新疆阜康荒漠红砂种群遗传结构及其与生态因子的耦合关系

应用RAPD标记技术对分布于新疆阜康荒漠的重要植物红砂(Reaumuria soongorica(Pall.)Maxim)种群遗传结构和遗传多样性进行了分析.15条随机引物对红砂7个亚种群的136个个体进行扩增,共检测71个位点,其中多态位点69个.研究结果表明:红砂种群的多态位点比率(PPB)为97.18%,显示出分布于过渡带的红砂种群内存在较高的遗传多样性.Shannon多样性指数(0.307 5)、Nei基因多样性指数(0.312 7)和基因分化系数(GST=0.312 0)揭示了红砂种群遗传变异多存在于亚种群内,而亚种群间的遗传分化则较小.红砂亚种群间的基因流Nm=1.102 8,Nm＞1但低于一般风媒传粉植物(Nm=5.24)的基因流水平,处于分化的临界状态.AMOVA分析说明红砂种群变异的61.58%存在于亚种群内,而亚种群间的变异占总变异的38.02%.另外,通过RAPD资料的聚类分析及相关性分析研究,发现红砂自然种群的遗传结构与绿洲荒漠过渡带的微生境生态因子(主要是土壤因子)相关,其中红砂亚种群遗传多样性水平与土壤中全磷和Cl含量呈显著负相关,与 C023含量呈显著正相关.而其它土壤生态因子则与红砂的遗传多样性指数的相关性均不显著(P＞0.05).表明红砂个体的分布可能与过渡带上壤的某些易溶性盐分相关.研究还发现,随着土壤中有机质、水分、全氮和全磷含量的减少,红砂种群的遗传多样性水平有上升的趋势.这可能与荒漠植物为了适应恶劣环境而在长期进化中产生更大的遗传变异潜力有关.本试验结果也进一步证实分布于较小范围内的红砂亚种群间的遗传距离、遗传多样性与亚种群的地理距离(经纬度差异)大小无显著的相关性.研究表明微生境的生态因子在红砂种群的适应性进化中起着重要的作用.     

新疆阜康绿洲荒漠过渡带叉毛蓬种群遗传多样性及环境适应性研究

本文采用RAPD分子标记分析了新疆阜康绿洲荒漠过渡带叉毛蓬种群的遗传多样性;运用ORIGIN软件,对叉毛蓬种群的遗传多样性和土壤因子进行了回归相关分析。结果表明:叉毛蓬种群具有高的遗传多样性(P=98.7%)。亚种群的Nei基因多样性指数(H)与土壤中的钠离子、氯离子含量显著负相关(P=0.042、P=0.0408);遗传多样性指数与土壤中的电导率、含水量无显著相关关系;多态位点比率(P)与土壤中的全钾含量显著相关(P=0.011),Shannon多样性指数和Nei基因指数与有机质呈极显著负相关(P=0.0030、P=0.0015),与全磷、全氮负相关,但没有达到显著水平。叉毛蓬为旱生植物,利用有限的水分就可以完成生活史,水分没有成为一种限制性因子;土壤中的氯盐在维持叉毛蓬亚种群遗传多样性方面可能起着较为重要的作用,成为与遗传多样性显著相关的限制性因子,对叉毛蓬种群的遗传多样性具有一定的选择压力;同时处于贫瘠土壤上的叉毛蓬机体能够更加完全地利用土壤中的限制性养分,与土壤养分表现出负相关关系。另外,用随机引物检测到的叉毛蓬种群77个位点中有11个位点的基因频率与过渡带土壤因子存在着显著相关,表明这些位点对土壤因子具有特殊的敏感性。新疆阜康地区绿洲荒漠过渡带中叉毛蓬种群的遗传多样性特性可能是亚种群对所处微生境长期适应的结果。     

