大针茅居群遗传分化和RAPD位点多态性分布的分析

利用RAPD分子标记技术对5个居群的90个大针茅个体间的遗传关系以及RAPD多态性与所在生境的相关性进行了研究.16个引物共扩增得到310个RAPD位点,利用几种多元分析方法对所得位点进行分析,结果显示:主轴法分析能够在三维坐标下将90个大针茅个体按居群来源进行分类,前三个轴虽然只解释了总变异的21.91%,却能将所研究的居群完全分开;典范判别分析可以将97.8%的大针茅个体正确地分类到已知居群,且在二维功能轴下能够清晰地看到个体按居群来源进行了分类;Spearman秩相关分析和多元逐步回归分析均得出大针茅RAPD位点的Nei's基因多样性与气候因子(包括年降水量、积温、年均温、一月份均温和七月份均温)之间存在显著的关联性.基于以上结果我们可以得出:大针茅地理居群分化显著;大针茅RAPD多样性并非随机分布而是与生境气候因子相联系;气候差异的自然选择,对大针茅遗传多样性和遗传结构的特点起决定作用.研究结果对大针茅种质资源的保护具有重要的指导意义.     

内蒙古中东部草原区克氏针茅种群遗传分化的RAPD研究

采用 RAPD-PCR技术对内蒙古中东部草原分布的 7个克氏针茅 (Stip a krylovii Roshev.)种群进行了分析。从 10 0个 10碱基随机引物中筛选出 2 1个有效引物 ,共扩增出 2 2 9条稳定的 DNA带 ,其中 171条带具有多态性 ,多态性百分比 (PPB)为74.67%。将每个扩增产物看作一个独立的性状 ,按其有无列出二元数据矩阵 ,计算 Jaccard、简单匹配系数 (SM)和 Dice遗传相似性系数 ,通过 UPGMA法构建分子标记聚类图 ;并通过主成分分析 (PCA)和主轴法分析 (PAF) ,将 7个种群分类 ;统计各个种群特异性 DNA带 ,计算占总扩增条带的百分数。结果表明 :(1)不同地理种群之间扩增结果差异明显 ,具有丰富的遗传多样性 ;(2 )不同地理种群间存在一定程度的分化 ,这种分化是与种群之间的实际距离相联系的 ,相距越远 ,种群相似程度越低 ,进一步分析表明种群的分化是与所处生境逐渐旱化相一致的 ;(3 )聚类图上将 7个种群分为 3类 ,PCA和 PAF分析通过 3个成分或因子也将 7个种群分为 3类 ,支持了聚类图的分类结果 ;(4)特异性位点所占百分比与种群所处生境也有一定的联系 ,它与环境干燥度的相关系数为 0 .76(P<0 .0 5)。     

内蒙古中东部草原区克氏针茅形态特征和RAPD遗传分化的相关性研究

以分布在内蒙古锡林郭勒盟东部草甸草原、中部典型草原和中西部荒漠化草原的4个克氏针茅种群为研究对象,采用形态学标记和RAPD分子标记相结合的方法进行遗传分化研究。结果表明：（1）无论是用形态学数据所得欧氏遗传距离矩阵还是用RAPD所得无偏差的Nei’s遗传距离矩阵,与种群分布的地理距离之间均不存在显著的相关关系,说明克氏针茅种群遗传分化受自然选择的影响。（2）种群之间存在显著的形态分化和遗传分化（p<0.05）。（3）对形态学数据所得欧氏遗传距离矩阵和RAPD所得Nei’s无偏差遗传距离矩阵进行Mantel检验所得结果不显著,表明对克氏针茅形态分化和遗传分化起主要作用的选择力是不完全相同的。     

内蒙古中东部草原大针茅的种群遗传分化

对内蒙古中东部草原区分布的 11个大针茅 (Stipa grandis P. Smirn)地理种群进行了 RAPD分析。从 10 0个随机引物中筛选出 18个有效引物 ,共扩增出 2 2 1条 DNA带 ,多态性 DNA带 12 1条 ,占 5 4 .75 % ,平均每个引物扩增的 DNA带数为 12 .2 8条 ;特异性 DNA带 2 5条 ,占 11.31%。基于 Jaccard遗传相似性系数对此 2 2 1条 DNA带进行 U PGMA聚类分析 ,将 11个种群分为 3类 ,白音锡勒牧场的 8个种群聚为一类 ,林西种群和克什克腾种群两个种群聚为一类 ,阿巴嘎种群单独成为第 3类。用Mantel检验作进一步分析表明 ,在相对较大的尺度上 ,大针茅的遗传分化与地理距离相关极显著 (g>g0 .0 0 5) ;而在相对较小的尺度上 (白音锡勒牧场 8个种群 ) ,相关不显著 (gg0 .0 5)。     

