中国板栗居群间等位酶基因频率的空间分布

中国板栗21个自然群间等位酶遗传变异的空间自相关分析及F－统计分析结果表明：其多数等位基因频率在居群间呈随机分布模式,缺乏一定的空间结构;而部分等位基因表现为渐变或双向渐变的非随机分布模式,又具有特定空间结构。中国板栗遗传变异空间结构模式的形成可能是长距离基因流、自然气候、人类活动、地理距离隔离等诸因素综合作用的结果。文中还就居群等位基因分布格局的成因进行了讨论：在第四纪冰川后,中国板栗以长江流域中下游的孑遗中心为起点,等位基因分别沿着向北和向南的不同方向迁移形成现在的居群结构;季风气候和人类活动干扰是削弱居群分化的主要因素,而基于环境梯度的选择,是形成由北向南渐变分布的原因。     

准噶尔无叶豆5个自然居群ISSR遗传变异的空间自相关分析

采用空间自相关分析方法对准噶尔无叶豆(Eremosparton songoricum)5个居群遗传变异的空间结构进行了研究。根据8对ISSR引物扩增的多态性位点,选择了基因频率在30–70%的ISSR位点,运用GenAlEx6和SAAP4.3软件以及地理距离间隔方法分别计算了5个居群的空间自相关系数。结果表明:准噶尔无叶豆居群具有明显的空间遗传结构,绝大多数ISSR位点变异呈非随机分布。位于沙漠腹地的B、D居群和位于沙漠东缘的F居群的遗传变异呈现渐变模式,分别在7m,7m及9m范围内个体呈现显著正相关,推测与克隆繁殖占绝对优势、有性更新罕见发生有关,而克隆大小的差别则主要由微生境差异所引起。位于沙漠北缘的G居群的遗传变异呈现双向渐变模式,在3m内个体呈现显著正相关,这与该居群实生幼苗增补密切相关,但花粉和种子的有限散布所导致的距离隔离对该居群空间遗传结构产生了重要影响。而沙漠腹地的A居群呈现衰退模式,是因为小居群增加了近交的几率,并引起了遗传漂变。     

水杉孑遗居群AFLP遗传变异的空间分布

本研究采用空间自相关分析方法对水杉 (Metasequoiaglyptostroboides)孑遗居群AFLP遗传变异的空间结构进行了研究 ,以探讨水杉孑遗居群遗传变异的分布特征及其形成机制。根据 6对AFLP选择性引物扩增的 46个多态性位点 ,选择了其表型频率在 2 5 %～ 75 %的 2 7个AFLP标记 ,运用等样本频率方法和等地理距离间隔方法分别对 3 9株和 3 7株原生母树进行了空间自相关系数Moran’sI值计算。结果表明 :水杉孑遗居群缺乏空间结构 ,绝大多数AFLP位点变异为随机分布的空间模式 ,但也有少数位点存在显著性随机相关 ,在 4～ 8km地理距离间隔显示负相关 ,说明该间隔可能是水杉孑遗居群的部分基因交流的有效屏障。水杉原生母树分布存在 12～ 2 8km的明显距离间隔空挡 ,说明人类从迁入该区域起就影响着水杉孑遗居群的原始生境 ,导致其生境片断化、景观破碎 ,进而形成岛屿状分布格局 ,并引起了水杉残留居群的随机遗传漂变。根据本研究结果 ,结合水杉孑遗居群较低的遗传多样性 ,分析探讨了水杉孑遗居群濒危的机理 ,并提出了相应的保育策略 ,为水杉的有效保育提供了科学依据     

濒危物种--巴东木莲等位酶遗传变异的空间自相关分析

采用空间自相关分析方法对巴东木莲目前残留的两个最大居群, 小溪居群的40个个体和桑植居群的28个个体等位酶遗传变异的空间结构进行了研究, 以揭示两居群遗传变异的空间模式, 并探讨其形成机制及与巴东木莲致濒原因、过程之间的关系。根据检测出来的8个酶系统的19个酶位点, 选择基因频率大于0 1小于0 9的等位基因, 运用等样本频率和等地理距离间隔两种方法分别计算两居群不同距离等级下的Moran’sI空间自相关系数。结果表明: 小尺度的小溪居群等位基因的遗传变异缺乏空间结构, 为随机分布模式。巴东木莲生境片断化的桑植居群则是相反的结果, 遗传变异存在明显的空间结构, 遗传变异空间分布为斑块状。造成这种差别的原因可能是桑植居群片断化和地理隔离造成的基因流的限制。上述结果为进一步制定有效的巴东木莲的保育措施提供科学的理论依据。     