内蒙古高原小叶锦鸡儿与中间锦鸡儿遗传多样性的研究

利用ISSR分子标记,选取内蒙古高原自东向西共15个锦鸡儿种群(7个小叶锦鸡儿种群,8个中间锦鸡儿种群)进行遗传多样性分析。结果表明:(1)7个小叶锦鸡儿种群总的多态位点百分数为98.19%,Nei’s基因多样性指数与Shannon信息指数分别为0.289 7、0.444 0;居群间遗传分化系数Gst为0.119 0,表明小叶锦鸡儿种群存在中等程度的遗传分化;居群间基因交流频繁,基因流(Nm)为3.701 0。(2)8个中间锦鸡儿种群多态位点百分数为99.7%,Nei’s基因多样性指数为0.312 8,Shannon信息指数为0.478 4;居群间遗传分化系数(Gst)为0.188 1,表明中间锦鸡儿种群存在较大的遗传分化,基因流(Nm)为2.157 8。(3)中间锦鸡儿遗传多样性及遗传分化均高于小叶锦鸡儿,这是中间锦鸡儿替代小叶锦鸡儿适应不良环境扩展分布的遗传基础。(4)邻接聚类分析结果显示,15个锦鸡儿种群表现为从东到西逐渐聚类,体现了这2个种在分布上的地理渐变性及地理替代性;遗传多样性各指数与气象因子及土壤因子之间的相关性分析表明,平均气温对锦鸡儿种群的遗传分化起着重要的作用。     

新疆阜康荒漠地区叉毛蓬居群的遗传结构和分化

应用RAPD技术,对新疆阜康荒漠地区叉毛蓬进行了居群遗传分析。结果表明：①用14个随机引物对5个叉毛蓬亚居群的98个个体进行了RAPD扩增,共检出3919条扩增片段,多态带3868条,总的多态位点百分率为98．7％;②Shannon多样性指数(HPOP／HSP＝0．6933)和Nei基因多样性指数(HS／HT＝0．6948)显示出大部分的遗传变异存在于叉毛蓬亚居群内,遗传分化系数(GST＝o．3052)表明亚居群问的分子变异占居群总遗传变异的30％以上;②5个叉毛蓬亚居群间的平均遗传距离为0．1817,变异范围从0．1258到0．2445,与同一物种亚种间遗传距离的变幅较一致(0．02—0．20),表明5个亚居群间产生了遗传分化;④叉毛蓬亚居群的基因流Nm＝1．138,低于一般广布种的基因流水平(Nm＝1．881),且远低于毛乌素沙地柠条的基因流(Nm＝5．9529),相对有限的基因流可能在叉毛蓬居群遗传分化的维持中起着作用。以上分析表明,尽管大部分的遗传多样性存在于叉毛蓬亚居群内,但5个亚居群间已有明显遗传分化的趋势。     

四川西部濒危植物桃儿七遗传多样性的RAPD分析

桃儿七是一种具有重要药用价值的珍稀濒危植物。采用RAPD分子标记技术,对在四川西部地区的桃儿七7个自然种群的遗传多样性水平和遗传结构进行了分析。用12个RAPD引物对7个种群共140个样品进行了扩增,共得到111条清晰带,其中32条具有多态性,在物种水平上多态位点百分率(PPB)为28.83%,在种群内的多态位点百分率变动幅度为4.50%至16.22%。同其它一些濒危植物相比,桃儿七种群具有较低的遗传多样性(He=0.0622,Ho=0.0987)。7个自然种群间出现了很强的遗传分化,分化指数接近70%。种群间的基因流低(Nm=0.2240)。造成上述结果的可能原因是与桃儿七的繁育方式和有限的基因流等因素有关。应将遗传多样性相对较高的松潘县牟尼沟种群作为原位保护的核心种群进行保护,尽量保护所有现有种群。     

濒危灌木长叶红砂遗传多样性的RAPD分析

应用RAPD分子标记对濒危灌木长叶红砂(Reaumuria trigyna)种群遗传多样性进行了分析.应用18条随机引物对长叶红砂5个种群的95个个体进行扩增,检测到118个位点,其中多态位点105个.结果表明:长叶红砂种群的多态位点比率(P)为88.98%,显示出长叶红砂种群存在较高的遗传多样性.Shannon多样性指数(0.4966)、Nei基因多样性指数(0.3303)和基因分化系数(Gst=0.1425)的分析结果显示,长叶红砂种群遗传变异大多存在于种群内,种群间的遗传分化占14.25%.聚类分析表明,长叶红砂种群遗传距离与地理距离之间无直接相关关系.遗传多样性水平与物种特性和所处不同群落有关,濒危植物并不一定表现为遗传变异水平的降低.     