大针茅种群RAPD多样性及其与若干生态因子的相关关系

利用RAPD分子标记,对锡林郭勒草原主要建群种大针茅（Stipa grandis P.Smirn.）5个种群共90个基因株的遗传多样性进行了分析.由16个10碱基随机引物共扩增得到310条清晰可重复的RAPD片段,且全部为多态性条带.利用POPGENE软件对RAPD数据进行分析可以看出,不同地理种群大针茅存在很高的遗传变异,且大部分变异存在于种群之内,只有少量变异存在于种群之间（≈28%）.Pearson相关分析表明,大针茅种群内基因多样性与温度因子（≥10℃年积温、年均温和1月份均温）之间存在显著（p＜0.05）或极显著（p＜0.01）的相关关系;Mantel检验结果显示,大针茅种群间的遗传距离与种群间的实际地理距离之间不存在显著的相关关系（r=0.184,p=0.261）,但与水热因子的分异之间存在显著（p＜0.05）或极显著（p＜0.01）的相关关系.这些都表明水热差异的自然选择引起大针茅种群RAPD标记的生态地理分化,而迁移和遗传漂变对大针茅种群间的分化不起决定作用.     

不同放牧压力下大针茅种群的遗传多样性

大针茅是亚洲中部草原亚区特有的蒙古草原种,以大针茅建群的草原在内蒙古的分布面积为2 798 081hm^2.从遗传多样性上探讨了大针茅种群在放牧压力下的适应机制,结果表明：虽然放牧导致部分基因位点丢失,但整个种群仍表现出丰富的多态性,ISSR检测的多态性条带比率为89%.Nei＇s指数计算的大针茅种群间的遗传分化为0.1984,说明有19.8%的遗传变异存在于种群之间, 80.2%的遗传变异存在于种群内. 由Shannon＇s和Nei＇s多样性指数检测的大针茅种群内遗传多样性随着放牧压力的增加有逐渐减弱的趋势.根据遗传距离构建的UPGMA聚类图中, 中度和重度放牧样地首先聚为一类, 不放牧和轻度放牧样地聚为一类, 随后聚在一起.     

应用RAPD技术研究阿尔卑斯山黄花茅居群内的遗传分化

应用RAPD技术,沿一个海拔梯度研究了阿尔卑斯山黄花茅自然居群的遗传变异和分化。实验 表明,虽然在亚居群间有很少的亚居群独有遗传标记的存在,但通过RAPD资料的聚类分析、主因子分 析以及相关分析观察到遗传分化沿海拔梯度发生,而且亚居群间的遗传分化和它们的海拔高度(地理距 离)呈有意义的正相关。研究结果暗示,在阿尔卑斯山的高山-亚高山过渡区,亚居群间的海拔高度差别 可能导致黄花茅开花和生长物候期的变化,而后者限制了亚居群间的基因流,从而引起居群内的遗传分化。     

内蒙古中东部草原贝加尔针茅、大针茅和克氏针茅的染色体核型分析

以内蒙古草原3种针茅属植物为材料,常规压片法制片后观察记录染色体数,并进行核型分析。实验结果表明: 贝加尔针茅、大针茅和克氏针茅细胞染色体数均为2n=44,属于2A核型,为二倍体。在3种针茅的染色体中,中部着丝粒染色体占大多数平均为62.1%,其次近中部着丝粒染色体平均为28.9%,近端部着丝粒染色体较少约为9.0%。在3种针茅的第五号染色体上均有随体,表明起源于同一祖先。虽然染色体核型均属于较对称型,但是染色体不对称系数随着3种针茅分布生境的干旱程度的增加而逐渐增加,可能是长期适应与进化的结果。     

美国白蛾种群遗传分化的RAPD分析

应用随机扩增多态性DNA(RAPD)技术,对9个不同地理种群美国白蛾进行了遗传多样性和UPMGA聚类分析.结果表明:25个RAPD引物共扩增191个位点,片段大小在200～2000 bp,其中158个是多态位点,多态百分率为82.72%,遗传距离指数在0.2043～0.5108,遗传相似性系数在0.4892～0.7957;9个不同地理种群的美国白蛾可以分成3类:辽宁省和山东类群、北京和天津类群、美国类群,表明美国白蛾不同地理种群间的遗传分化与地理位置相关.     

