珍稀濒危植物长叶红砂种群遗传多样性的ISSR分析

采用ISSR分子标记技术,对濒危小灌木长叶红砂(Reaumuria trigyna) 集中分布的5个种群的遗传多样性水平和遗传结构进行了研究。14条引物共检测到114个位点,其中99个为多态位点,多态位点比率为86.84％,长叶红砂种群具有较高的遗传多样性。物种水平上Shannon多样性指数(I)为0.468 8,Nei基因多样性指数(H)为0.308 4;种群水平上,多态位点比率P为77.89%,I为0.410 6,H为0.260 9,基因分化系数Gst为0.106 9,揭示了长叶红砂种群遗传变异多存在于种群内,种群间的遗传分化较小,占10.69%。 基因流(Nm)为4.178 7＞1,说明种群间的基因交流,防止了由于遗传漂变导致的遗传分化。聚类分析表明长叶红砂种群遗传距离与地理距离之间无显著的相关性。研究结果说明遗传多样性水平与物种本身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。     

濒危植物连香树居群的遗传多样性和遗传分化研究

利用ISSR分子标记技术对濒危植物连香树10个居群的遗传多样性和遗传变异进行了分析,结果表明:连香树物种水平遗传多样性较高,多态位点百分率(PPB)达到69.59%,Nei’s基因多样性指数(H)和Shannon信息指数(I)分别为0.231 3和0.351 4;而在居群水平上,多态位点百分率(PPB)为30.61%,Nei’s基因多样性指数(H)和Shannon信息指数(I)分别为0.115 6和0.173 3。遗传变异分析表明,居群间遗传分化程度高,遗传分化系数(GST)为0.500 3,居群间基因流Nm为0.527 3。Mantel检测,居群间的遗传距离和地理距离之间不存在显著的相关性。生境的片断化使居群间的基因流受阻,可能是导致居群间高遗传分化和居群水平低遗传多样性的主要原因。     

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(G_(ST)=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。红砂业种群间的基因流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CI含量呈显著负相关,与CO_3~2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土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     

浙江省境内七子花天然种群遗传多样性研究

利用RAPD技术对浙江省境内的七子花9个天然种群遗传多样性和遗传分化进行研究.结果表明,12种随机引物对180棵植物进行检测,共得到164个可重复的位点.多态位点百分率在14.60%～27.44%(平均为20.73%),以括苍山种群最高,其次是四明山种群,最低是观音坪种群.Shannon指数和Nei指数均反映出七子花各种群具有较低的遗传多样性,但遗传分化明显.Shannon指数显示种群内遗传多样性只占总遗传多样性的27.28%,而种群间遗传多样性却占72.72%;Nei指数表明种群内的遗传变异较小,种群间的遗传变异较大,种群间的遗传分化系数为0.7157.七子花种群间的基因流为0.1987,遗传相似度平均为0.7306,遗传距离平均为0.3150,各种群间的遗传分化明显.根据遗传距离聚类分析,大致可以将9个七子花种群分为东部和西部两大类群.     

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     

不同海拔高度木荷种群遗传多样性的ISSR分析

利用ISSR分子标记技术分析了浙江天台山不同海拔高度木荷种群的遗传多样性和遗传分化.用12个引物对4个木荷种群共80个样品进行扩增,共检测到170个位点,其中多态位点154个,多态位点百分率(P)为90.59%.木荷总的Shannon信息指数(I)为0.5033,Nei指数(h)为0.3408,表明种水平的遗传多样性较高.而种群水平的遗传多样性比种水平低,P平均为63.68%,I平均为0.3789,h平均为0.2608.AMOVA分子差异分析表明,在总的遗传变异中,29.56%的变异存在于种群间,70.44%的变异存在于种群内,种群间的基因分化系数(Gst)为0.2348.木荷种群间的基因流为1.6293,4个种群间的平均遗传距离为0.1500.     