古尔班通古特沙漠荒漠肉苁蓉遗传多样性分析

为了全面了解古尔班通古特沙漠荒漠肉苁蓉居群分布的遗传多样性特点,本研究通过ISSR分子标记技术,利用Nei和Shannon等多样性指数对古尔班通古特沙漠中5个居群166个个体的荒漠肉苁蓉遗传多样性、荒漠肉苁蓉种群和种内的遗传多样性进行分析。在供试材料中,8个引物共扩增出144个多态位点,多态位点百分率达100%,5个居群的多态位点百分率差异在46.53%～77.78%之间。在物种水平上,Nei基因多样度(h)为0.260 4,Shannon多样性指数(I)是0.411 0。遗传变异分析表明,物种水平的居群间遗传分化系数Gst为0.222 2,居群间的基因流Nm为1.750 7。研究显示古尔班通古特沙漠中荒漠肉苁蓉多态位点比例高,各居群基因交流较多,不同居群间遗传变异并不明显,这些对肉从蓉资源有效地保护和利用具有重要意义。     

马尾松纯林中球孢白僵菌种群的遗传异质性

应用ISSR分子标记对安徽省麻姑山马尾松人工纯林的111株球孢白僵菌进行遗传异质性分析,7个引物共得到58个位点,其中多态位点比率为93.10%.不同调查时间亚种群的Nei基因多样性(He)为0.2552,Shannon信息指数(I)为0.3825,亚种群间的基因分化系数(Gst)为0.2269,基因流(Nm)为0.8518,其中5月和7月间的遗传距离最小,为0.0408;不同寄主亚种群的He为0.2623、I为0.3884,亚种群间的Gst为0.1964、Nm为1.0223,其中鞘翅目和鳞翅目间亚种群的遗传距离最小,为0.0163.表明麻姑山球孢白僵菌存在较高的遗传异质性,亚种群间的遗传变异较小,亚种群内表现出相对较大的遗传变异,未见ISSR图谱相同或高度相似的菌株.     

四川六个厚朴种群遗传结构

利用ISSR技术对四川6个野生厚朴种群的遗传结构进行了分析,以评估野生厚朴资源的遗传现状。10条ISSR引物共测到114个位点,其中多态位点93个,多态位点百分率(PPB)为81.58%,Nei遗传多样性指数(H)和Shannon信息指数(I)分别为0.320和0.469,表明厚朴物种水平具有较高的遗传多样性;相比之下,种群水平遗传多样性则相对较低(PPB、H、I分别平均为48.25%、0.189和0.277)。分子变异分析(AMOVA)表明,种群内部和种群间均存在极显著遗传分化(P0.001),其中,36.82%的变异存在于种群间,63.18%存在于种群内,种群间的基因分化系数(GST)为40.42%。厚朴种群间的基因流(Nm)为0.737,平均遗传距离为0.211,算术加权平均数法(UPGMA)显示厚朴6个种群被分为3大类群。Structure分析表明,厚朴种群间遗传结构具有独立性特点。     

水松自然种群和人工种群遗传多样性比较

采用ISSR分子标记技术分析水松不同起源种群的遗传多样性.结果表明:10条引物共检测出95个扩增位点,多态位点数占39.0%.与其他濒危裸子植物相比,水松的遗传多样性较低,遗传分化系数Gst为0.3982,基因流Nm仅0.3778,种群间存在一定程度的遗传分化,但种群内变异占主导地位;遗传距离与地理距离呈正相关关系.自然种群的多态位点百分率(P)、Nei的条带多样度(He)和Shannon信息指数(Ⅰ)平均值(39.3%、0.1499和0.2202)分别高于人工种群(30.7%、0.1265和0.1759).自然种群的遗传分化系数(Gst0.4513)和平均遗传距离(D=0.0301)也高于人工种群(Gst=0.3025,D=0.0192).     

