高原鼠兔四个地理种群的遗传多样性与遗传分化

采用7 个多态微卫星DNA 标记分析了4 个高原鼠兔地理种群(海晏种群、西大滩东种群、西大滩西种群和昆仑山种群)的遗传多样性和遗传分化。采用多态信息含量(PIC)、期望杂合度(H_e )、观测杂合度(H_o)、基因流(N_m )和基因分化系数(F_st )对种群及物种的遗传多样性水平进行分析;计算各种群间的遗传距离(GD)、遗传相似度(GI)以及遗传距离与地理距离的相关系数,并进行UPGMA 聚类分析。研究结果显示,高原鼠兔的遗传多样性在小哺乳动物中处于较高水平, 其H_e 和H_o 的平均值分别为0. 5332 和0. 6003, 其F_st 为0. 0975,即有9. 75% 的变异存在于种群之间,即变异主要存在于种群内部。4 个种群间的杂合度与多态信息含量均无显著差异,说明它们的遗传多样性水平基本相当。海晏种群与其余3 个种群的遗传分化均达到了中度分化水平(F_st = 0.1043),而另3 个种群间几乎没有分化(F_st = 0. 0253)。Mantel test 结果表明地理距离与遗传距离间没有显著的相关性。     

内蒙古扁蓿豆遗传多样性的ISSR分析

应用ISSR分子标记对分布于内蒙古不同地区的扁蓿豆(Medicago ruthenica)8个地理种群进行了遗传多样性研究.结果表明:扁蓿豆具有较高的遗传多样性;15个引物共扩增出363个位点,物种水平上Nei s基因多样性指数为0.198 9,Shannon多样性指数为0.303 7;种内总基因多样性为0.308 6,种群内基因多样性为0.198 9,64.45%的遗传变异存在于种群内,35.55%的遗传变异存在于种群间,种群间的遗传分化系数为0.355 5,基因流为0.906 4,8个种群间基因交流较少,遗传分化较强.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.     

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     

入侵植物粗毛牛膝菊种群遗传多样性及遗传分化

利用ISSR分子标记技术,分析粗毛牛膝菊(Galinsoga quadriradiata)在中国分布的18个地理种群遗传多样性和遗传结构特点,为粗毛牛膝菊的防控奠定基础。结果表明:筛选的10条引物共扩增出349个位点,经Popgene软件分析,粗毛牛膝菊种群多态位点百分比(P)为8.88%~29.51%,Nei基因多样性指数(H)为0.0248~0.1023;种群遗传分化系数(Gst)为0.4663,种群间基因流(Nm)为0.5723;遗传相似度平均为0.9404,遗传距离平均为0.0621,UPGMA聚类分析将18个粗毛牛膝菊地理种群分为5大类;经Mantel检验,不同地理种群遗传距离与地理距离相关性不显著。研究表明,粗毛牛膝菊种群的遗传多样性较低;各地理种群间产生了一定程度的遗传分化;粗毛牛膝菊的入侵及扩散途径以人为多次反复传播为主。     

不同成花量金花茶花果期果枝叶内源激素的变化

该研究采用ISSR分子标记,对黄枝油杉7个自然种群的遗传多样性进行了分析。结果表明：用12条ISSR引物对218个黄枝油杉个体进行扩增,共扩增出125个位点。在物种水平上,多态性位点百分数( PPL)为100.00％,Shannon信息多样性指数( I)为0.4177,Nei’ s基因多样性指数( H)为0.2666;在种群水平上,多态性位点百分数(PPL)在71.20％~92.00％之间,平均值为80.69％,Shannon信息多样性指数(I)在0.3273~0.3886之间,平均值为0.3548,Nei’ s基因多样性指数( H)在0.2139~0.2478之间,平均值为0.2291。这说明黄枝油杉在物种水平和种群水平上均显示出较高的遗传多样性。 Nei’ s遗传多样性分析( Gst＝0.1433)和AMOVA分析(Φst＝17.91％)表明,黄枝油杉的遗传变异主要存在于种群内,种群间的遗传分化程度较低,种群间保持一定的基因交流( Nm＝2.9890>1)。 Mantel分析显示,黄枝油杉种群间的遗传距离和地理距离之间不存在显著的相关关系( r＝0.4567, P＝0.0610>0.05)。     

