广东5个野生大豆居群的遗传多样性分析

采用SSR分子标记对来自广东省5个县野生大豆居群的遗传多样性进行了分析,为广东野生大豆资源保护和利用提供依据。结果显示:(1)5个野生大豆居群在60个SSR位点共检测出263个等位变异,同一位点上等位基因数目最多为10个,最少为2个,平均为4.38个;不同群体中特有等位基因数不同,其中连州(LZ)和南雄(NX)野生大豆的特有等位基因数目较多,分别为19个和16个;Shannon指数(I)变化范围为0.162~2.174,期望杂合度(He)的变化范围为0.073~0.899。(2)广东连州(LZ)野生大豆居群的遗传多样性最高,而仁化(RH)野生大豆的遗传多样性最低,二者的Shannon指数(I)分别为0.811、0.113;群体分子方差(AMOVA)分析结果揭示,居群间变异占51%,群体内变异占49%,且仁化居群与其他居群间基因流较小。(3)依据遗传距离可将连州(LZ)和连南(LN)聚类为一类,乳源(RY)和南雄(NX)为一类,仁化(RH)单独为一类。研究表明,广东不同野生大豆居群间遗传多样性差异较大,而且居群内基因类型多,其中连州(LZ)和乳源(RY)野生大豆居群的遗传多样性较高,证明广东野生大豆群体保存了丰富的基因资源。     

湖南新田野生大豆自然居群遗传多样性分析

利用SSR分子标记技术对8个来自湖南新田的野生大豆自然居群遗传多样性进行了分析.结果表明:(1)所分析的材料中73对SSR引物共检测到397个等位变异,等位变异数范围为2～10个,平均为5.4个;期望杂合度(He)的变化范围从0.16～0.82,平均为0.64.(2)分子方差分析发现,居群间存在着严重的遗传分化,群体69%的变异存在于居群间,31%的遗传变异存在于居群内.(3)新田的8个居群中桑梓路边(SZLB)和桑梓(SZ)两个居群的遗传多样性比其他群体的高,而新田1 km处(XT1)、新田2 km处(XT2)和新田6 km处(XT6)野生大豆居群的遗传多样性较低.(4)根据遗传距离可将8居群分为3类:新田1 km处和新田2 km处为一类;新田6 km处单独为一类;大冠岭上龙秀、龙秀后山、桑梓、桑梓路边和青龙等处为一类.(5)居群遗传距离和地理距离之间存在线性相关,相关系数为0.837(P<0.01);海拔与期望杂合度呈显著正相关,相关系数为0.92(P=0.001).研究结果表明,湖南新田野生大豆具有较高的遗传多样性,但不同居群的遗传多样性差异很大;位于该县高海拔山区大冠岭一带的野生大豆居群是湖南新田地区的一个多样性中心.     

我国部分金莲花种质资源遗传多样性的RAPD研究

用RAPD标记对来自不同产地的24份金莲花种质从分子水平开展遗传多样性研究,为综舍评价我国金莲花资源现状及植物资源的合理保护提供参考。结果显示,30条RAPD引物共扩增获得194条清晰可辨条带,其中多态性条带108条,多态性位点百分率为55．67％,金莲花总多样性指数为0．1460,居群内遗传多样性为0．0591,Shannon’s多样性指数为0．2248;通过UPGMA进行聚类分析,将24份金莲花种质划分为3个大类,根据总遗传多样性和居群内遗传多样性计算不同居群间遗传分化系数为0．6902,基因流估计平均值为0．2244。研究结果表明,目前我国金莲花种质资源的遗传多样性指教偏低,应该尽快采取相应措施,对不同金莲花资源进行合理保护。     

我国部分金莲花种质资源遗传多样性的RAPD研究

用RAPD标记对来自不同产地的24份金莲花种质从分子水平开展遗传多样性研究,为综合评价我国金莲花资源现状及植物资源的合理保护提供参考。结果显示,30条RAPD引物共扩增获得194条清晰可辨条带,其中多态性条带108条,多态性位点百分率为55.67%,金莲花总多样性指数为0.1460,居群内遗传多样性为0.0591,Shannon’s多样性指数为0.2248;通过UPGMA进行聚类分析,将24份金莲花种质划分为3个大类,根据总遗传多样性和居群内遗传多样性计算不同居群间遗传分化系数为0.6902,基因流估计平均值为0.2244。研究结果表明,目前我国金莲花种质资源的遗传多样性指数偏低,应该尽快采取相应措施,对不同金莲花资源进行合理保护。     