都支杜鹃遗传多样性的ISSR分析

通过ISSR分子标记对都支杜鹃(Rhododendron shanii)5个居群114个个体的遗传多样性进行了分析。8个引物共检测到69个位点,其中多态位点36个,多态位点百分率 （P） 为52.17%;物种水平的Shannon多样性指数（I）为0.2536,Nei指数（H）为0.1659;居群水平的P、I和H分别平均为32.46%、0.1955和0.1344;Nei’s基因分化系数GST=0.1845,基因流Nm=2.2104;遗传结构的AMOVA分析显示,总的遗传变异中88.3%存在于居群内,11.7%存在于居群间;PCA分析和Splite Tree构建的NJ树均显示居群间分化小;遗传距离与地理距离显著相关。较强的基因流、多年生木本及异交与分布区狭窄等可能是导致都支杜鹃遗传多样性较低的主要原因。目前该种的保护应以就地保护为主,尤其要注意对大居群的保护。     

Ecological genetics of Reaumuria soongorica (Pall.) Maxim. population in the oasis–desert ecotone in Fukang,Xinjiang, and its implications for molecular evolution

Using inter-simple sequence repeat (ISSR) markers, studies were performed to characterize the population genetic diversity and structure of Reaumuria soongorica (Pall.) Maxim. in the oasis–desert ecotone in Fukang, Xinjiang. Eleven primers were screened to amplify DNA sequences from 132 individuals, which corresponded to seven subpopulations. Totally, 176 loci, all of them polymorphic, were detected, and the percentage of polymorphic bands (PPB) was 100%, indicating a relatively high genetic diversity within the R. soongorica population. According to the hierarchical analysis of molecular variances (AMOVA), the analysis of Shannon's diversity and Nei's analysis of gene diversity, the percentages of genetic variation among subpopulations were 15.87%, 16.28% and 14.58%, respectively, which meant that 83.72–85.42% of total genetic variation occurred within subpopulations. Besides, POPGENE analysis also revealed a relatively high gene flow (N_m = 2.9290) among subpopulations. Correlation analysis showed that there existed no significant correlation between the ISSR-based genetic diversity of the seven R. soongorica subpopulations and their ecological factors (mainly in soil) (P > 0.05). However, on the other hand, Mantel test revealed a significant correlation between inter-subpopulation genetic distances and geographic distances (r = 0.637, P < 0.01), indicating that geographic distance was among the important factors affecting the population genetic structure of R. soongorica. Meanwhile, a comparative analysis was performed between the present ISSR-based and the previously published RAPD-based results, and revealed obvious discrepancies, implying the different evolutionary patterns of the genomic regions sampled by ISSR and RAPD markers.     

GENETIC VARIABILITY OF GELIDIUM CANARIENSIS (RHODOPHYTA) DETERMINED BY ISOZYME ELECTROPHORESIS1

The populations of Gelidium canariensis (Grunow) Seoane-Camba from the Canary Islands were analyzed for genetic variability by isozyme electrophoresis in 1989 and 1990. Each population was divided into sporophytic and gametophytic subpopulations. Twenty-three to 27 putative alleles corresponding to 22 gene loci were analyzed. Sev-enteen loci were monomorphic in all six subpopulations, and five were polymorphic in at least one subpopulation. Significant deviations from Hardy-Weinberg equilibrium were found. The amount of genetic variability (percentage of polymorphic loci, mean number of alleles per locus, and average gene diversity) of haploid subpopulations was lower than that of diploid subpopulations. No correlation between genetic distance and geographical distance was found. Low genetic differentiation between sporophytic and gametophytic subpopulations of the same locality was obsewed in two populations. The low genetic diversity and genetic differentiation suggest that the genetic structure of the populations of G. canariensis from the Canary Islands is due to a combination of founder effects and the predominance of asexual reproduction. Initial differences in gene frequencies may have persisted because of insufficient time to reach a higher level of differentiation.     