长臀鮠的AFLP分析

采用 AFLP分子标记技术对珠江长臀鮠和海南长臀鮠共60个个体(每个群体30个)进行了遗传多样性研究。选取的18对引物组合均能扩增出清晰、可重复的扩增产物,扩增带型差异明显。两个群体均表现出较高的多态位点比例和特异性条带数。群体内个体间的遗传相似度(平均值)珠江长臀鮠种群为0.9462±0.0237, 海南长臀鮠为0.9465±0.0226,海南长臀鮠比珠江长臀鮠略高。群体间的遗传相似度是0.9367±0.0231,小于两个群体内的遗传相似度,两群体的遗传距离是0.0634±0.0230。根据遗传相似度绘制了UPGMA 聚类图。研究结果表明：珠江长臀鮠和海南长臀鮠间的遗传差异属于种内差异,两者同属一个有效种。     

基于ISSR分子标记的褐马鸡亲缘关系分析

褐马鸡(Crossoptilon mantchuricum)是中国特有濒危鸟类,国家一级保护动物。为了保护褐马鸡种质资源,保障驯养繁育种群和再引入种群的遗传基因结构优化,采用ISSR分子标记技术,对山西庞泉沟国家自然保护区和太原动物园两个种群35个褐马鸡进行了亲缘关系分析。从20条ISSR引物中筛选出10条扩增条带清晰稳定、重复性好的引物,共扩增出65条DNA条带,其中77%呈多态性。两个种群各个体之间的Nei's无偏差遗传距离和遗传相似度分析表明:个体间遗传相似性的平均值分别为0.5061与0.7591,遗传距离的平均值分别为0.4939与0.2409。用组平均法对35个褐马鸡个体进行聚类分析,结果显示:大多数同一种群的个体首先聚在一起,显示出生态地理条件相似的种群亲缘关系较近。     

云南茶树资源遗传多样性分析(英文)

利用EST标记对云南134份茶树资源遗传多样性和亲缘关系进行了分析.结果显示:(1)30对引物共检测到等位位点127个,平均每对引物产生4.23个;共检测到263个基因型,平均每对引物所扩增的基因型有8.8个,遗传多态性信息含量变异范围为0.014～0.736,平均达0.50l.(2)资源间的平均遗传距离和相似系数分别为0.413和0.597,聚类可将134份资源划分为4大组.(3)8个种群间的遗传相似系数变异范围为0.753～0.981,平均遗传相似系数为0.891.结果表明,云南茶树资源间的遗传差异比较大,遗传基础较宽,具有丰富的遗传多样性,而不同种间的遗传差异比较小.     

柴达木地区野生黑果枸杞种群遗传多样性的AFLP分析

采用扩增片段长度多态性(AFLP)分子标记技术对青海省柴达木地区5个野生黑果枸杞(Lycium ruthenicum)种群的120份样品的遗传多样性进行分析。结果表明: 柴达木地区野生黑果枸杞具有很高的遗传多样性, 9对选扩引物共得到1691条清晰条带, 其中多态性条带1678条, 多态性变异率为99.23%, 种群间的有效等位基因数为1.4712, Nei’s基因多样性为0.3245, Shannon信息指数为0.4367。分子方差分析(AMOVA)结果表明: 柴达木地区5个黑果枸杞种群的遗传变异主要存在于种群内部(92%), 种群间的遗传分化较小(8%, 遗传分化系数0.08)。黑果枸杞种群间的遗传相似系数介于0.9709-0.9922之间, 平均值为0.9835。种群间的聚类及Mantel检验(γ = 0.3368, p = 0.8064)均表明柴达木地区黑果枸杞种群地理距离与遗传距离之间的相关性不明显; 黑果枸杞个体间的聚类表明同一种群的个体不能完全聚在一起。对同一种源的遗传多样性分析发现, 诺木洪奥斯勒草场的种源内部的遗传变异更为丰富, 这或许可以推断诺木洪可能为柴达木地区野生黑果枸杞种质资源的中心产区。     

