极濒危植物中华水韭休宁居群的遗传结构

采用超薄平板微型聚丙烯酰胺等电聚焦电泳方法对极濒危蕨类植物中华水韭(Isoetes sinensis)现存于安徽休宁的5个亚居群的等位酶多样性和遗传结构进行了研究。结果表明：中华水韭居群每位点平均等位基因数A=1．7,平均多态位点比率P=55．56％,平均预期杂合度He=0．201。居群中半数的多念位点表现为等位基因的“固定杂合”,5个亚居群的遗传多样性无显著差异,但都表现出严重偏离Hardy—Weinberg平衡的杂合子过昔;其遗传变异主要发生于亚居群内(94．27％),亚居群之间的遗传分化较小(Gsl=0．0573),亚居群间遗传一致度较高(I=0．960—0．999)。我们推断这可能是由于居群构建之初的奠基者效应或者原种群曾经历了较为严重的遗传瓶颈所导致;此外亚居群间便利的基因交流也可能起到了很大作用(Nm=4．5062)。取自休宁居群的75株样品由13个专一多位点基因型(18个位点等位酶基因型)组成,亚居群及个体间高度遗传均质。本文还就中华水韭休宁野生居群濒危的遗传因素进行了探讨,并提出了相应的保育策略。     

珍稀濒危蕨类植物东方水韭的遗传多样性

采用ISSR分子标记对珍稀濒危蕨类植物东方水韭和中华水韭4个自然居群共72个样品进行了DNA多态性分析。从65个随机引物中筛选出11个有效引物,共产生98条DNA片段,其中68条为多态性条带,多态位点百分率(PPL)为66.33%。东方水韭两个居群的多态位点百分比率(PPL)较低(8.16%和7.14%)。中华水韭两个居群的PPL也较低(9.18%和23.47%)。中华水韭物种水平上的PPL(51.02%)高于东方水韭(9.18%)。AMO-VA分析结果表明,东方水韭遗传变异中主要存在于居群内(94.74%),而中华水韭绝大部分的遗传变异却存在于居群间(86.71%)。东方水韭和中华水韭个体间UPGMA聚类结果表明:同一物种的个体完全能聚在一起,中华水韭的两个居群也能明显分开,而东方水韭两居群的个体并不能完全聚在一起。探讨了可能造成上述居群遗传结构模式的主要因素,同时提出今后工作中需重点解决的问题。     

梭梭同工酶遗传多态性初步研究

采用不连续聚丙烯酰胺凝胶电泳技术对采自新蛹阜康绿洲荒漠过渡带的40个梭梭个体的同工酶遗传多态性进行了初步研究。从24个酶系统中筛选,得到了14个酶系统可用于该植物的遗传变异分析。共检测出30个位点、54个等位基因,其中18个位点表现出多态性。在物种水平上,多态位点比率为60％,而平均每个位点的等位基因数为1．8。本研究的方法和结果将为后续相关研究提供一定的参考。     

使用多态异型酶标记物估计野鲮的遗传变异性

本文首次分析了野鲮鱼 (Labeodyocheilus)等位酶的变异情况。通过对 17个酶系统的研究 ,发现 2 8个可以稳定检测的位点 ,其中 8个位点具有多态性。使用这 8个等位酶位点 ,分析了取自不同河流 ,即Satluj、Yamuna和Tons河的样本的遗传多样性情况。结果显示 ,不同样本间存在显著的遗传异质性 ,各位点的表观杂合度介于 0 0 392 (Yamuna河 )与 0 0 4 87(Tons河 )之间。因此 ,本研究所筛选出的多态性等位酶位点为研究该野鲮鱼的种群遗传结构奠定了基础     

松毛虫属（Dendrolimus) 部分种类亲缘关系与遗传分化的等位酶分析

采用等位酶聚丙烯酰胺凝胶电泳技术对松毛虫属5个种和亚种的野生种群进行了亲缘关系和遗传变异的研究.8种等位酶系统(乳酸脱氢酶LDH、苹果酸脱氢酶MDH、苹果酸酶ME、乙醇脱氢酶ADH、甲酸脱氢酶FDH、谷氨酸脱氢酶GDH、过氧化物酶POD、过氧化氢酶CAT)共检测到12个基因位点,其中6个位点为多态位点,检测到15个等位基因.松毛虫属5个种和亚种的总体水平多态位点比率P＝50%,平均有效基因数A = 1.917,平均期望杂合度He =0.267,平均遗传距离为0.0730～0.5701.遗传参数表明松毛虫属昆虫种间存在较高程度的遗传变异,聚类图和遗传距离数据表明赤松毛虫与马尾松毛虫亲缘关系最近,落叶松毛虫与思茅松毛虫亲缘关系最远.     

