松嫩平原中部地区羊草种群的遗传结构研究

松嫩平原中间地区的羊草,依其生长的微环境不同可分成灰绿色和黄绿色两种叶色类型的种群。移栽实验表明,这两类种群实际上是灰色和灰绿色两种类型的混生群体。采用淀粉凝胶电泳技术及等位酶分析方法测定了不同生境、不同分类种群的遗传结构,发现羊草种群遗传变异度很高;但是无论如何归属,这一草原区域上的羊草种群遗传分化程度很低（ＦＳＴ≤０．０３４）。这可能与羊草与异花授粉、不同类型混生及种群间基因流强度大有关。     

微生境下羊草两种生态型种群的遗传多样性及遗传分化——等位酶分析

采用水平淀粉凝胶电泳技术,应用等位酶分析方法测定了松嫩平原南部微生境条件下羊草灰绿色和黄绿色两种生态型９个种群的遗传多样性和遗传分化程度。羊草种、种群和生态型水平都维持较高的遗传多样性。两种生态型之间有明显的遗传多样性差异及遗传分化。灰绿型和黄绿型的多态位点百分率分别为６７．３％和５７．１％,等位基因平均数分别是２．２和１．９,期望杂合度分别为０．３４８和０．２９８。两种生态型种群之间平均遗传距离     

松嫩草原羊草种群遗传分化的研究

通过等位酶技术, 综合分析了松嫩平原11 个羊草种群的遗传多样性及遗传分化指标, 深入剖析了灰绿型和黄绿型两种叶色类型羊草种群之间的遗传差异:两类种群在等位基因频率、非平衡位点和A、P、He 及固定指数F 上明显不同, 两类种群间有极明显的遗传分化。黄绿型种群的A、P、He 皆低于灰绿型;黄绿型F < 0, 灰绿型F > 0, 这种差异主要表现在DIA-1、PGM、SKD 和ACP 等位点上;两类种群间的遗传分化主要发生在ADH、DIA-2 和PGM 等位点上。种群间的遗传距离与地理距离之间没有相关。     

松嫩草原羊草种群遗传分化的研究

通过等位酶技术,综合分析了松嫩原理１１个羊草种群的遗传多样性及遗传分化指标,深入剖析了灰绿型和黄绿型两种叶色类型羊草种群之间的遗传差异：两类种群在等位基因频率、非平衡位点和Ａ、Ｐ、Ｈe及固定指数Ｆ上明显不同,两类种群间有极明显的遗传分化。黄绿型种群的Ａ、Ｐ、Ｈe皆低于灰绿型;黄绿型Ｆ＜０,灰绿型Ｆ＞０,这种差异主要表现在ＤＩＡ－１、ＰＧＭ、ＳＫＤ和ＡＣＰ等位点上;两类种群间的遗传分化主要发生在ＡＤＨ、ＤＩＡ－２和ＰＧＭ等位点上。种群间的遗传距离与地理距离之间没有相关。     

羊草种群克隆多样性的初步研究

 采用水平淀粉凝胶电泳技术检测了松嫩草原上两种叶色类型(灰绿型和黄绿型)羊草(Leymus chinensis)种群的克隆多样性。羊草种群中克隆多样性较高,Simpson指数平均为0.983,97.7% 的基因型为局部分布;在克隆特性上,灰绿型和黄绿型羊草也明显不同,黄绿型种群的克隆多样性低于灰绿型。由基株数据计算的种群遗传多样性与由分株计算的结果一致,进一步确认了黄绿型和灰绿型羊草间存在着明显的遗传分化。种群中不时有实生苗补充及环境异质性引起的分化选择作用可能是维持种群内基因型多样性的重要因素。     

羊草遗传多样性的研究

本文运用光镜和电镜技术,对不同土壤条件下７个羊草种群营养体形态结构进行了观察,在此基础上,运用ＲＡＰＤ技术,对７个羊草种群的遗传多样性进行了研究,分析了遗传多样性与环境因子的相关关系。结果表明：１）７个羊草种群根的结构与盐碱土型羊草结构相似;茎的结构与黑钙土型羊草结构相似;叶的结构呈现黑钙土型羊草结构和盐碱土型羊草结构之间的过渡类型。２）羊草种群的遗传多态性非常高,５３个引物在７个羊草种群中共检测到３６５条扩增片段,多态带３０３条,多态率达到８３．０１％。特有带１２１条,占３３．２１％。３）７个羊草种群之间的遗传距离变异范围为０．２３４９－０．６１６６,聚类分析表明这７个种群可分子为３组。４）多态位点百分数与土壤有机质、全氮含量呈现比较大的负相关;特有带百分数与土壤镁离子、钙离子呈现较大的负相关;遗传距离值与土壤的电导率、水溶性钠离子呈现较大的正相关。     