Study on genetic diversity of mangrove plant Aegiceras corniculatum populations in Guangxi

采用RAPD-PCR方法探讨广西3个不同生境下桐花树种群的遗传多样性和遗传分化.结果表明:3个不同生境桐花树RAPD扩增多态百分率为20.2%,3个不同生境桐花树种群两两之间的遗传距离分别为0.195、0.169、0.26,平均遗传距离为0.208.同一种群不同个体的扩增多态百分率最高为37.28%,其次为20.93%,最小的为19.32%.Shannon's遗传多样性指数3个种群分别为0.331、0.225和0.17,其大小顺序与多态百分率的结果一致.种群内遗传多样性比率为62.3%,种群间遗传多样性比率为37.7%.说明广西3个不同生境的桐花树种群的遗传变异大部分存在种群内,种群间遗传变异较小.     

盔型溞(Daphnia galeata)四个地理种群遗传多样性及分化的RADP 分析

利用RAPD 技术对采自云南和广东省的盔形溞的四个不同地理种群(拉市海、程海、洱海和流溪河水库)遗传多样性进行了分析。从20 条寡聚核苷酸中筛选出了12 条扩增产物稳定的随机引物。在4 个群体180 个个体中共检测到72 个可重复位点, 其中多态位点65 个, 多态率超过90%。四个种群的遗传多样性指数(Shannon 指数)介于0.405-0.440 之间, 其中以流溪河水库群体遗传多样性最高, 拉市海群体遗传多样性最低。四个不同地理的盔形溞种群间的遗传分化系数Gst 为0.23。分子方差分析(AMOVA)表明, 四个地理种群内的分子变异为71%, 种群之间为29%, 说明4个地理种群之间的遗传分化水平较高; 云南三个种群内变异为70%, 种群之间的变异为30%, 说明距离较近云南省内的3 个湖泊种群内存在较大的遗传变异, 以上分子方差分析中P 值为0.001, 表明差异极显著(P<0.01)。Jaccard 距离和Nei’s 无偏遗传距离分析显示, 地理距离最近的程海种群(CH)与拉市海种群(LS)并未首先聚在一起, 而是与洱海种群(EH)聚在一起, 之后与地理距离最远的流溪河种群(LX)相聚; 种群分化与距离之间的弱相关性支持资源垄断假说。     

冷蒿种群在放牧干扰下遗传多样性的变化

通过随机扩增多态性 DNA(RAPD)方法检测了放牧干扰下冷蒿种群遗传多样性的变化。 17条 (组 )引物进行 RAPD分析 ,扩增共产生 2 5 4条带 ,其中 2 4 0条为多态性带 ,多态位点百分率达 94 .4 9%。随着放牧强度的增加 ,冷蒿种群多态位点百分数 ,Nei遗传多样性指数、Shannon信息指数均下降 ,种群内个体平均遗传一致度增加。放牧梯度上 4个冷蒿种群 H t=0 .2 116 ,Hs=0 .170 0 ,Dst=0 .0 4 16 ,种群间基因分化系数 Gst=0 .196 5 ,基因流 N*m=2 .0 4 5 1;同时随着放牧强度的增加 ,种群间的 Dst、Gst增加 ,N*m 降低。说明放牧限制了种群间的基因交流 ,使种群发生遗传分化。放牧梯度上的 4个冷蒿种群的遗传距离很小 ,但是随着放牧强度的增加 ,遗传距离在缓慢的增加 ,种群间的遗传一致度降低。根据遗传距离所构建的 U PGMA聚类图中冷蒿 4个种群随着牧压的增加 ,逐级聚在一起。这表明冷蒿种群的遗传分化与放牧强度的关系     

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).     