三峡库区特有种疏花水柏枝的保护遗传学研究

采用超薄平板微型聚丙烯酰胺等电聚焦电泳方法对三峡库区特有种疏花水柏枝 (Myricarialaxiflora)的 13个自然居群和 1个人工迁地保护居群的等位酶遗传变异进行了初步研究。检测了 5个酶系统 ,得到 13个等位酶位点 ,遗传多样性及其遗传结构分析结果表明 :疏花水柏枝具有较高水平的遗传多样性 ,平均多态位点比率P =78.7% ,每位点平均等位基因数A =1.8,平均预期杂合度He=0 .317,高于中国植物特有种的平均水平 ,且群体中杂合基因型个体偏多 ;其遗传变异主要发生于居群内 ( 84.86 % ) ,居群间又存在一定的遗传分化 (Gst=0 .15 14) ,居群间平均基因流Nm =1.40 1,居群间遗传距离为 0 .0 0 2～ 0 .176 ;UPGMA聚类分析显示疏花水柏枝在三峡湖北境内的白水河—泄滩一带分为上游和下游 2个居群组 ;武汉植物园迁地保护的混合居群基本保育了其遗传多样性总水平。在分析讨论疏花水柏枝遗传多样性与其繁育系统、生境及其起源进化的关系的基础上 ,探讨了疏花水柏枝濒危的主要原因 ,推断其应为第四纪冰期影响后的古孑遗种。最后 ,在评价迁地保护成果的基础上 ,提出了今后进一步保育的策略。     

中华水韭遗传多样性的RAPD分析

采用RAPD方法对珍稀濒危植物中华水韭(Isoetes sinensis)4个自然居群的48个样品进行了DNA多态性分析。从60个随机引物中筛选出14个有效引物,共产生124条DNA片段,其中72条为多态性条带,总的多态位点百分率(PPB)为58．06％。各居群间多态位点百分率差异显著(0．81％-12．90％)。AMOVA分析结果表明,4个居群间基因分化系数Фst=0．5894,即遗传变异中有相当一部分来源于群体间(58．94％)。日益缩小的种群规模而导致的居群内近交和遗传漂变的发生以及居群间有限的基因交流可能是中华水韭目前遗传结构的主要成因。鉴于目前中华水韭居群内个体数偏少、遗传多样性较低的现状,建议对其进行就地保护并保护尽可能多的生境,对不同自然居群内的个体进行植株相互移栽和育苗移栽,以提高不同居群间的基因交流,尽可能地保护中华水韭的遗传多样性。     

鹅掌楸（Liriodendronchinense）遗传多样性的等位酶论证

选择５个具有地理代表性的鹅掌楸种群,分析６种酶系统９个位点上２７个等位基因的遗传变异。结果表明鹅掌楸种内保存较高的等位酶变异。     

基于核基因LEAFY的中国珍稀濒危植物中华水韭的遗传多样性分析

利用核基因LEAFY第二个内含子片段对中国现存中华水韭（Isoetes sinensis Palmer）的遗传多样性进行分析,探讨了中华水韭自然居群的遗传多样性结构及其形成机制。结果显示：现存中华水韭7个自然居群共105个样本中存在78个单倍型,单倍型多样性（H_d）为0.989,核苷酸多样性（π）为0.021,遗传差异主要存在于居群内（72%）,且存在较高的基因流（N_m=0.59）。同时,居群遗传学分析结果发现中华水韭居群不存在明显的谱系地理格局（G_ST>N_ST）;Mantel检验中Rxy值为-0.286,P（rxy-rand≥rxy-data）值为0.370,表明居群遗传距离和地理距离之间没有明显相关性;UPGMA聚类分析显示处于海拔较高位置的2个居群与其它5个居群遗传关系较远;中性检验（Taijima's D、Fu & Li's D^*和F^*）检测结果均为负值,基于稳定模型的失配分布检测显示为多峰。根据中华水韭居群的地理位置,推测中华水韭的遗传结构可能与水系、海拔分布及其杂交后代多倍化的物种形成过程相关。     

湖北海棠的等位酶变异和遗传多样性研究

采用超薄平板微型聚丙烯酰胺等电聚焦电泳方法对湖北海棠（Malus hupehensis)的9个野生居群和2个人工栽培居群的等位酶变异和遗传多样性进行了初步研究。通过对12个酶系统29个酶位点的检测,结果表明湖北海棠有25个酶位点的等位基因频率分布差异,,有10个居群发现稀有等位基因,并有11个（37．9％）重复位点;湖北海棠的遗传多样性水平很高,等位基因平均数A＝2．127,多态位点百分率P＝74．927,平均预期杂合度He=0.376;居群间的基因分化系数GST＝0．224。与其他苹果属植物相比,湖北海棠具有中等丰富的遗传变异水平。居群间的基因流仅为Nm=0.866,表明遗传漂变是影响居群遗传变异和遗传结构的一个重要因素。     