内蒙古中东部不同草原地带羊草种群遗传分化

运用 RAPD技术对内蒙古不同草原地带分布的 5个羊草种群 (共 10 0个个体 )的遗传多样性进行分析。 31个随机引物(10 nt)在 5个羊草种群中共检测到 4 96个扩增片断 ,其中多态性片断 4 89个 ,总的多态位点百分率达 98.6 %。利用 Nei指数和Shannon指数估算了 5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 :无论是种群内还是种群间 ,羊草均存在较高的遗传变异 ,大部分的遗传变异存在于种群内 (Nei指数和 Shannon指数估算结果分别为 85 .4 %和 72 .5 % ) ,只有少部分的遗传变异存在于种群间 ;不同种群的遗传多样性存在差异 ,各种群的遗传多样性与其所处的地理位置具有显著的相关性 ;5个种群的平均遗传距离为 0 .5 0 95 ,变异范围为 0 .4 6 84～ 0 .5 4 76 ;聚类分析结果显示地理距离较近的种群遗传距离较小 ,首先聚在一起 ,而地理距离较远的种群遗传距离较大 ,说明羊草种群间的遗传分化与地理距离存在一定相关性 ;但地理距离最近的两个种群并未最先聚集 ,说明羊草种群间的分化还与其生境的异质性有关     

典型草原退化群落不同恢复演替阶段羊草种群空间格局的比较

羊草(Leymus chinensis)为典型草原群落的主要建群种之一, 在群落中扮演着重要角色。应用摄影定位法测定处于不同恢复演替阶段的羊草种群空间格局, 通过点格局、种群空斑、种群领地及种群领地密度等方法分析发现, 羊草种群在恢复演替过程中经历了种群增长和种群衰退的过程。在此过程中, 羊草种群数量出现最高点, 此点之前, 种群拓殖大于自疏, 种群整体增长; 此点之后, 种间竞争及种内竞争致使种群衰退, 而种间竞争占主导地位, 种内竞争相对较弱。羊草种群的增衰导致种群空斑发生变化, 从而引起种群格局类型发生相应的变化, 表现为在恢复21 a的群落中, 羊草种群在10 m×10 m的取样范围内表现出两种格局分布类型: 在0~4.85 m之间呈现聚集分布, 当尺度大于4.85 m时, 则表现为随机分布; 在恢复8 a的群落中, 羊草种群在10 m×10 m的取样范围内出现3种格局分布类型: 在0~3.01 m之间呈聚集分布, 在3.01~3.37 m之间为随机分布, 当尺度大于3.37 m时则表现为均匀分布; 在严重退化群落中, 羊草种群在整个10 m×10 m测定尺度上呈现聚集分布。由此可见, 羊草种群格局在恢复演替过程中是变化的, 这种变化主要由群落剩余资源驱动下的种群拓殖及种内种间竞争所致。     

羊草地下部生态场二维行为的特征分析

通过理论分析与野外实验,本文建立了羊草个体与种群地下部生态场的势函数（生态势）模型,由此模型,分析了羊草个体在不同种群密度状态下,生态势的大小变化,并根据此模型,应用计算机绘制了地下部生态场的二维图形模式。作者从数学模型与图形两个方面分析了;羊草地下部生态场作用大小;不同密度种群的个体生态场生态势变化;羊草地下部生态场的季节性变化等,从而揭示了羊草个体与种群地下部生态场行为的特征、行为变化及其规律性。     