黄枝油杉遗传多样性的ISSR分析

该研究采用ISSR分子标记,对黄枝油杉7个自然种群的遗传多样性进行了分析。结果表明:用12条ISSR引物对218个黄枝油杉个体进行扩增,共扩增出125个位点。在物种水平上,多态性位点百分数(PPL)为100.00%,Shannon信息多样性指数(I)为0.417 7,Nei’s基因多样性指数(H)为0.266 6;在种群水平上,多态性位点百分数(PPL)在71.20%~92.00%之间,平均值为80.69%,Shannon信息多样性指数(I)在0.327 3~0.388 6之间,平均值为0.354 8,Nei’s基因多样性指数(H)在0.213 9~0.247 8之间,平均值为0.229 1。这说明黄枝油杉在物种水平和种群水平上均显示出较高的遗传多样性。Nei’s遗传多样性分析(Gst=0.143 3)和AMOVA分析(Φst=17.91%)表明,黄枝油杉的遗传变异主要存在于种群内,种群间的遗传分化程度较低,种群间保持一定的基因交流(Nm=2.989 01)。Mantel分析显示,黄枝油杉种群间的遗传距离和地理距离之间不存在显著的相关关系(r=0.456 7,P=0.061 00.05)。     

五个红罗非鱼群体的遗传多样性分析

实验采用微卫星标记技术,选用22对微卫星引物对5个红罗非鱼群体进行遗传多样性分析。经PCR扩增,16个微卫星位点扩增产物在关岛红罗非鱼（GD）、珍珠白红罗非鱼（ZZ）、佛罗里达红罗非鱼（FL）、明月红罗非鱼（MY）、马来西亚红罗非鱼（ML）中均获得了清晰稳定的条带。分析结果显示:16个微卫星标记共检测到146个等位基因。5个群体的平均等位基因数（N_a）在6.5625-8.5625,平均有效等位基因数（N_e）在4.1495-6.1330,平均杂合度（H_e）在0.7491-0.8247,平均多态信息含量（PIC）在0.6939-0.7840,说明它们的遗传多态性丰富。卡方检验表明5个红罗非鱼群体的大部分位点偏离Hardy-Weinberg平衡。在5个群体中,关岛红罗非鱼（GD）与珍珠白红罗非鱼（ZZ）遗传相似系数（0.6171）最小,遗传距离（0.4827）最大,说明两者亲缘关系最远;佛罗里达红罗非鱼（FL）与马来西亚红罗非鱼（ML）遗传相似系数（0.9069）最大,遗传距离（0.0977）最小,可推断两者亲缘关系最近。采用UPGMA进行聚类分析,结果表明:佛罗里达与马来西亚先聚成一支,二者再与珍珠白聚在一起,接着三者与明月聚在一起,最后,四者与关岛聚到一起。聚类结果说明关岛群体与其他4个群体亲缘关系最远;佛罗里达与马来西亚亲缘关系最近,珍珠白群体次之,明月群体再次之。以上结果可推断5个红罗非鱼群体遗传多态性丰富,具有较大的选育潜力。     

喜马拉雅-横断山区钟花报春居群遗传多样性及遗传分化

应用简单序列重复区间(ISSR,Inter-simple sequence repeat)分子标记,对喜马拉雅．横断山区钟花报春(Primula sikkimensis)进行居群遗传分析。用10个ISSR引物对13个居群的254个个体进行扩增,共检出91条扩增片段,全部为多态带,总的多态位点百分率为100％。Shannon多样性指数(Ho)从0．2293到0．4016,居群水平上平均值(HPCP)为0．3211,物种水平上(Hsp)为0．5576。利用分子方差(AMOVA)软件分析,其结果为：在总的遗传变异中,有50．28％的遗传变异属于居群之间;用POPGENE计算出的遗传分化系数GST=0．4127,即居群间的分化变异占居群总遗传变异的41．27％,比AMOVA分析所得的结果偏低。居群间遗传距离变化范围从0．0780到0．4748,遗传一致度(I)的变化范围从0．6220到0．9250。居群间的基因流Nm=0．7114,相对低的基因流可能是维持钟花报春居群遗传分化的原因。这表明,喜马拉雅．横断山区钟花报春的13个居群具有很高的遗传多样性,并且居群间的分化也很大。     