山核桃种质资源遗传多样性的RAPD分析

运用RAPD分子标记技术对山核桃种质资源的五处天然居群遗传多样性进行了初步研究。20条10bp随机引物共检测出252个扩增位点,其中多态性位点168个,多态性位点比率为66.7%。依据Shannon’s表型多样性指数,山核桃种质资源的遗传多样性水平相对较高,群体内变异占总变异的60.32%,居群间变异率为39.68%。五处天然居群中,岛石居群遗传多样性水平最高,为0.2800,临目居群最低,为0.1992。群体内平均遗传距离为0.0914,居群间平均遗传距离为0.1188。丰富的遗传多样性可保证山核桃种质群体能够持续生存和发育,也为山核桃选优、品种改良及遗传育种工作奠定了遗传学基础。     

山东省3个野生大豆居群生育期基因遗传多样性分析

以来自山东省3个居群的137份野生大豆种质资源为试验材料,利用等位基因特异性DNA标记进行生育期E1～E4基因型鉴定及遗传多样性分析。结果表明:在山东省野生大豆生育期基因E1～E4中,E1、E4位点上只检测出1个等位变异,皆为显性基因型E1、E4;E2、E3位点上变异较为丰富,分别以E2-in、E3-Ha为主;共发现5种基因型组合,其中E1E2-dlE3-HaE4基因型为优势组合。3个居群遗传变异不尽相同,临沂居群E2、E3位点以E2-in、E3-Mi为主,共有4种基因型组合,基因型组合以E1E2-inE3-MiE4为主。蓬莱和荣成居群,E2、E3位点以E2-dl、E3-Ha为主,共有3种基因型组合,以E1E2-dlE3-HaE4为主。在遗传多样性方面,山东荣成和蓬莱的亲缘关系较近,与临沂亲缘关系较远。遗传多样性最高的为临沂居群,其次是蓬莱居群,荣成居群。本研究结果可为山东省野生大豆种质资源利用提供理论依据,具有重要的应用价值。     

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。     

基于AFLP分析的伯乐树(Bretschneidera sinensis)谱系地理学研究

伯乐树（Bretschneidera sinensis Hemsl.）是主要分布于中国的濒危物种。采用AFLP分子标记对分布于中国11个省的24个伯乐树居群192个个体进行谱系地理学研究。结果显示,伯乐树有相对较高的遗传多样性水平,基因多样性指数（He）和Shannon指数（Ⅰ）分别为0.2728和0.4070。伯乐树居群间的遗传分化远大于居群内遗传分化,遗传分化系数G_ST=0.7138,基因流N_m=0.2005。通过聚类分析、STRUCTURE分析和BAPS分析发现,24个伯乐树居群可形成4大地理居群组和进化谱系;云贵高原东部地区居群遗传多样性较高,可能是伯乐树在中国的扩散中心和冰期避难所,伯乐树在冰期后由此向外进行居群扩散;南岭地区各居群遗传多样性水平普遍高于其他地区,与邻近地区各居群的亲缘关系较近,可能为伯乐树演化历史上的另一个冰期避难所。     

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。     

广西地不容种质资源的ISSR分析

采用简单序列重复区间扩增(ISSR)分子标记技术对广西地不容3个野生居群和1个引种居群共92个个体进行了遗传多样性研究。10个引物共扩增出61条带,其中60条具多态性,多态性位点百分率为98.36%。4个居群多态性百分率在73.77%～86.89%。Nei’s基因多样性指数(H)为0.3379,Shannon信息多样性指数(Ⅰ)为0.5055。3个野生居群Nei’s遗传分化系数(Gst)表明:83.87%遗传变异分布在居群内,16.13%的遗传变异分布在居群间。引种居群与3个野生居群间的遗传一致度达0.8846。引种居群有效地保护了广西地不容的遗传多样性。     

Population structure of the wild soybean (Glycine soja) in China: implications from microsatellite analyses

Background and Aims Wild soybean (Glycine soja), a native species of East Asia, is the closest wild relative of the cultivated soybean (G. max) and supplies valuable genetic resources for cultivar breeding. Analyses of the genetic variation and population structure of wild soybean are fundamental for effective conservation studies and utilization of this valuable genetic resource. Methods In this study, 40 wild soybean populations from China were genotyped with 20 microsatellites to investigate the natural population structure and genetic diversity. These results were integrated with previous microsatellite analyses for 231 representative individuals from East Asia to investigate the genetic relationships of wild soybeans from China. Key Results Analysis of molecular variance (AMOVA) revealed that 43·92 % of the molecular variance occurred within populations, although relatively low genetic diversity was detected for natural wild soybean populations. Most of the populations exhibited significant effects of a genetic bottleneck. Principal co-ordinate analysis, construction of a Neighbor-Joining tree and Bayesian clustering indicated two main genotypic clusters of wild soybean from China. The wild soybean populations, which are distributed in north-east and south China, separated by the Huang-Huai Valley, displayed similar genotypes, whereas those populations from the Huang-Huai Valley were different. Conclusions The previously unknown population structure of the natural populations of wild soybean distributed throughout China was determined. Two evolutionarily significant units were defined and further analysed by combining genetic diversity and structure analyses from Chinese populations with representative samples from Eastern Asia. The study suggests that during the glacial period there may have been an expansion route between south-east and north-east China, via the temperate forests in the East China Sea Land Bridge, which resulted in similar genotypes of wild soybean populations from these regions. Genetic diversity and bottleneck analysis supports that both extensive collection of germplasm resources and habitat management strategies should be undertaken for effective conservation studies of these important wild soybean resources.     