濒危物种——巴东木莲等位酶遗传变异的空间自相关分析

采用空间自相关分析方法对巴东木莲目前残留的两个最大居群,小溪居群的40个个体和桑植居群的28个个体等位酶遗传变异的空间结构进行了研究,以揭示两居群遗传变异的空间模式,并探讨其形成机制及与巴东木莲致濒原因、过程之间的关系。根据检测出来的8个酶系统的19个酶位点,选择基因频率大于01小于09的等位基因,运用等样本频率和等地理距离间隔两种方法分别计算两居群不同距离等级下的Moran''s I空间自相关系数。结果表明：小尺度的小溪居群等位基因的遗传变异缺乏空间结构,为随机分布模式。巴东木莲生境片断化的桑植居群则是相反的结果,遗传变异存在明显的空间结构,遗传变异空间分布为斑块状。造成这种差别的原因可能是桑植居群片断化和地理隔离造成的基因流的限制。上述结果为进一步制定有效的巴东木莲的保育措施提供科学的理论依据。     

用分子标记揭示植物随机大居群中亚居群的遗传结构——茅栗自然居群空间遗传结构的SSR分析

采用微卫星标记对茅栗(Castanea sequinii)随机大居群以及其中各亚居群的遗传结构进行了空间自相关分析,以探讨植物自然居群内遗传变异的分布特征及其形成机制。通过9对微卫星引物所产生的119个多态位点,测定了大别山区域内茅栗居群以及各亚居群的空间自相关系数Moran's I值。结果表明:大别山分布的野生茅栗为一个缺乏空间结构的随机大居群,茅栗亚居群之间频繁的花粉流削弱了地理隔离导致的遗传漂变或分化作用在维系居群随机遗传结构中具有的重要作用。但是,在接近亚居群大小的地域范围内(0.228 km)具有一定的空间结构,即小地域尺度中的亚居群存在着空间遗传结构。取样的3个亚居群在小格局范围内都存在一定的空间结构,遗传变异基本上呈非随机分布,在短距离内(61 m)3个亚居群一致表现出不同程度的显著正相关,而随着距离的增加,Moran's I值虽然在不同亚居群间存在一定差异变化,但是总体而言趋向预期值,即不存在空间结构,说明其遗传变异在亚居群内只是在短距离内形成一定的空间结构。研究认为有限的种子散播以及微生境选择等因素可能是产生这种小格局的遗传结构的主要原因。上述研究结果有助于进一步了解植物随机大居群的进化历史和生态过程,同时也为栗属植物中国特有种的保育策略提供了科学依据。     

猕猴桃自然居群SSR遗传变异的空间自相关分析

本研究采用空间自相关分析方法对同域分布的中华猕猴桃(Actinidiachinensis)和美味猕猴桃(A.deliciosa)自然居群SSR遗传变异的空间结构进行了研究,以探讨猕猴桃自然居群遗传变异的分布特征。选用的9对SSR引物在两物种中共扩增出104个等位基因。选择频率在20–80%的SSR等位基因,运用等样本对频率方法分别对同域分布的中华猕猴桃和美味猕猴桃各1个居群及其中华/美味猕猴桃复合居群进行了空间自相关系数Moran’sI值计算。结果表明:中华猕猴桃和美味猕猴桃的遗传变异在居群内均存在着一定程度的空间结构,尽管近半数或半数以上的等位基因在居群内表现为随机分布的空间模式,但也有相当比例(29.6–48.0%)的等位基因在种内居群中和复合居群中(河南西峡51.0%,陕西商南44.7%)呈现渐变、衰退、双向衰退或侵扰模式。而且其居群内遗传变异的空间分布规律,不论是在种内还是复合居群中都基本一致:相距在100m以内,特别是30m范围内的个体间的等位基因表现出显著性的正相关,但随着地理距离的增大逐渐显示出负相关,说明猕猴桃属植物的有效传粉距离可能在100m左右,种子散播主要集中在30m的近距离内。猕猴桃自然居群遗传变异的空间结构是其传粉和种子散播等生物学特性与生境共同作用的结果,其中种子近距离的散播、花粉传播的有限距离及人为干扰是最主要的因素。本研究结果揭示了这两个近缘物种居群遗传变异的空间分布特征及相互关系,有助于进一步探讨猕猴桃属植物的遗传变异、居群扩散及其地理系统发育进化等方面的规律,并为制定相应的保育策略和措施提供基础数据和科学依据。     