华东竹黄菌不同居群遗传分化的RAPD分析

为了解竹黄地理居群间的遗传分化,本研究采用随机引物扩增多态性DNA分子标记技术对江苏、安徽和浙江3省的8个居群共32个竹黄样本进行了遗传多样性分析.从50个RAPD引物中筛选得到了5个随机引物,对供试材料的DNA进行扩增,共检测出77个位点,其中多态性位点52个,多态性位点比率为67.53%.UPGMA聚类分析结果表明,这8个居群分为三类:安吉居群、临安居群、宜兴居群、广德居群和泾县居群聚为一类;宁国居群和休宁居群聚为一类;淳安居群单独为一类.遗传多样性分析表明8个竹黄居群中,淳安居群的遗传多样性水平最高,安吉居群的遗传多样性水平最低.Nei's基因多样性指数和Shannon信息指数均表明竹黄物种水平的遗传多样性高于居群水平.     

RAPD diversity of Stipa grandis populations and its relationship with some ecological factors

The genetic diversity of Stipa grandis P.Smirn and its relationship with the climatic variables were studied using the RAPD technique for 90 genes from five natural populations sampled in the Xilingol steppe, China. Sixteen oligonucleotides screened from 100 random primers were used to amplify 310 trackable RAPD loci, which were all polymorphic. By analyzing the RAPD data using POPGENE software, different geographic S. grandis populations were studied, which indicated a high level of genetic diversity, and the maximum variation was observed within the populations with a 28% variation observed among the populations. Using Pearson correlation analysis, significant (P < 0.05) or highly significant (P < 0.01) relationships were found between gene diversity indexes and temperature factors (≥10C cumulative temperature in a year, annual mean temperature and mean temperature in January). Mantel's tests showed that there was no significant correlation between Nei's unbiased genetic distance and the geographic distance of S. grandis populations (r = 0.184, P = 0.261). However, there were significant or highly significant correlations between Nei's genetic distance and the several climatic divergences in pairwise S. grandis populations. All results indicated that natural selection resulting from variations in water and temperature was responsible for the adaptive eco-geographical differentiation indicated by the RAPD markers of different S. grandis populations, and that immigration and gene drift did not play an important role in affecting the differentiation of S. grandis populations.     

RAPD diversity of Stipa grandis populations and its relationship with some ecological factors

The genetic diversity of Stipa grandis P.Smirn and its relationship with the climatic variables were studied using the RAPD technique for 90 genes from five natural populations sampled in the Xilingol steppe, China. Sixteen oligonucleotides screened from 100 random primers were used to amplify 310 trackable RAPD loci, which were all polymorphic. By analyzing the RAPD data using POPGENE software, different geographic S. grandis populations were studied, which indicated a high level of genetic diversity, and the maximum variation was observed within the populations with a 28% variation observed among the populations. Using Pearson correlation analysis, significant (P < 0.05) or highly significant (P < 0.01) relationships were found between gene diversity indexes and temperature factors (≥10°C cumulative temperature in a year, annual mean temperature and mean temperature in January). Mantel's tests showed that there was no significant correlation between Nei's unbiased genetic distance and the geographic distance of S. grandis populations (r = 0.184, P = 0.261). However, there were significant or highly significant correlations between Nei's genetic distance and the several climatic divergences in pairwise S. grandis populations. All results indicated that natural selection resulting from variations in water and temperature was responsible for the adaptive eco-geographical differentiation indicated by the RAPD markers of different S. grandis populations, and that immigration and gene drift did not play an important role in affecting the differentiation of S. grandis populations.     

内蒙古锡林郭勒高原大针茅种群分株构件数量性状的地理变异研究

采用单因素方差分析、变异组分分析和分形几何学的原理和方法,对内蒙古锡林郭勒盟不同气候条件下的3个大针茅种群分株构件数量性状进行了研究,并结合它们所在生境特点对所得结果进行了分析。结果显示：（1）整个生长季内,不同种群大针茅营养枝高度的生长模式不同;营养枝高度和生殖枝高度在种群间差异显著,且多数变异存在于种群之间;（2）在不同生长期内,大针茅种群地上部干重与植株高度之间存在显著的分形关系;在无强度干扰的情况下,大针茅种群营养枝分形维数的大小与大针茅营养枝地上部干重的累积程度是一致的;但在长期严重干旱条件下,分形维数值表现为快速增加;（3）整个生长季内,同一生境条件下大针茅种群营养枝地上部干重与植株高度之间也存在显著的分形关系,且不同样地间分形维数值差异显著。不同生境条件下大针茅种群分株构件数量性状的差异是对所在生境长期适应、自然选择的结果。     