RAPD analysis of genetic diversity and population genetic structure of Stipa krylovii Reshov. in Inner Mongolia steppe

Random amplified polymorphic DNA (RAPD) analysis was used to characterize the genetic diversity and population genetic structure of Stipa krylovii populations in Inner Mongolia steppe of North China. Thirteen 10 bp oligonucleotide primers, which generated 237 RAPD bands, were used to analyze 90 plants of five populations from three regions, meadow steppe, typical steppe and desert steppe, from the east to the west. The genetic diversity of Stipa krylovii that was revealed by observed number of alleles (na), expected number of alleles (ne), Nei's diversity index (h), Shannon's diversity index (H), amplificated loci, polymorphic loci and the percentage of polymorphic loci (PPB) increased from the east to the west. The Pearson's correlation analysis between genetic diversity parameters and ecological parameters indicated that the genetic diversity of Stipa krylovii was associated with precipitation and cumulative temperature variations along the longitude (humidity were calculated by precipitation and cumulative temperature). Dendrogram based on Jaccard's genetic distance showed that the individuals from the same population formed a single sub-group. Although most variation (56.85%) was within populations, there was high genetic differentiation among populations of Stipa krylovii, high differentiation within and between regions by AMOVA analysis. Either Nei's unbiased genetic distance (G(ST)) or gene flow (Nm) among pairwise populations was not correlated with geographical distance by Mantel's test (P > 0.05), suggesting that there was no consistency with the isolation by distance model in these populations. Natural selection may have played a role in affecting the genetic diversity and population structure, but habitat destruction and degradation in northern grassland in China may be the main factor responsible for high genetic differentiation among populations, within and among regions.     

Genetic structure and differentiation of Psathyrostachys huashanica populations detected with RAPD markers

Psathyrostachys huashanica Keng is a perennial grass and belongs to genus Psathyrostachys under Triticeae.sathyrostachys is found in the center of Middle Asia and the Caucasus Mountain,while P.huashanica,a species endemic to China,is only located in Mt.Hua in the Shaanxi province,China.At present,the population of this species is decreasing,and reaching the edge of extinction.Due to the limitation in distribution and the importance as breeding material for germplasm storage,it has been considered as first class among the national protected rare plants.For this reason,the present study is significant in probing plant flora,origin and evolution of Triticeae,and crop breeding.Randomly amplified polymorphic DNA (RAPD)markers were used to analyze the genetic structure and differentiation of P.huashanica populations sampled in three valleys (Huangpu,Xian,and Huashan Valleys)in Mr.Hua.One hundred and twenty-two RAPDfragments were obtained in all 266 individuals with 20 primers with a mean of 6.1 (2-10)fragments per primer.The percentage of polymorphic loci (PPB)was 60.66%in Huangpu Valley,90.98%in Xian Valley,95.08%in Huashan Valley,and the total PPB was 95.08%,which indicated a highly genetic variability of P.huashanica.The Shannon's Information index and GST were 0.3306 and 0.3263,respectively,indicating that there were more genetic variations within the subpopulations than those among the subpopulations.The gene flow among the subpopulations of P.huashanica (Nm=1.0322)was much less than that of the common anemophytes (Nm=5.24).Mean genetic distance is 0.1571(range:0.0022-0.2901).The highest value of genetic distance was found between the subpopulation (hp1)of Huangpu Valley and the highest altitude subpopulation (h8)of Huashan Valley.Correlation analysis detected significant correlation between genetic distance and vertical distance of altitude.Clustering analysis and principal coordinate analysis revealed the genetic differentiation among the populations of P.huashanica.Differentiation mainly occurred between the higher altitude subpopulations and the lower altitude subpopulations,suggesting that altitude might be the major factor that restricted the gene flow between different altitude subpopulations and resulted in differentiation of subpopulations.     

