡紫和黄色的管状花冠口等为代表性表型性状.居群内各数量性状间以单株基生叶数和单株分枝数变异系数较高(均超过50%),而花序直径变异系数最低(18.14%);居群间各表型性状以株高和单序管状花数变异系数较高(52.98%和41.98%),而单株基生叶数和基生叶长变异系数较低(<20%).地理类群间表型分化系数为26.58%,地理类群内表型分化系数为73.42%.灯盏花性状表型多样性指数以株高最高(2.243),以单株分枝数和单株基生叶数较低(1.723和1.874),总体平均表型多样性指数为2.028;不同地理类群的表型多样性指数为1.589~1.890,并以楚雄地区最高,曲靖地区最低.研究发现,灯盏花种质资源具有丰富的质量和数量性状变异,多数性状的地理类群内变异大于地理类群间,且表型多样性指数相对较高,对其地理类群内变异的保护和利用对灯盏花育种具有重要的意义.     

Phenotypic Diversity of Acer ginnala (Aceraceae) Populations at Different Altitude

In this study, we analyzed the phenotypic variation of Acer ginnala natural populations at different altitude in Qiliyu, investigated the level of phenotypic diversity by using ANOVA analysis, correlation analysis and cluster analysis. The results showed that there were significant differences in phenotypic variation among and within populations. Coefficient of variation (CV) varied from 705% to 3812%. High phonotypic diversity (1.9253) occurred within A.ginnala populations, the mean phenotypic diversity index of populations ranged from 1.9022 to 1.9837. Phenotypic differentiation coefficient (VST) among populations (13.79%) was less than that of within populations (86.21%). The variation within populations comprised a majority of total phenotypic variation. A significant relation had occurred between phenotypic traits and soil factors. Phenotypic diversity index had a very significant correlation with soil total nitrogen (P<0.05), no significant relation with altitude. Five populations gathered into two groups by cluster analysis, which consistent with the geographic distribution of Aginnala in Qiliyu. The traits variations of natural populations at different altitude were affected mainly by micro-environmental heterogeneity of different Aginnala populations. Utilizing of variation within and among populations is important significance for genetic improvement of A.ginnala.     

茶条槭不同海拔种群的表型多样性

为了揭示茶条槭（Acerginnala）不同海拔种群表型变异程度和变异规律,以山西七里峪天然分布的茶条槭为研究对象,调查不同海拔种群的种实和叶表型性状,采用方差分析、相关分析、聚类分析等方法,分析种群的表型多样性。结果表明：17个表型性状中16个存在显著差异,占总表型性状的94.12%。在物种水平上各个性状表现出较丰富的变异,变异系数（CV）在7.05%～38.12%之间。茶条槭种群具有高的表型多样性（1.9253）,5个不同海拔种群的平均表型多样性指数为1.9022～1.9837。种群间的表型分化系数均值（13.79%）小于种群内变异（82.71%）,种群内的变异是表型变异的主要来源。各表型性状及表型多样性指数与土壤中的N、K、AN、AK、AP、OR、MC表现出显著或极显著的相关关系（P〈0.05）,但与海拔高度呈现出不显著的相关性。UPGMA聚类分析显示5个种群形成明显的两组,与其地理分布相一致。不同海拔种群所处微生境的异质性是引起种群间差异的主要原因。茶条槭种群内、种群间变异的利用对其遗传改良具有重要的意义。     

内蒙古小花棘豆遗传多样性的ISSR分析

应用ISSR分子标记对内蒙古西部地区小花棘豆（Oxytropis glabra DC.）6个地理种群进行了遗传多样性研究.结果表明：小花棘豆具有较高的遗传多样性;14个引物共扩增出327个位点,物种水平上Nei＇s基因多样性指数为0.1972,Shannon多样性指数为0.3287;种内总基因多样性为0.1976,种群内基因多样性为0.1653,83.67%的遗传变异存在于种群内,16.33%的遗传变异存在于种群间,种群间的遗传分化系数为0.1633,基因流为2.5613,6个种群间有一定遗传分化,但遗传漂变不会引起遗传分化.UPGMA遗传距离聚类结果表明,生态地理条件相似的种群优先聚集.     