中国特有植物卧龙沙棘自然群体的RAPD分析

应用12个随机引物对卧龙沙棘全部2居群共28个个体进行了RAPD分析。结果表明,卧龙沙棘具有较丰富的遗传多样性,多态位点百分率为78.05%,Nei’s基因多样性h=0.2553,Shannon’s多态性信息指数Ι=0.3841。分布范围狭窄的卧龙沙棘在亚种水平的遗传多样性明显高于分布较广的中国沙棘。在居群水平上,卧龙沙棘同样具有很高的遗传多样性,平均多态位点百分率为63.42%,Nei’s基因多样性h=0.2193,Shannon’s多态性信息指数I=0.3287。卧龙沙棘的基因分化系数Gst=0.1425,表明遗传变异主要存在于居群内。AMOVA的结果也表明,在全部的遗传变异中,19.18%的遗传变异存在于居群之间,与Gst值基本一致。这一结果符合卧龙沙棘风媒、异交的繁育系统特点。     

凉水、丰林国家自然保护区红松居群遗传多样性的RAPD分析

采用了RAPD分子标记技术分析了凉水和丰林国家自然保护区红松(Pinus koraiensis)居群的遗传多样性。10个随机引物检测到61个可重复的位点,多态位点比率为0.6935。Nei指数统计结果表明,红松的遗传多样性凉水居群(0.2634)大于丰林居群(0.2607)。对比分析了这两个天然红松居群的遗传多样性变化,红松种内的遗传变异主要存在于居群内,居群间存在一定的遗传分化。     

刚毛柽柳天然居群遗传多样性初探

柽柳是荒漠地区主要的灌木资源树种。以刚毛柽柳为代表,运用RAPD技术分析了广布于新疆境内9个刚毛柽柳(Tamarix hispida L．)天然居群的遗传多样性及居群间的遗传分化。10条随机引物检测到157个可重复的位点,其中多态位点155个,占总位点数的98．7％。由Shannon表型多样性指数和Nei基因多样性指数估计居群间遗传分化百分比分别为62．5％和55．30％,表明刚毛柽柳种内的遗传变异主要存在于居群间。根据以上结果,我们认为新疆境内刚毛柽柳天然居群的遗传多样性很丰富,居群间分化程度较高;繁育系统属于一种自交和不完全异交混合的交配类型;形成并维持其分布格局的主要因素是基因流的隔离。     

有性生殖对栗疫病菌群体结构的影响

采用RAPD方法对来源于栗疫病菌8个不同子囊壳的子囊孢子后代和无性生殖的对照群体各23个菌株进行了群体结构的比较。从RAPD随机引物中筛选出扩增多态性丰富的4条引物,共扩增出条带73条,多态性检测率为100%。研究结果表明,在8个子囊壳和无性生殖群体中的基因多样性,64.27%由群体内部引起,只有35.73%的多样性由群体之间的基因差异引起。各子囊壳群体间存在的基因流动很小(Nm=0.8994)。有性群体和无性群体之间的遗传距离为0.1389,基因流动值为3.4212,说明子囊壳群体和无性生殖群体之间存在一定的系统关系。分析表明栗疫病菌子囊孢子后代在自然界的传播对自然界的病菌的多样性起重要的作用。     

Genetic diversity and population differentiation of chestnut blight fungus, Cryphonectria parasitica, in China as revealed by RAPD