A comparison of the genetic diversity in Dipteronia sinensis Oliv. and Dipteronia dyeriana Henry

Dipteronia is an endemic genus to China and includes only two species, Dipteronia sinensis and D.dyeriana.Based on random amplified polymorphic DNA (RAPD) markers,a comparative study of the genetic diversity and genetic structure of Dipteronia was performed.In total,128 and 103 loci were detected in 17 D.sinensis populations and 4 D.dyeriana populations,respectively,using 18 random primers.These results showed that the proportions of polymorphic loci for the two species were 92.97% and 81.55%,respectively,indicating that the genetic diversity of D.sinensis was higher than that of D.dyeriana.Analysis,based on similarity coefficients,Shannon diversity index and Nei gene diversity index,also confirmed this result.AMOVA analysis demonstrated that the genetic variation of D.sinensis within and among populations accounted for 56.89% and 43.11% of the total variation,respectively,and that of D.dyeriana was 57.86% and 42.14%,respectively.The Shannon diversity index and Nei gene diversity index showed similar results.The abovementioned characteristics indicated that the genetic diversity levels of these two species were extremely similar and that the interpopulational genetic differentiation within both species was relatively high.Analysis of the genetic distance among populations also supported this conclusion.Low levels of interpopulational gene flow within both species were believed to be among the leading causes for the above-mentioned phenomenon.The correlation analysis between genetic and geographical distances showed the existence of a remarkably significant correlation between the genetic distance and the longitudinal difference among populations of D.sinensis (p＜0.01),while no significant correlation was found between genetic and geographical distances among populations of D.dyeriana.This indicated that genetic distance was correlated with geographical distances on a large scale rather than on a small scale.This result may be related to differences in the selection pressure on species by their habitats with different distribution ranges.We suggest that in situ conservation efforts should focus on establishing more sites to protect the natural populations and their habitats.Ex situ conservation efforts should focus on enhancing the exchange of seeds and seedlings among populations to facilitate gene exchange and recombination,and to help conserve genetic diversity.     

基于RAPD数据探讨中华蓑藓(Macromitrium cavaleriei Card.& Thér.)形态变异的遗传基础

中华蓑藓(Macromitrium cavaleriei Card.&;Thér.)的形态变异强烈,为了解形态变异是否具有遗传学背景,本研究以采自浙南凤阳山、浙中金华北山、浙西北的天目山和江西庐山4个种群的中华蓑藓为材料,运用随机扩增多态性DNA(RAPD)探讨了中华蓑藓的遗传多样性。从100条随机引物中筛选出了15条有效引物,利用它们共获得183个条带,其中多态性条带占79.69%,中华蓑藓各种群间的Dice遗传距离为0.0732~0.1514。POPGENE32软件分析得到种的Nei基因多样性指数(H)为0.3378,Shannon指数(I)为0.5126,遗传分化系数(G_st)为0.1670;基因流(N_m)为2.4947;种群内遗传多样性指数为0.4055,占种群总的遗传多样性的79.11%,反映出研究区域内的中华蓑藓遗传变异大多数存在于种群内,中华蓑藓形态变异并没有多少遗传背景,很可能是生态环境因素引起的可塑性变异。聚类分析表明,中华蓑藓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。虽然4个种群内的形态变异丰富,但是属于同一物种的范围。     

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。     

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．     

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 diversity analysis of Hepatacodium miconioides at different altitude in Tiantal Mountain,Zhejiang Province,China and its relationship with environmental factors

The genetic diversity within and among populations of Hepatacodium miconioides collected at three different altitudes in Tiantai Mountain,Zhejiang Province and its relationships to environmental factors were analyzed by random amplified polymorphic DNA(RAPD)technique.Amplification using 12 random primers of 60 plants and 122 repetitive loci were produced.The percentage of polymorphic loci of three populations ranged from 18.85% to 23.77% with an average of 21.86%,indicating the relatively low genetic diversity of H.miconioides.The average Shannon index of phenotypic diversity(0.1329)and Nei index(0.0925)within populations were relatively low.A distinct genetic differentiation existed among populations Of H miconioides in spite of the relatively small geographical distribufion.The average genetic diversity within populations of H.miconioides accounted for 33.58% of the total genetic diversity while the genetic diversity among populations accounted for 66.42% as estimated by the Shannon index of phenotypic diversity,The genetic differentiation among populations of H.miconioides was 0.6546,as estimated by Nei index.The gene flow estimated from Gsr was only 0.2656 and it indicated that gene flow among populations of H.miconioides was relatively low.The mean value of the genetic identity among populations of H.miconioides was 0.7126 and the average of genetic distance of H.miconioides was 0.3412.The genetic identity between populations at the elevation of 990m and at the elevation of 780 m was the highest.The genetic identity between population at the elevation 500 m and other two populations was relatively low.The correlation analysis showed that the genetic diversity within populations was significantly related with the soil total nitrogen.     