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     

大仓鼠年龄组及性别群体的遗传多样性

本文应用随机扩增多态性DNA (RAPD) 技术, 采用多态位点率、Shannon 信息多样性指数和Nei 遗传多样性指数作为种群遗传变异的指标, 研究了1998 和1999 年大仓鼠种群性别群体和年龄组群体的遗传多样性。主要的结论是: 性别群体间遗传分化较小, 年龄组群体间分化较大; 年龄组相距越大, 遗传分化也就越大; 幼年组的遗传多样性高于老龄组的遗传多样性; 1999 年秋季种群的年龄组遗传分化和差异要比1998 年四季种群更为明显。大仓鼠不同年龄组群体间的遗传分化支持遗传结构由于受时空上的选择压力而产生变异和适应性观点。大仓鼠幼体的遗传多样性比成体和老体的较高, 这一结果倾向于支持Ford 的假说, 说明种群繁殖出的幼体遗传多样性高, 其中有遗传质量好的, 也有遗传质量差的,但在生存过程中, 随着选择压力的作用, 种群趋于适应, 与环境不相适应的类型遭到淘汰,低质的幼体由于自然选择压力的增加而从种群中消失, 致使成年和老年群体多态性逐渐降低。     

五个罗氏沼虾群体遗传多样性的微卫星分析

利用16对微卫星标记对来自泰国(CP)、缅甸(MN)、孟加拉(BD)和中国(MP和DP)的共5个罗氏沼虾群体进行了遗传多样性和遗传结构的分析。结果显示, 16个微卫星位点均具有较高的多态性, 平均等位基因数(N_a)、期望杂合度(H_e)、Shannon信息指数(I)和多态信息含量(PIC)分别为17.563、0.8316、2.1662和0.7328。5个群体的期望杂合度(H_e)介于0.7025—0.8594, 多态信息含量(PIC)介于0.6538—0.8048, 表明所有群体均具有高度遗传多样性, 遗传多样性水平CP>MP>BD>MN>DP。遗传分化指数(F_st)值介于0.03430—0.17333, 表明所有群体间均有不同程度的遗传分化。16个微卫星位点的F_st值均大于0.05, 均值为0.0977, 与群体间有遗传分化相符。AMOVA分析显示群体间变异占总变异的6.22%, 群体内个体间的变异占总变异的40.72%, 个体内部的遗传变异占总变异的53.07%。基于Nei氏遗传距离构建的UPGMA系统进化树显示, MN群体首先与MP群体聚为一类, 再与DP群体聚为一类, 之后再与BD群体聚为一类, 最后与CP群体聚为一类, 表明中国群体与泰国群体亲缘关系较远。遗传结构分析显示, 参试样本被划分为5个理论群体, 除MP群体中个体遗传结构混杂外, 其余群体中个体遗传结构相对独立。研究为罗氏沼虾种质资源的开发利用和优良品种的选育提供了参考数据。     

Microsatellite genetic variation in small and isolated populations of Magnolia sieboldii ssp. japonica

Magnolia sieboldii ssp. japonica, distributed mainly in western Japan, is restricted to high elevation areas (1000-2000 m above sea level) and usually forms small isolated populations. Four microsatellite loci were assayed for 19 populations from six regions spanning the range of distribution, and the levels and distribution of genetic variation were estimated. All four loci were variable, with a total of 39 alleles, but the overall level of microsatellite genetic variation was low, especially compared with a related species, M. obovata. Genetic structure in M. sieboldii was characterised by low intrapopulational genetic variation (A = 3.74 and H(o) = 0.366 on average) and high genetic differentiation even among regional populations. Highly significant isolation-by-distance (IBD) models at the short distance were detected. Genetic drift and limited gene flow was considered to be important in determining the genetic structure within regions. Total genetic differentiation was remarkably high (F(ST) = 0.488 and R(ST) = 0.538), suggesting genetic barriers among regions. Neighbour-joining dendrograms relating the 19 populations, and further analysis on the IBD models, revealed that a stepwise mutation model was more suited than an infinite allele model to explain the genetic differentiation among regions. It is suggested that mutation at microsatellite loci might be influential in generating the genetic differentiation among regions. These results showed the potential of hypervariable microsatellite loci to evaluate the effects of genetic drift and population isolation within regions, and to detect genetic distinctiveness, in spite of the loss of overall genetic variation in M. sieboldii.     