Seventeen Cryphonectria parasitica populations sampled from six regions in China were investigated using RAPD. Across all 169 isolates from the 17 populations evaluated, 52 of the 71 markers (73%) were polymorphic, total genetic diversity (h) was 0.1463, and Shannon’s index was 0.2312. Diversity within populations accounted for 74% of total genetic diversity, and genetic differentiation among populations was 0.26 (G _ST = 0.26). Gene flow was 1.4 among the populations; higher gene flow was found among populations within regions and among regions [N _m (G _SR) = 2.8 and N _m (G _RT) = 3.5]. The unweighted pair group mean analysis (UPGMA) dendrogram revealed two distinct clusters: the northern China group and the southern China group. The spatial autocorrelation analysis revealed that the variation at most loci was randomly distributed and lacked spatial structure, but several loci and closer distances were spatially structured. Human activity and habitat could also be important factors affecting genetic structure among C. parasitica populations in China. Genetic diversity was highest in Southwest China, descending in an orderly fashion to Northeast China. This pattern indicated that Southwest China might be the center of origin of C. parasitica in China. The present study provides useful information for understanding the origin and spread of chestnut blight fungus in China and valuable data for formulating relevant strategies for controlling the disease in China.     

大别山山核桃天然群体遗传结构的初步分析

利用RAPD分子标记技术检测了大别山山核桃3个天然居群的遗传多样性和遗传结构。20条10 bp随机引物共检测到238个扩增位点,其中多态性位点162个,多态位点百分率(PPB)为68.1%。居群水平Shannon’s多态性信息指数(I)介于0.2651~0.2801之间;居群水平Ne i’s基因多样性指数(H)介于0.1789~0.1890之间。遗传变异计算显示大别山山核桃居群间基因分化系数(Gst)为0.4063,分子方差分析(AMOVA)表明居群间基因分化水平为0.4177,居群间基因流(Nm)为0.7306,说明大别山山核桃大部分变异存在于居群内,居群间基因交流相对较少。这一结果符合大别山山核桃风媒、异交的繁育系统特点,但其居群间基因分化程度明显高于异交植物的平均水平(Gst=0.1930)。地理隔离、居群内近交及居群间基因流受阻可能是形成目前大别山山核桃天然群体遗传结构的主要因素。     

栲树天然群体遗传结构的RAPD分析

利用RAPD分子标记对 5个栲树 (CastanopsisfargesiiFranch .)天然群体共计 188个个体的遗传多样性和群体遗传结构进行了分析。 4 1个随机寡核苷酸引物共检测到 385个位点 ,其中多态位点 15 7个 ,占 4 0 .78%。物种水平的Shannon多样性指数I=0 .4 5 97,Nei基因多样度h =0 .2 96。遗传变异分析表明 ,栲树群体的遗传变异主要存在于群体内 ,利用Shannon多样性指数估算的分化 (Hsp_Hpop) /Hsp=0 .0 4 76 ,遗传分化系数Gst =0 .0 4 2 9,分子方差分析 (AMOVA)也证实了这一结论 ,群体内的变异组分占了 94 .97% ,群体间变异只占 5 .0 3%。AMOVA分析结果的显著性检验也表明 ,群体间及群体内个体间均呈现出显著分化 (P <0 .0 0 1)。     

Mixed mating in natural populations of the chestnut blight fungus, Cryphonectria parasitica

As in plants, fungi exhibit wide variation in reproductive strategies and mating systems. Although most sexually reproducing fungi are either predominantly outcrossing or predominantly selfing, there are some notable exceptions. The haploid, ascomycete chestnut blight pathogen, Cryphonectria parasitica, has previously been shown to have a mixed mating system in one population in USA. In this report, we show that both selfing and outcrossing occur in 10 additional populations of C. parasitica sampled from Japan, Italy, Switzerland and USA. Progeny arrays from each population were assayed for segregation at vegetative incompatibility (vic) and DNA fingerprinting loci. Outcrossing rates (t(m)) were estimated as the proportion of progeny arrays showing segregation at one or more loci, corrected by the probability of nondetection of outcrossing (alpha). Estimates of t(m) varied from 0.74 to 0.97, with the lowest rates consistently detected in USA populations (0.74-0.78). Five populations (four in USA and one in Italy) had t(m) significantly less than 1, supporting the conclusion that these populations exhibit mixed mating. The underlying causes of variation in outcrossing rates among populations of C. parasitica are not known, but we speculate that--as in plants--outcrossing is a function of ecological, demographic and genetic factors.     