金钱槭和云南金钱槭遗传多样性比较研究

金钱槭属(Dipteronia)是我国特有少种属,属下仅金钱槭(D. sinensis)和云南金钱槭(D. dyeriana)两种。该文用RAPD标记揭示了金钱槭的遗传多样性和遗传结构,并与云南金钱槭的RAPD研究结果进行了比较。同时,对两物种遗传距离与地理距离的相关性进行了分析,结果有助于阐释该属植物遗传变异的产生机制。研究显示,18条随机引物在17个金钱槭居群(226个个体)中检测到128个扩增位点,物种水平的多态位点比率为92.97%,在4个云南金钱槭居群(45个个体)中则检测到103个扩增位点,物种水平的多态位点比率为81.55%,金钱槭的多态位点比率高于云南金钱槭。相似性系数值、Shannon多样性指数和Nei基因多样性指数分析反映了与多态位点比率相一致的结果。AMOVA(Analysis of molecular variance)分析结果显示,金钱槭居群内、居群间的遗传变异分别占总变异量的56.89%和43.11%。云南金钱槭居群内、居群间的遗传变异分别占总变异量的57.86 %和42.14%。Shannon多样性指数、Nei基因多样性指数的分析结果与AMOVA分析结果趋势相同。上述特征值揭示,金钱槭和云南金钱槭居群间的遗传分化均已达到较高水平,推测居群间低水平的基因流可能是导致上述现象产生的原因之一。遗传距离与地理距离的相关分析结果显示,金钱槭居群间的遗传距离与经度差异存在极显著水平的相关性(p<0.01),云南金钱槭居群间的遗传距离与地理隔离则无显著相关关系。说明在大尺度上遗传距离与地理距离相关而在小范围内则无上述关系,该结果可能与位于不同分布区内的物种所承受的生境选择压力不同有关。建议在对该属植物进行就地保护时,应设立多个保护点,保护自然居群及其周围生境;在迁地保护时,应通过加大居群间种子和幼苗的交换,人为创造基因交流和重组的条件,保存该属植物的遗传多样性。     

基于RAPD数据探讨中华蓑藓(Macromitrium cavaleriei Card. & Thér.)形态变异的遗传基础

中华蓑藓（Macromitrium cavaleriei Card.＆Thér.）的形态变异强烈,为了解形态变异是否具有遗传学背景,本研究以采自浙南凤阳山、浙中金华北山、浙西北的天目山和江西庐山4个种群的中华蓑藓为材料,运用随机扩增多态性DNA（RAPD）探讨了中华蓑藓的遗传多样性。从100条随机引物中筛选出了15条有效引物,利用它们共获得183个条带,其中多态性条带占79·69%,中华蓑藓各种群间的Dice遗传距离为0·0732~0·1514。POPGENE32软件分析得到种的Nei基因多样性指数（H）为0·3378,Shannon指数（I）为0·5126,遗传分化系数（Gst）为0·1670;基因流（Nm）为2·4947;种群内遗传多样性指数为0·4055,占种群总的遗传多样性的79·11%,反映出研究区域内的中华蓑藓遗传变异大多数存在于种群内,中华蓑藓形态变异并没有多少遗传背景,很可能是生态环境因素引起的可塑性变异。聚类分析表明,中华蓑藓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。虽然4个种群内的形态变异丰富,但是属于同一物种的范围。