Deep phylogeographic break among Octopus variabilis populations in China: Evidence from mitochondrial and nuclear DNA analyses

The genetic structure of marine populations is greatly influenced by the dispersal ability of the organisms, and it is intuitive that a limited dispersal capability would result in greater genetic differentiation. Octopus variabilis is a typical cephalopod species that shows limited dispersal potential, and previous genetic surveys by a mitochondrial DNA analyses revealed high levels of genetic differentiation among its populations, suggesting the existence of cryptic or subspecies. To test this hypothesis, amplified fragment length polymorphisms (AFLPs) and the cytochrome oxidase II (COII) gene sequence were used to re-evaluate the spatial genetic structure of five populations of O. variabilis along the coast of China. Four distinct groups were identified within these five populations: the Dalian + Qingdao, Zhoushan, Wenzhou, and Dongshan groups. A deep genetic break among the Dongshan, Wenzhou, and other two groups were specifically recognized by both genetic markers. A considerable number of distinct alleles for AFLP and a deep divergence of 13.9–19.4% in the COII gene sequences were found among them, suggesting the occurrence of potential cryptic or subspecies of O. variabilis. A genetic structure of isolation by distance was identified in O. variabilis by a Mantel test, with the geographic distance explaining 62% of the variation in genetic differentiation. This result suggests that gene flow is geographically restricted for this species and that limited dispersal may be the main reason for the genetic differentiation among O. variabilis populations. The present results indicate that special care should be taken in future fishery exploitation and conservation efforts for this species and that conservation management should include populations representing all lineages.     

广东高州7个普通野生稻居群遗传结构的SSR分析

利用32对SSR引物对来自全部7个自然居群的217份广东高州普通野生稻(简称“高野”)材料进行遗传结构、多样性和遗传聚类分析。结果表明, 高野各居群因遗传结构存在差异而相对独立, 但各居群之间由于存在基因渗透又具有一定的相似性。高野总体多样性指数(Ht)为0.65, 居群内的多样性(HS=0.431)略大于居群间的多样性(DS=0.392), 二者差异并不显著。居群间的遗传分化系数(GST)为0.611, 说明高野群体的遗传差异是由居群内和居群间的遗传分化共同作用的结果。其中A、B、E居群间, D、F、G居群间遗传相似性较高, C居群与其它居群之间存在较大差异。根据7个居群的遗传结构, 结合其地理分布状况, 认为遗传多样性最大的B和E居群以及遗传分化最小的C居群应作为重点对象进行保护。     

Landscape genetics and hierarchical genetic structure in Atlantic salmon: the interaction of gene flow and local adaptation

Disentangling evolutionary forces that may interact to determine the patterns of genetic differentiation within and among wild populations is a major challenge in evolutionary biology. The objective of this study was to assess the genetic structure and the potential influence of several ecological variables on the extent of genetic differentiation at multiple spatial scales in a widely distributed species, the Atlantic salmon, Salmo salar . A total of 2775 anadromous fish were sampled from 51 rivers along the North American Atlantic coast and were genotyped using 13 microsatellites. A Bayesian analysis clustered these populations into seven genetically and geographically distinct groups, characterized by different environmental and ecological factors, mainly temperature. These groups were also characterized by different extent of genetic differentiation among populations. Dispersal was relatively high and of the same magnitude within compared to among regional groups, which contrasted with the maintenance of a regional genetic structure. However, genetic differentiation was lower among populations exchanging similar rates of local as opposed to inter-regional migrants, over the same geographical scale. This raised the hypothesis that gene flow could be constrained by local adaptation at the regional scale. Both coastal distance and temperature regime were found to influence the observed genetic structure according to landscape genetic analyses. The influence of other factors such as latitude, river length and altitude, migration tactic, and stocking was not significant at any spatial scale. Overall, these results suggested that the interaction between gene flow and thermal regime adaptation mainly explained the hierarchical genetic structure observed among Atlantic salmon populations.     

Seed bank influences on genetic diversity in the rare annual Clarkia springvillensis (Onagraceae)

The potential for seed banks to significantly affect the genetic structure of populations was recognized nearly two decades ago. However, there has been little empirical work that examines the problem. In this study, we explore the possibility that the seed bank of a rare annual, Clarkia springvillensis, could act as a buffer against the genetic consequences of small population size. We examined the adult and seed bank cohort in three natural populations. The seed bank was surveyed by collecting soil cores twice during the growing season: postgermination and post seed set. The genetic constitution of the adults and seed bank cohort was determined by examining eight polymorphic isozyme loci via starch gel electrophoresis. The total genetic diversity in the seed bank (Ht = 0.355) was significantly higher than in the adults (Ht = 0.260). Additionally, Fst estimates of genetic differentiation among populations showed significantly less differentiation among population seed banks (Fst = 0.008) than among adults (Fst = 0.045). These results are in agreement with the expectation that seed banks would act to maintain genetic diversity in populations as well as have the effect of slowing differentiation of populations.     