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     

大王马先蒿云南五个居群遗传变异研究

采用随机扩增多态DNA(RAPD)分子标记方法,对大王马先蒿(PedicularisrexL.)分布在云南中甸、丽江、大理、武定和昆明的5个居群(其中中甸居群有3个亚居群)的遗传多样性和遗传结构进行了研究。结果表明,大王马先蒿居群具有较高的遗传多样性,多态位点百分率P、Shannon表型多样性指数I和Nei的基因多样性指数h分别为82.0%、0.361和0.240,遗传多样性水平与居群的地理分布范围相关;大王马先蒿居群间的遗传变异较高,遗传变异主要发生在居群之间,而不是居群内部;居群间遗传分化系数Gst为0.747,遗传分化明显,居群间基因交流较少。居群间的遗传距离与居群间的相对地理距离具有一定的相关性。对云南西北部中甸居群的3个亚居群的遗传多样性分析表明,居群的遗传多样性水平与海拔高度有一定的相关性。居群间遗传变异较高可能是由于大王马先蒿为短命多年生植物,繁育系统为混交型,且自交占较大比例等原因造成的。     

不同生境夏蜡梅群体遗传多样性的RAPD分析

利用RAPD技术对天台大雷山4个不同生境：灌丛、常绿阔叶林、杉木林和竹林中的夏蜡梅群体进行遗传多样性研究。12个随机引物在80个个体中共检测到182个可重复的位点,其中多态位点为49个,总的多态位点百分率为26.92%。4个群体的多态位点百分率在6.04%~11.54%之间,平均为8.93%,其中竹林群体最高,常绿阔叶林群体最低,大小顺序为竹林群体＞灌丛群体＞杉木林群体＞常绿阔叶林群体,Shannon指数和Nei指数估算结果为灌丛群体最高,其次是竹林群体,第三是杉木林群体,最低的是常绿阔叶林群体。AMOVA分子差异分析表明夏蜡梅群体间遗传分化程度高,71.91%的变异存在于群体间,28.09%的变异存在于群体内,群体间的基因分化系数（G_ST）为0.627 4。夏蜡梅群体间的基因流很低,N_m=0. 297 0。聚类分析结果表明杉木林群体和灌丛群体最先聚在一起,再与常绿阔叶林群体相聚,最后与竹林群体聚在一起。可见,夏蜡梅在各生境间有着不同的遗传多样性,且在各生境间发生了明显的遗传分化。     

Genetic variation,population structure and identification of yellow catfish, <Emphasis Type="Italic">Mystus nemurus</Emphasis> (C&;V) in Thailand using RAPD,ISSR and SCAR marker

Random amplified polymorphic DNA (RAPD) and inter-simple sequence repeat (ISSR) markers were used to investigate the genetic structure of four subpopulations of Mystus nemurus in Thailand. The 7 RAPD and 7 ISSR primers were selected. Of 83 total RAPD fragments, 80 (96.39%) were polymorphic loci, and of 81 total ISSR fragments, 75 (92.59%) were polymorphic loci. Genetic variation and genetic differentiation obtained from RAPD fragments or ISSR fragments showed similar results. Percentage of polymorphic loci (%P), observed number of alleles, effective number of alleles, Nei’s gene diversity (H) and Shannon’s information index revealed moderate to high level of genetic variations within each M. nemurus subpopulation and overall population. High levels of genetic differentiations were received from pairwise unbiased genetic distance (D) and coefficient of differentiation. Mantel test between D or gene flow and geographical distance showed a low to moderate correlation. Analysis of molecular variance indicated that variations among subpopulations were higher than those within subpopulations. The UPGMA dendrograms, based on RAPD and ISSR, showing the genetic relationship among subpopulations are grouped into three clusters; Songkhla (SK) subpopulation was separated from the other subpopulations. The candidate species-specific and subpopulation-specific RAPD fragments were sequenced and used to design sequence-characterized amplified region primers which distinguished M. nemurus from other species and divided SK subpopulation from the other subpopulations. The markers used in this study should be useful for breeding programs and future aquacultural development of this species in Thailand.