Genetic differentiation among Hemarthria compressa populations in south China and its genetic relationship with H. japonica

Within and among populations genetic variance of twelve Hemarthria compressa populations and one Hemarthria japonica population from China were analyzed using inter simple sequence repeat (ISSR). Twelve primers amplified a total of 165 genomic DNA fragments across a total of 148 individuals of which 156 were polymorphic (94.55%). 75.76% of the bands were unique to each species, while the average genetic distance (GD) between one population of H. japonica and twelve populations of H. compressa was 0.44, which suggest that there was distinct differentiation between these two species. In H. compressa, twelve primers produced 145 bands across 145 individuals. High genetic diversity was observed at species level. The percentage of polymorphic loci (P) was 86.21% and Shannon's information index of diversity (I) was 0.357. In contrast, there were relatively low levels of genetic diversity within population (P=32.93%, I=0.174). Analysis of molecular variance (AMOVA) showed that a considerable proportion of genetic variation (48.02%) resided among populations. The coefficient of gene differentiation (G(ST)=48.6%) also suggested that there was strong genetic differentiation among H. compressa populations in southern China. An indirect estimate of the number of migrants per generation (N(m)=0.264) indicated that gene flow was low among populations of this species. Relative high clonal diversity was found, and all local genotypes were found.     

基于SSR分子标记的中国黄连木遗传多样性分析北大核心CSCD

该研究利用筛选出的7对SSR引物,对中国20个省、市、自治区的210份种质资源进行分子标记试验,分析中国黄连木种质资源遗传多样性、亲缘关系、遗传分化特点并构建DNA分子身份证,为黄连木的资源保护、种质利用提供理论依据,结果表明:(1)7对引物在210份种质中共扩增出158个等位基因位点,平均每对引物的等位基因数为22.571个。(2)基因多样性(GD)变化幅度为0.654~0.913,平均为0.804;期望杂合度(He)变化范围0.257~0.771,平均为0.532;多态信息含量(PIC)变化范围0.639~0.907,平均为0.784。(3)从不同地区黄连木群体的遗传多样性来看,观测杂合度(Ho)介于0.373~0.600之间,平均值为0.520;期望杂合度(He)介于0.632~0.811之间,平均值为0.737;从各群体间遗传分化指数(Fst)来看,黄连木各地区群体间的遗传分化值在0.015~0.099之间,各群体间的遗传分化处于中等以下水平。(4)分子方差分析(AMOVA)结果显示,黄连木的遗传分化变异以群体内为主,占总变异量的94%,群体间的变异占6%。(5)UPGMA聚类、群体遗传结构分析和PCoA分析结果相一致,全部种质被划分为两大类,西南地区群体单独为一类,其他地区单独为一类。(6)利用7对SSR引物构建了210份黄连木种质的DNA分子身份证。     

Population genetic structure of the medicinal plant Vitex rotundifolia in China: implications for its use and conservation

Vitexrotundifolia L.is an important plant species used in traditional Chinese medicine.For its efficient use and conservation,genetic diversity and clonal variation of V.rotundifolia populations in China were investigated using inter-simple sequence repeat markers.Fourteen natural populations were included to estimate genetic diversity,and a large population with 135 individuals was used to analyze clonal variation and fine-scale spatial genetic structure.The overall genetic diversity (GD) of V.rotundifolia populations in China was moderate (GD=0.190),with about 40% within-population variation.Across all populations surveyed,the average within-population diversity was moderate (P = 22.6%; GD = 0.086).A relatively high genetic differentiation (Gst=0.587)among populations was detected based on the analysis of molecular variance data.Such characteristics of V.rotundifolia are likely attributed to its sexual/asexual reproduction and limited gene flow.The genotypic diversity (D=0.992) was greater than the average values of a clonal plant,indicating its significant reproduction through seedlings.Spatial autocorrelation analysis showed a clear within-population structure with gene clusters of approximately 20 m.Genetic diversity patterns of V.rotundifolia in China provide a useful guide for its efficient use and conservation by selecting particular populations displaying greater variation that may contain required medicinal compounds,and by sampling individuals in a population at >20 m spatial intervals to avoid collecting individuals with identical or similar genotypes.     