SRAP analysis of genetic diversity of nine native populations of wild sugarcane, Saccharum spontaneum, from Sichuan, China

Saccharum spontaneum is a wild sugarcane species that is native to and widely distributed in China. It has been extensively used in sugarcane breeding programs, and is being tested for the development of bioenergy cultivars. In order to provide basic information for the exploitation of this species, we analyzed genetic variation among and within native S. spontaneum populations collected from Sichuan, China. Eighty plants from nine native populations were sampled. Twenty-one sequence-related amplified polymorphism primer pairs generated 235 clearly scorable bands, of which 185 were polymorphic (78.7%). Nei's genetic diversity was 0.2801 and Shannon's information index was 0.4155 across the populations. Genetic diversity parameters, G(ST) value (0.2088) and N(m) value (1.8944), showed that the genetic variation within populations was greater than that among populations. In the cluster analysis, one major grouping was formed by populations from Ya'an and another one by populations from Sichuan basin; a population from Baoxing formed a single cluster. In order to fully comprehend the genetic diversity of cold-tolerant local germplasm in this species, germplasm should be collected from the heterogeneous environments along the northern regions of this species' distribution. The germplasm that we collected should be a valuable resource for Saccharum breeding.     

内蒙古地区刺叶柄棘豆(Oxytropis aciphylla Ledeb.)种群遗传多样性分析

用ISSR分子标记对内蒙古地区刺叶柄棘豆(Oxytorpis aciphylla Ledeb.) 5个地理种群进行了种群遗传多样性分析。结果表明：刺叶柄棘豆种群具有较高的遗传多样性,11个ISSR引物扩增出215条带,总的多态位点百分率为98.14%,Shannon多样性指数I=0.2108,Nei基因多样性指数 H=0.341 6,种内总基因多样性(H_t) 为0.2108,种群内基因多样性(H_s)为0.160 4, 大部分遗传变异(76.11%)的遗传变异存在于种群内, 23.89%的遗传变异存在于种群间。遗传分化系数(Gst)为0.238 9,基因流(Nm)为1.592 9。5个居群间已有遗传分化趋势,遗传漂变不会引起遗传分化。UPGMA遗传距离聚类结果表明, 5个地理种群中,植被类型为荒漠草原的4个种群之间遗传距离较近,与1个荒漠种群距离较远。     

基于ISSR数据探讨卷叶凤尾藓(Fissidens dubius P.Beauv.)遗传多样性

卷叶凤尾藓(Fissidens dubius P.Beauv.)是凤尾藓科凤尾藓属植物,该种分布广泛,形态变异强烈。为了解其遗传多样性及种群遗传结构特点,本研究利用ISSR分子标记对采集于浙江、福建、广西、四川、辽宁5个省区的卷叶凤尾藓14个自然种群的遗传多样性进行了评价。结果显示:筛选出的12对引物共扩增出259条清晰、重复性高的条带,其中多态性位点有248个,多态位点百分率为95.75%;种群总的Nei's基因多样性指数为0.2327,Shannon's信息指数为0.3701,说明卷叶凤尾藓遗传多样性水平较高;14个种群的遗传分化系数(Gst)为0.7078,种群间的基因流(Nm)为0.1864,表明大部分遗传变异(72.01%)存在于种群间,27.99%的遗传变异存在于种群内,即卷叶凤尾藓种群间遗传分化明显。基于ISSR数据的聚类分析表明,在遗传距离50为分组阈值处,14个种群可被分为6组(G1~G6):G1为来自于浙江省不同采集地点的8个种群(JHBS除外);G2由浙江金华北山种群(JHBS)组成;G3包括福建武夷山(WYS)和天宝岩种群(TBY);G4、G5、G6分别由广西龙胜县花坪种群(GX)、四川龙池种群(LC)、辽宁白石砬子保护区种群(BSLZ)组成,表明卷叶凤尾藓种群间的遗传分化主要由地理距离造成,种群内的遗传分化可能与其生境的异质性有关。     