Genetic structure of three orchid species with contrasting breeding systems using RAPD and allozyme markers

Zeuxine gracilis, Zeuxine strateumatica, and Eulophia sinensis are wild orchids with different breeding systems and colonizing abilities. Zeuxine gracilis is an outcrosser with restricted distribution, whereas S. strateumatica is an apomictic colonizer found only in newly available open habitats. Eulophia sinensis is an outcrossing colonizer. This study investigates the levels of genetic variation and patterns of population structure in these wild orchids to provide genetic information for the development of suitable conservation strategies. Lack of allozyme variation was characteristic of all three species, especially in populations of the two colonizing orchids, Z. strateumatica and E. sinensis. More variable markers, randomly amplified polymorphic DNAs (RAPDs), were further employed to characterize population structure of these species. Substantial genetic variation was found at the RAPD loci within populations of Z. gracilis (p = 21.65 ± 15.88%, A = 1.217 ± 0.159, and H = 0.076 ± 0.054) and E. sinensis (p = 17.82 ± 20.97%, A = 1.179 ± 0.209, and H = 0.070 ± 0.084), but little variation existed within populations of Z. strateumatica (p = 2.84 ± 2.58%, A = 1.029 ± 0.026, and H = 0.011 ± 0.011). Regardless of the breeding system, the total gene diversity at the species level was partitioned primarily between populations, as shown by high G(ST) values, in all three species. An extremely high level of population differentiation (G(ST) = 0.924) was found in the apomictic colonizer Z. strateumatica. The patterns of genetic variation in these wild orchids are apparently related to their differences in breeding system and colonizing ability. Different conservation strategies are needed for the long-term survival of these species.     

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.     

Evidence for long isolation among populations of a pacific cycad: genetic diversity and differentiation in Cycas seemannii A.Br. (Cycadaceae)

The genetic structure of Cycas seemannii A.Br. (Cycadaceae), sampled throughout its range in Vanuatu, New Caledonia, Fiji, and Tonga, was studied using starch-gel electrophoresis. Twenty enzyme loci in 13 enzyme systems were examined. Low genetic diversity within populations (A = 1.2, P = 21.3, Ho = 0.047, and He = 0.057) and a high degree of differentiation among populations (F(ST) = 0.594) were found. This, together with low gene flow estimates, suggests genetic drift by isolation to have been most critical to the current genetic structure of the species. Inbreeding may occur to some extent (F(IS) = 0.165). The decline in abundance of C. seemannii, coupled with the low level of genetic diversity, suggest that conservation strategies are urgently needed.     

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。     

Isozyme electrophoresis patterns of the liver fluke, Clonorchis sinensis from Kimhae, Korea and from Shenyang, China

An enzyme analysis of the liver fluke, Clonorchis sinensis from Kimhae, Korea and from Shenyang, China was conducted using a horizontal starch gel electrophoresis in order to elucidate their genetic relationships. A total of eight enzymes was employed from two different kinds of buffer systems. Two loci from each enzyme of aconitase and esterase (alpha-Na and beta-Na); and only one locus each from six enzymes, glucose-6-phosphate dehydrogenase (G6PD), alpha-glycerophosphate dehydrogenase (GPD), 3-hydroxybutyrate dehydrogenase (HBDH), malate dehydrogenase (MDH), phosphoglucose isomerase (PGI), and phosphoglucomutase (PGM) were detected. Most of loci in two populations of C. sinensis showed homozygous monomorphic banding patterns and one of them, GPD was specific as genetic markers between two different populations. However, esterase (alpha-Na), GPD, HBDH and PGI loci showed polymorphic banding patterns. Two populations of C. sinensis were more closely clustered within the range of genetic identity value of 0.998-1.0. In summarizing the above results, two populations of C. sinensis employed in this study showed mostly monomorphic enzyme protein banding patterns, and genetic differences specific between two populations.     

Microsatellite primers in the endangered quillwort Isoetes hypsophila (Isoetaceae) and cross-amplification in I. sinensis

? Premise of the study: The first microsatellite primers were developed for Isoetes hypsophila, an endangered quillwort species endemic to the Qinghai-Tibetan Plateau in China, to further describe its genetic variability and population structure. We also examined their cross-amplification in a congeneric species, I. sinensis. ? Methods and Results: Using the Fast Isolation by AFLP of Sequences COntaining Repeats (FIASCO) protocol, nine microsatellite loci were isolated and characterized in 32 samples from four natural populations of I. hypsophila. The primers amplified di- and hexanucleotide repeats with three to 11 alleles per locus. Seven of nine primers were cross-amplified in I. sinensis with two to seven alleles per locus. ? Conclusion: The microsatellite loci primers will be useful for studies of genetic diversity and gene flow in natural populations of Isoetes species.     