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.     

Genetic Diversity of Jatropha curcas (Euphorbiaceae) Collected from Southern Yunnan,Detected by Inter-simple Sequence Repeat ( ISSR)

The genetic diversity of 158 individuals from eight semi-wild populations from Yunnan Province was estimated using ISSR method (8 primers). The results revealed an extraordinarily high level of genetic diversity ( at species level,percentage of polymorphic loci PPB = 91.04% , effective number of alleles N_e = 1.5244 , Nei′s (1973 ) gene diversity H_e= 0.3070, and Shannon′s information index H_o = 0 . 4618 ; at population level, PPB = 55. 04% , N_e = 1.3826, Nei′s (1973) gene diversity H_e = 0.2171, and Shannon′s information index H_o = 0.3178). The level of genetic differentiation between populations is lower than that among populations . The low level of genetic differentiation among populations was detected, based on Nei′s genetic diversity analysis (29.44%), and AMOVA (36.50%). There is no associations between geographical distance and genetic identity.We suggest that Jatropha curcas of Yunnan Province might not be introduced from the same place.     

Genetic diversity analysis of Hepatacodium miconioides at different altitude in Tiantai 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 distribution. 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 G _ST 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 990 m 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.     

云南南部不同种源地小桐子遗传多样性的ISSR 分析

应用ISSR 分子标记方法对采自云南的8 个居群的小桐子( Jatropha curcas) 共158 个个体进行遗传多样性分析。8 个ISSR 引物共扩增到了67 个位点, 其中61 个是多态性位点。分析结果表明: (1) 云南小桐子的遗传多样性水平很高。在物种水平上, 平均每个位点的多态位点百分率PPB = 91.04% , 有效等位基因数N_e = 1.5244, Nei′s 基因多样性指数H_e= 0.3070, Shannon 多样性信息指数H_o = 0.4618; 在居群水平上, PPB = 55.04%, N_e = 1.3826, H_e = 0.2171, Shannon 多样性信息指数H_o = 0.3178。(2) 居群间的遗传分化低于居群内的遗传分化。基于Nei''s 遗传多样性分析得出的居群间遗传多样性分化系数G_st = 0.2944。AMOVA分析显示: 云南小桐子的遗传变异主要存在于居群内, 占总变异的63.50%, 居群间的遗传变异占36.50%。(3) 居群间的地理距离及遗传一致度并不存在相关性。鉴于以上指标, 我们推测云南小桐子可能来自不同的地区。     

Genetic diversity of the tropical tree Terminalia amazonia (Combretaceae) in naturally fragmented populations

The effect of long-term fragmentation on the genetic diversity of populations of the neotropical tree species, Terminalia amazonia, was studied using random amplified polymorphic DNA (RAPD) analysis. Leaf material from 104 trees was collected from three naturally fragmented gallery forest patches and three plots in nearby continuous forest in the Mountain Pine Ridge, Belize. In total, 30 RAPD bands generated by five decamer primers were used to compare the genetic diversity of the six populations in the two groups. Genetic variation within the populations (H0), as estimated by the Shannon diversity index, ranged from 0.32 to 0.38, with an overall diversity of 0.38 (Hspecies). Analysis of molecular variation revealed that most (94.4%, P<0.001) of the variation was attributable to differences among individuals within populations. Population differentiation was significantly (P=0.038) lower among the fragmented populations than among continuous forest populations. On average, the fragmented populations also had slightly, but statistically significant (P=0.046) lower levels of genetic diversity. However, one gallery forest site had a higher level of genetic diversity than two of the continuous forest sites. We suggest that the long-term effect of fragmentation on the genetic diversity of tropical trees will depend upon the amount of local forest cover in proximity to the fragmented populations.