岷江柏天然种群种实表型变异特征

运用巢式方差分析、变异系数、表型分化系数和聚类分析等多种分析方法,研究了11个岷江柏种群的13个种实表型性状在种群内和种群间的变异及其与环境因子间的关系,并对其进行了类群划分.结果表明: 岷江柏种实表型性状在种群间和种群内均存在显著差异,种群内的变异(49.7%)大于种群间的变异(28.6%),种间平均分化系数为43.4%,分化程度相对较大.球果质量的平均变异系数最高(37.2%),其次是单个球果种子质量,球果长的平均变异系数最小(8.0%),是最稳定的种实性状.康定县的表型多样性最丰富,武都县的最小.在岷江柏的研究区内,最热月的平均气温和生长季的水分条件是其种实表型的主要限制因子.依据13个种实表型性状将11个岷江柏天然种群分为2类3亚类,基本上代表了3个流域的种群分布情况.大渡河流域种群种实表型性状最佳,岷江流域最差.     

Patterns of isozyme variation in relation to population size,isolation, and phytogeographic history in royal catchfly (Silene regia; Caryophyllaceae)

The distribution of genetic variation within and among plant populations is influenced by both contemporary and historical factors. I used isozyme analysis of band phenotypes to examine genetic structure in the rare prairie forb Silene regia. Relationships between current-day population size, isolation, and phenotypic variation were assessed for 18 populations in two regions with differing postglacial history. Western populations from unglaciated southern Missouri and Arkansas were more genetically diverse based on the Shannon-Weaver index (H) and a polymorphic index than were more eastern populations. These differences may be due to loss of variation with repeated founding of new populations in previously glaciated sites in Indiana and Ohio. Within the western region, population size was not significantly correlated with genetic variation. In the east, size was correlated with Shannon-Weaver diversity. There was no relationship between variation and isolation in either region, but eastern populations were slightly more differentiated. Greater among-population differentiation and the demonstrated connection between population size and variation in the eastern sites may reflect lower levels of interpopulation gene flow in the fragmented remnant prairies of Indiana and Ohio.     

大别山山核桃种群遗传多样性研究

为了更有效地保护和合理开发大别山山核桃(Carya dabieshanensis)资源,该文利用RAPD分子标记技术,对3个天然大别山山核桃种群的90个单株的遗传多样性、种群内和种群间的遗传变异进行了研究,结果表明:20对10 bp随机引物共检测到238条谱带,其中多态带为162条,占68.1%。遗传多样性分析结果显示: Shannon多样性指数为0.476 1,58.18%的变异分布于群体内,而种群间变异占了41.82%;Nei指数群体总基因多样度为0.314 5,群体内平均基因多样度(H_S)为0.186 5,群体间的基因多样度(H_ST)为0.128 0,群体Nei基因分化系数(G_ST)为0.406 7,说明40.67%的变异存在于种群间,群体内的变异占了总变异的59.33%,与Shannon多样性指数相比基本一致,均表明种群内有较丰富的遗传变异,这为优良品种选育提供广阔前景;种群间的基因流(N_m)为0.730 6,证明种群间遗传交换较小,这与环境适应性和高山阻隔有一定的关系。     

Global analysis of regional differences in craniometric diversity and population substructure.

Estimates of genetic diversity in major geographic regions are frequently made by pooling all individuals into regional aggregates. This method can potentially bias results if there are differences in population substructure within regions, since increased variation among local populations could inflate regional diversity. A preferred method of estimating regional diversity is to compute the mean diversity within local populations. Both methods are applied to a global sample of craniometric data consisting of 57 measurements taken on 1734 crania from 18 local populations in six geographic regions: sub-Saharan Africa, Europe, East Asia, Australasia, Polynesia, and the Americas. Each region is represented by three local populations. Both methods for estimating regional diversity show sub-Saharan Africa to have the highest levels of phenotypic variation, consistent with many genetic studies. Polynesia and the Americas both show high levels of regional diversity when regional aggregates are used, but the lowest mean local population diversity. Regional estimates of F(ST) made using quantitative genetic methods show that both Polynesia and the Americas also have the highest levels of differentiation among local populations, which inflates regional diversity. Regional differences in F(ST) are directly related to the geographic dispersion of samples within each region; higher F(ST) values occur when the local populations are geographically dispersed. These results show that geographic sampling can affect results, and suggest caution in making inferences regarding regional diversity when population substructure is ignored.