新考察收集野生大豆与已保存野生大豆的遗传多样性比较

本研究以65份东北地区新收集野生大豆资源以及与其来源相同的已经编目保存的资源为实验材料,利用60对SSR引物进行遗传分析。分析结果表明新收集材料在22个位点的遗传多样性指数都高于以前收集的资源,有62个等位变异是新收集材料所特有。新收集材料与其它资源间的平均遗传相似系数为0．1918。说明新收集的材料使得野生大豆的遗传多样性水平得到提高,对野生大豆进行补充考察和收集是有价值的。     

大豆种质资源遗传多样性研究进展

我国拥有丰富的大豆种质资源,大豆种质资源遗传多样性研究也取得了较大进展。总结了近年来大豆种质资源组成、保存、研究、利用等几方面的研究进展,讨论了大豆遗传多样性的重要性和发展方向,以期为大豆优良品种培育相关研究提供参考。     

中国野生稻收集、鉴定和保存现状

本通过介绍我国野生稻种质资源的考察、收集、繁种、编目、鉴定、评价和保存、保护状况,论述了我国野生稻丰富的遗传多样性和种质资源研究成就,针对目前存在的突出问题,提出了我国野生稻种质资源研究目标和主要任务。     

Importance of genetic characterization and conservation of plant genetic resources: The breeding system and genetic diversity of wild soybean (Glycine soja)

Abstract Plant genetic resources play an important role in the improvement of cultivated plants. To characterize and evaluate the ecological and reproductive features of wild soybean ( Glycine soja Sieb. et Zucc.), which is the most probable ancestor of cultivated soybean ( G. max (L) Merr.), the breeding system and genetic diversity of G. soja were investigated. The extent of natural cross-pollination of G. soja was estimated in four populations along the Omono River in Akita Prefecture, Japan by examining allozyme variation. Although it has been previously believed that G. soja is autogamous, as is cultivated soybean, the mean multilocus outcrossing rate ( t m) estimate was 13%. These values are much higher than the outcrossing rate previously reported for both G. soja and G. max . Frequent visits by honeybees and carpenter bees to flowers were also observed, which supported this conjecture. Furthermore, to evaluate the genetic variation of G. soja as a genetic resource, the genetic structure of 447 populations over Japan were analyzed. Wild soybean populations had a higher degree of variation of isozyme loci. The G ST coefficient of gene differentian values among the sites within the district were particularly high, revealing that the isozyme genotype was greatly different among site populations and homogeneous within the sites. The genetic differentiation among nine districts was observed in the allele frequencies of a few loci, indicating that geographic isolation in the wild soybean population was effectively created through the distance between the districts. The difference in the allele frequency among the districts may be produced under genetic drift. Finally, the importance of the preservation of natural plant populations and the habitats of wild progenitors (i.e. the in situ conservation of plant genetic resources) was emphasized.     

Genetic diversity assessment and ex situ conservation strategy of the endangered Dendrobium officinale (Orchidaceae) using new trinucleotide microsatellite markers

Dendrobium officinale (Orchidaceae) is an endangered plant species with important medicinal value. To evaluate the effectiveness of ex situ collection of D. officinale genetic diversity, we developed 15 polymorphic trinucleotide microsatellite loci of D. officinale to examine the genetic diversity and structure of three D. officinale germplasm collections comprising 120 individuals from its germplasm collection base and their respective wild populations consisting of 62 individuals from three provinces in China. The three germplasm collections showed reductions in gene diversity and average number of alleles per locus, but an increase in average number of rare alleles (frequency?≤?0.05) per locus in comparison to their wild populations. However, the differences in gene diversity between the germplasm collections and wild populations were not statistically significant. The analysis using STRUCTURE revealed evident differences in genetic composition between each germplasm collection and its wild population, probably because the D. officinale individuals with distinct genotypes in each wild population were unevenly selected for establishing its germplasm collection. For conservation management plans, we propose that D. officinale individuals with rare alleles need to be conserved with top priority, and those individuals with the most common alleles also should be concerned. The 15 new microsatellite loci may be used as a powerful tool for further evaluation and conservation of the genetic diversity of D. officinale germplasm resources.     