内蒙古高原小叶锦鸡儿(Caragana microphylla)、中间锦鸡儿(C. davazamcii)和柠条锦鸡儿(C. korshinskii)的遗传多样性及遗传关系

采用RAPD技术对10个具较大地理跨度的小叶锦鸡儿、中间锦鸡儿和柠条锦鸡儿种群的遗传多样性和遗传关系进行了研究.共检测到678个位点,多态条带比率(PPB)为100%;特有位点41个,占6.05%.总体上3种锦鸡儿的遗传多样性表现出自东向西递减的趋势,分析表明其与生长地点年均气温呈显著负相关.AMOVA表明:3种锦鸡儿种间变异只占总体变异的6.08%,且显著性检验表明这种变异不显著;种内种群间的变异占总变异的11.90%;总变异的主要部分来自种群内部(82.02%). 3种锦鸡儿各种群总体分析结果表明:种群内变异比率Hpop/Hsp为0.8013,基因分化系数Gst为0.1603,种群每代迁移数Nm为2.6192,显示种群间存在一定强度的基因流,3种锦鸡儿间表现为异交性.3种锦鸡儿多样性高低及种群聚类分布格局都表现出一定的地理连续性.     

Genetic diversity and genetic relationship of Caragana microphylla, Caragana davazamcii and Caragana korshinskii on the Inner Mongolia Plateau, China

C. microphylla, C. davazamcii and C. korshinskii exhibit a geographical replacement series from east to west on the Inner Mongolia Plateau. Currently, there is still a debate about the taxonomic and genetic relationship among these 3 species. We studied the genetic diversity and genetic relationship among these 3 species by analyzing DNA samples of individual plants from within 10 populations with random amplified polymorphic DNA (RAPD) markers. We identified 678 RAPD loci in total, of which all were polymorphic (PPB = 100%). There were 41 unique loci (6.05%). In general, a trend presented that the genetic diversity of these species decreased from east to west. Further, the genetic diversity was significantly negatively correlated with the local annual mean temperature. Analysis of molecular variation (AMOVA) showed that the genetic variation among these 3 species was only 6.08% of the total genetic variation. Between the species, the genetic variation was insignificant (P = 0.9961). The proportion of genetic variation among populations within each species was 11.90% (P < 0.001) of the total genetic variation, and the total genetic variation mainly existed within the populations (82.02%). Estimated with Shannon's index, genetic differentiation within the populations (Hpop/Hsp) was 0.8013, the coefficient of gene differentiation (Gst) was 0.1603, and the gene flow index (Nm) was 2.6192. This, thus, indicates that there is relatively high gene flow among these populations, and that these 3 species are crossbreeding. The genetic diversity level and the population distribution pattern showed geographic continuity to some extent.     

Landscape conservation genetics of <Emphasis Type="Italic">Dipteryx alata</Emphasis> (“baru” tree: Fabaceae) from Cerrado region of central Brazil

In this paper random amplified polymorphic DNA (RAPD) was used to evaluate the degree of among-population differentiation and associated spatial patterns of genetic divergence for Dipteryx alata Vogel populations from Cerrado region of central Brazil, furnishing support for future programs of conservation of this species. We analyzed patterns of genetic and spatial population structure using 45 RAPD loci scored for 309 trees, sampled from five different regions with two populations each. Genetic structure analysis suggested that panmixia null hypothesis can be rejected, with significant among-population components of 15%. Hierarchical partition by Analysis of Molecular Variance (AMOVA) shows that 5% of genetic variation is within regions, whereas 10% of variation is among regions, and these results were confirmed by a Bayesian analyses on HICKORY. The Mantel correlogram revealed that this divergence is spatially structured, so that local populations situated at short geographic distances could not be considered independent units for conservation and management. However, genetic discontinuities among populations were found in the northwest and southeast parts of the study area, corresponding to regions of recent socio-economic expansion and high population density, respectively. Taking both geographic distances and genetic discontinuities into account it is possible to establish a group of population to be conserved, covering most of D. alata geographic distribution and congruent with previously established priority areas for conservation in the Cerrado region.     

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.