内蒙古锡林郭勒高原大针茅种群分株构件数量性状的地理变异研究

采用单因素方差分析、变异组分分析和分形几何学的原理和方法,对内蒙古锡林郭勒盟不同气候条件下的三个大针茅种群分株构件数量性状进行了研究,并结合它们所在生境特点对所得结果进行了分析。结果显示：（1）整个生长季内,不同种群大针茅营养枝高度的生长模式不同;营养枝高度和生殖枝高度在种群间差异显著,且多数变异存在于种群之间;（2）在不同生长期内,大针茅种群地上部干重与植株高度之间存在显著的分形关系;在无强度干扰的情况下,大针茅种群营养枝分形维数的大小与大针茅营养枝地上部干重的累积程度是一致的;但在长期严重干旱条件下,分形维数值表现为快速增加;（3）整个生长季内,同一生境条件下大针茅种群营养枝地上部干重与植株高度之间也存在显著的分形关系,且不同样地间分形维数值差异显著。不同生境条件下大针茅种群分株构件数量性状的差异是对所在生境长期适应、自然选择的结果。     

Examining the genetic diversity of Stipa grandis under various grazing pressures

The Stipa grandis steppe in the Inner Mongolia Autonomous Region occupies an area of 2798081 hm2. On the basis of the genetic variation, it was found that its adaptability to the environmental conditions under grazing pressure was significant. Using the Inter-Simple Sequence Repeat (ISSR) procedure, the changes to the genetic diversity of the Stipa grandis population under different grazing pressures were observed. Plant samples were collected from a series of grazing gradients of the Stipa grandis steppe in Dalinuoer National Nature Reserve in the Inner Mongolia (located at 116°38′–116°41′E and 43°25′–43°27′N.), which has the following vegetation types in abundance: Leymus chinensis is the constructive species; the dominant species include Stipa grandis, Cleistogenes squarrosa, and Artemisia frigida; the companion species is Potentilla acaulis and others. According to the grazing pressure, the following four grazing gradients were identified from the dwellings of the herdsmen to the enclosure site: (1) no grazing (CK enclosure site); (2) light grazing (LG); (3) moderate grazing (MG); (4) heavy grazing (HG). Young leaves of each Stipa grandis were collected during the growing season. The results showed that the Stipa grandis showed abundant genetic diversity despite the fact that certain polymorphic loci were lost; at the same time, new polymorphic loci emerged when grazing pressure increased; a total of 10 primers were used, and 74 bands were produced in total, of which 65 bands were polymorphic; the total percentage of polymorphism was 89%; the percentage of polymorphic loci of the Stipa grandis population decreased with the increase of grazing pressure; the percentage of polymorphic loci was 62.2% in the no-grazing (CK) population, 64.9% in the light-grazing (LG) population, 58.1% in the moderate-grazing (MG) population, and 56.8% in the heavy-grazing (HG) population; the genetic diversity of the population in the descending order using the Shannon's information index is as follows: (1) light grazing (0.3486); (2) no grazing (0.3339); (3) moderate grazing (0.3249); (4) heavy grazing (0.2735) with the same distributional pattern as the Nei's genetic diversity index. The test showed the following: As the grazing pressures increased, the change of genetic diversity decreased; the genetic differentiation coefficient among the population (Gst) was 0.1984, which showed the presence of small partial genetic diversity (19.8%) among populations; gene flow (Nm*) between primers varied from 0.9806 to 3.4463, and the mean gene flow (Nm*) was 2.0202; the UPGMA cluster figure that was constructed on the basis of the genetic distance matrix showed four populations that became genetically closer at each step: (1) The first group was the moderate-grazing (MG) population and the heavy- grazing (HG) population; (2) The second group consisted of the no-grazing (CK) population and the light-grazing (LG) population; (3) The two groups gathered together.     

内蒙古草原大针茅群落地上生物量与降水量的关系

根据中国科学院内蒙古草原生态系统定位研究站在大针茅样地(面积500m×500m,地理坐标43°32′20″～43°32′40″N116°33′00″～116°33′30″E)的地上生物量与气候观测资料,利用SPSS分别进行大针茅群落地上生物量与年降水量、月降水量关键时期(4～6月份与6～8月份)降水量以及1～7月份总降水量的相关分析;对年降水量接近的1982、1983和1989年(分别为283.2mm,289.9mm,287.2mm)的地上生物量进行方差分析;运用积分回归模型模拟了降水的季节分配对群落生物量的影响。结果表明:(1)群落生物量的年际变化与年降水、月降水、关键时期降水(4～6月份和6～8月份)以及1～7月份降水量的变化没有显著的相关性(p>0.1);(2)在年降水量接近的年份,群落的地上生物量之间存在显著差异。降水量季节分配的变化对地上生物量的影响还有待于进一步研究。