Soybean germplasm pools in Asia revealed by nuclear SSRs

Soybean was domesticated in East Asia, where various kinds of landraces have been established as a result of adaptation to different environments and the diversification of food cultures. Asia is thus an important germplasm pool of soybean. In order to evaluate the genetic structure of the Asian soybean population, we analyzed allelic profiles at 20 simple-sequence repeat (SSR) loci of 131 accessions introduced from 14 Asian countries. The SSR loci produced an average of 11.9 alleles and a mean gene diversity of 0.782 in the accessions tested. Quantification theory III analysis and cluster analysis with the UPGMA method clearly separated the Japanese from the Chinese accessions, suggesting that the Japanese and Chinese populations formed different germplasm pools. The Korean accessions were involved in both germplasm pools, whereas most of the accessions from southeast and south/central Asia were derived from the Chinese pool. Relatively high genetic diversity and the absence of region-specific clusters in the southeast and south/central Asian populations suggest that soybean in these areas has been introduced repeatedly and independently from the diverse Chinese germplasm pool. The present study indicates that the two germplasm pools can be used as exotic genetic resources to enlarge the genetic bases of the respective Asian soybean populations.     

Genetic Structure of Natural Populations of Wild Soybean (Glycine soja) in Beijing Region

In order to exploit the genetic resources of wild soybean (Glycine soja) which is the progenitor of cultivated soybean (Glycine max), the genic frequencies of Ti (coding trypsin inhibitors) and Sp1 (coding β-amylase isozymes) for 13 populations of wild soybean in Beijing region were determined. There are 2 alleles (Tia and Tib) in Ti locus of Beijing populations. Calculation of heterozygosity indicates Sp1 is polymorphic, while this monomorphic within a population. Based on the vatiation (from 0 to 50%) for heterozygosity of Sp1 among populations, with special reference to the values of genetic distances among populatious, and no heterozygote has been found in 1300 plants which would be heterozygotes if they were outbreeder, we suggested that wild soybean in natural populations is absolute inbreeder. The frequencies of Ti and Sp1 alleles vary from place to place extremely, however, no correlation exists between allozyme frequencies and ecological factors. Field investigation has shown that there is a threat from the reduction in available habitats, caused by building irrigation works .and urbanization. Finally, sampling strategy for conservation of genetic resources of wild soybean was discussed and some suggestions were made.     

贵州野生猕猴桃表型遗传多样性分析

通过对146份贵州猕猴桃种质资源表型遗传多样性的研究,为贵州猕猴桃品种选育打下基础,对146份不同区域猕猴桃种质资源48个质量性状进行描述、赋值,并结合单果重等9个数量性状,使用主成分分析、聚类分析等进行综合评价。结果表明,57个质量性状和数量性状均存在丰富的多样性和变异性;146份资源的Shannon’s遗传多样性指数为1.28,从各区域遗传多样性指数可以看出,演化进程上从遗传多样性指数高的地区向低的地区进行演化;主成分分析结果显示,前14个主成分累计贡献率达75.076%,其中前6个主成分的累计贡献率达51.911%,为提高品种选育和评价的工作效率,可将猕猴桃种质资源的描述指标简化为新梢被毛、果实被毛等18个性状;聚类结果显示,贵州猕猴桃种质的欧氏距离为1.00~25.00之间,在D=19.25处,146份野生猕猴桃分为6个类群。本文有效揭示了贵州省猕猴桃种质资源丰富的多样性和亲缘关系,明确野生猕猴桃各种群间性状区分特征和部分优良资源性状的地理分布,对贵州猕猴桃种质资源的种质鉴定、保护利用和品种选育有重要意义。     

北京地区野生大豆种群SSR标记的遗传多样性评价

 使用40对SSR引物分析了北京地区野生大豆(Glycine soja)天然种群的遗传结构与遗传多样性。10个种群共检测到526个等位变异, 平均每对引物等位基因数为13.15个, 种群平均Shannon指数(I)为0.658, 群体平均位点预期杂合度(H_e)为0.369, 群体平均位点杂合度(H_o)为1.29 %。平均种群内遗传多样度(H_s)为0.362, 平均种群间遗传多样度(D_ST)为0.446, 基因分化程度(G_ST)为0.544。该研究显示, 中-西部生态区种群比北部和东部山区种群有较高的遗传多样性。在地理上, 环绕北京地区的太行山和燕山两大余脉区域野生大豆种群遗传分化表现出地理差异。可能是经过干旱选择而形成的有抗旱潜力的种群在遗传上表现单一化。期待该种群提供耐旱基因。