Development of microsatellite markers for Ophiocordyceps sinensis (Ophiocordycipitaceae) Using an ISSR-TAIL-PCR method

? Premise of the study: Microsatellite primers were developed for Ophiocordyceps sinensis, an endangered medicinal fungus endemic to the Tibetan Plateau, to investigate its genetic diversity and population structure. ? Methods and Results: An inter-simple sequence repeat (ISSR)-thermal asymmetric interlaced (TAIL)-PCR method was established to develop microsatellite markers. A total of 30 perfect and imperfect microsatellites were identified in 48 individuals of O. sinensis from five provinces within China representing different populations. Seventeen loci were polymorphic with two to four alleles per locus, while 13 were monomorphic. ? Conclusions: The results indicate that the microsatellite markers developed here may be used in studies of population genetics and conservation biology of O. sinensis. Furthermore, the ISSR-TAIL-PCR method is a simple strategy for microsatellite marker development.     

Genetic diversity of six populations of Atractomorpha sinensis and Atractomorpha peregrina in Shanxi Province, China

Ten enzymes (AAT,CK,G3PDH,HEX,IDH,LDH,MDH,ME,PGI,PGM)were examined using horizontal starch gel electrophoresis to estimate the levels of genetic variation within and among six natural populations of two grasshopper species Atractomorpha sinensis and A.peregrina from Shanxi,China.The collecting sites were geographically distant from each other from south to north:Quwo district,Linfen city;Xiangyuan county,Changzhi;Jinyuan district,Taiyuan city;Yuanping county,Xinzhou city and Fanshi county of Xinzhou.A.sinensis showed 43 alleles at 16 loci but A.peregrine showed 39 alleles at 15 loci (ldh-1 was deficient).The zymograms showed that some common alleles were shared at several loci in these two species (Aat-1-b,Aat-2-b,G3pdh-a,Ck-1-b and Ldh-b).However,Hex-1-a,Hex-2-a,Hex-3-a,Idh-2-b,Mdh-2-b,Mdh-1-f Pgi-b,Pgm-b had common alleles in A.sinensis and Hex-1-b,Hex-2-b,Hex-3-b,Idh-2-a,Mdh-2-a,Mdh-1-d,Pgi-a,Pgm-c were of high frequency in A.peregrine instead.Most of the observed genotype frequencies were found to significantly deviate from the Hardy-Weinberg expectations in both species.A tendency of clinal distribution of allele frequency was observed at three loci.The frequency of the moderately migrating allele Me-c (0.318-0.740)in A.peregrina,Hex-1-a (0.800-1.000)and Ldh-b (0.487-0.750)in A.sinensis demonstrated increased frequency from north to south.Such tendency suggests that the allele frequency in these three loci may be correlated with the species'geographic distributions.A.sinensis showed higher genetic diversity than A.peregrina as indicated by higher mean number of alleles per locus (A=1.9-2.3 in A.sinensis and 1.7-2.2 in A.peregrina),percentage of polymorphic loci (56.3%-68.8%in A.sinensis and 43.8%-56.3%in A.peregrina),and the observed heterozygosities (Ho=0.072-0.096 in A.sinensis and 0.070-0.107 in A.peregrina).The observed heterozygosities of the six populations were all noticeably lower than the Hardy-Weinberg expectations,mostly due to heterozygote deficiency in the populations of both species.The overall mean Fsr were small (FST=0.045,P＞0.05 in A.sinensis populations and 0.087,P＞0.05 in A.peregrina populations).Nei's genetic identity (I)estimates indicate low intraspecific (＞0.95)but higher interspecific (0.377-0.447)genetic diversity.The cluster analysis based on modified Roger's genetic distance (D)showed that the two species were divided into two branches.Both species are of limited dispersal capacity and a moderate geographical barrier might significantly restrict the gene exchange among populations,resulting in accumulation of local genetic differentiations.The A.sinensis populations used in this study were separated from each other by 155.2 to 271.4 km and the A.peregrina populations were separated from each other by 78.8 to 174.9 km with observable physical barriers.The aUozyme data showed only minimal genetic differentiation at population level,most likely as a result of gene exchange.It is reasoned that natural factors and human agricultural activities might have facilitated migration and dispersal for the two species.