鄂尔多斯高原不同生境条件下中间锦鸡儿植物叶片表皮特征及遗传多样性变化分析

该研究在鄂尔多斯高原从东到西按照降雨量逐渐减少的梯度选取了5个地区,对中间锦鸡儿(Caragana davazamcii)叶片的表皮结构进行了比较观察,发现不同生境条件下的中间锦鸡儿由于环境的长期作用表皮表现出一定的差异性,主要表现在随着多年平均降雨量的减少叶片表皮毛密度、气孔密度、气孔指数均有所增加,气孔深陷程度逐渐加深,角质层由光滑变得粗糙,但并不是线性增加,因此本研究对不同生境的中间锦鸡儿植物叶片做了遗传多样性分析,发现随着生境由东向西的变化,中间锦鸡儿种群遗传多样性有增加的趋势,与表皮形态特征变化一致,说明中间锦鸡儿呈现明显的表现型可塑性,可塑性反应比较高。     

中华猕猴桃和美味猕猴桃自然居群遗传结构及其种间杂交渐渗

 利用9对SSR引物对中华猕猴桃（Actinidia chinensis）和美味猕猴桃（A. deliciosa）两近缘种的5个同域分布复合体和各自1个非同域分布居群进行了遗传多样性、居群遗传结构的分析以及种间杂交渐渗的探讨。结果表明：1）两物种共有等位基因比例高达81.13%,物种特有等位基因较少（中华猕猴桃：13.27%,美味猕猴桃：5.61%）,但共享等位基因表型频率在两近缘种间存在差异,而且与各同域复合体中两物种样本的交错程度或间距存在关联;2）两种猕猴桃均具有极高遗传多样性,美味猕猴桃的遗传多样性（H_o＝0 .749, PIC＝0.818）都略高于中华猕猴桃（H_o＝0.686,PIC＝0.799）;3）两猕 猴桃物种均具有较低的Nei’s居群遗传分化度,但AMOVA分析结果揭示种内异域居群间（F_ST=0.091 5）和同域复合体种间（F_ST=0.111 5）均存在一定程度的遗传分化;中华猕猴桃居群遗传分化（G_ST=0.086; F_ST=0.212 1）高于美味猕猴桃（G_ST= 0.080;F_ST=0.142 0）;4）同域分布复合体两物种间的遗传分化（G_ST=0.020）低于物种内异域居群间的遗传分化（中华猕猴桃：G_ST=0.086; 美味猕猴桃：G_ST=0.080）,同域复合体物种间的基因流（N_m＝7.89 -29.75）远远高于 同种异域居群间（中华猕猴桃：N_m =2.663; 美味猕猴桃：N_m=2.880）; 5）居群UPGMA聚类揭示在同一地域的居群优先聚类,个体聚类结果显示多数个体聚在各自居群组内,但各地理居群并不按地理距离的远近聚类,这与Mantel相关性检测所揭示的居群间遗传距离与地理距离没有显著性相关的结果一致。进一步分析表明两种猕猴桃的遗传多样性和居群遗传结构不仅受其广域分布、远交、晚期分化等生活史特性的影响,同时还与猕猴桃的染色体基数高 (x=29)、倍性复杂和种间杂交等因素密切相关,其中两种猕猴桃的共享祖先多态性和同域分布种间杂交基因渗透对两猕猴桃的居群遗传结构产生了重要影响。     

濒危植物长叶榧群体遗传多样性的RAPD分析

借助随机扩增多态DNA方法,分析了中国特有的濒危植物长叶榧的遗传多样性和遗传分化．结果表明：12个随机引物在9个长叶榧自然群体180个样品中可检测到180个可重复位点,其中多态位点119个．长叶榧物种水平的遗传多样性较高,多态位点百分率（P）为66．11％,Shannon信息指数（,）为0．3087,Nei指数（h）为0．2015;而群体水平的遗传多样性较低,P、I和h分别平均为23．76％、0．1221和0．0813．AMOVA分子变异显示,42．57％变异来源于群体内,57．43％变异来源于群体间,群体间的遗传分化系数（Gst）为0．5965,群体间的遗传分化程度高．长叶榧群体间的基因流很低,为0．3382．瓶颈效应、群体隔离和群体间基因流低等因素都加剧了长叶榧群体间的遗传分化．9个长叶榧群体间的平均遗传距离为0．1630．通过UPGMA进行聚类,可将9个长叶榧群体分为浙江和福建两大类群．建议在迁地保护时应尽量避免在群体之间实施种质迁移．