10个南方皂荚群体遗传多样性的AFLP分析

[目的]研究南方皂荚的遗传多样性和遗传结构现状,为制定有效的保护策略和育种策略提供理论依据。[方法]采用扩增片段长度多态性技术对供试的215份皂荚的遗传多样性及遗传距离进行分析。[结果]表明:检测到1 782个位点,其中,有1 389个为多态性位点,多态位点百分率为77.94%;皂荚各群体Shannon’s信息指数平均为0.256;Nei’s多样性指数平均为0.168,表明皂荚群体的遗传多样性偏低,皂荚群体间存在着一定的遗传分化;根据遗传距离UPGMA聚类分析,将10个群体划分为4大类。由遗传分化系数和分子方差分析结果发现,群体内的变异是皂荚遗传变异的主体,74.79%的变异来自群体内。[结论]皂荚群体的遗传多样性与遗传结构的形成不仅与其分布广泛、种子特性及生活史有关,而且与人为的砍伐、引种、生境片段化等因素有重要关系。基于上述结果提出了皂荚的保护策略。     

云南松主分布区天然群体的遗传多样性及保护单元的构建

以20个云南松天然群体为对象,SSR分析表明云南松遗传变异主要存在于群体内,各群体间的遗传多样性水平差异不显著。基于SSR分子标记遗传多样性分析,根据Nei's遗传相似度,采用逐步聚类优先取样法,分别对初始群体、遗传多样性保护单元和剩余群体进行比较、t检验,以此评价遗传多样性保护单元的代表性。结果表明,利用该方法抽样的群体能很好地代表初始群体的遗传多样性,按30%的群体抽样,等位基因数、有效等位基因数、Shannon's信息指数和期望杂合度的保留率分别达到初始群体的98.03%、105.36%、103.99%和105.56%。保护单元的遗传多样性均高于剩余群体,抽样群体组成的遗传多样性保护单元的效果较好。     

马尾松种子园及其附近人工林的亲子代群体遗传结构分析

利用同工酶标记对广西覃塘林场马尾松无性系种子园及其附近一人工林的亲子代群体遗传结构进行研究。研究结果表明，不论是种子园还是附近人工林均表现为：亲代群体处于遗传平衡状态，杂合体相对过量，但子代已偏离遗传平衡，杂合体相对不足，亲子代的基因频率变化不大。种子园亲代群体的遗传多样性略高于子代，而附近人工林的亲代群体遗传多样性略低于子代。本文研究的种子园具有较宽的遗传基础，该种子园附近人工林的遗传多样性与种子园接近，但不论是人工林本身还是它的子代其多样性平均水平都较种子园的亲代和子代略低。     

北亚热带日本落叶松不同改良水平群体的遗传多样性

【目的】利用EST-SSR标记比较和评价北亚热带亚高山区日本落叶松引种种源群体、一代育种群体和二代育种群体的遗传多样性及其变化趋势,为该区域日本落叶松高轮次遗传改良和持续利用提供依据。【方法】利用16个SSR标记分析日本落叶松3个群体共873份个体的遗传多样性,应用Gen Alex 6.41软件进行遗传参数估算、遗传变异分析和主坐标分析。【结果】16对引物在全部样品中共检测到106个等位基因,平均等位基因数为6.7个,不同位点的多态性差异较大,其中中高度多态性位点有14个,说明这些标记能够较好地反映该群体的遗传多样性水平; 3个群体的平均有效等位基因数(Ne)为2.543,Shannon多样性指数(I)为0.979,多态性信息含量PIC值为0.480,具有较高的遗传多样性;引种种源群体、一代育种群体和二代育种群体的多样性指数I值分别为0.911、1.017和1.009,PIC值分别为0.432、0.484和0.488,说明一代和二代育种群体的遗传多样性参数略高于种源群体,但方差分析结果显示3个群体之间差异不显著;总体来说3个群体间的遗传距离较小,在0.006～0.075之间,其中,一代和二代育种群体间的距离最小,种源群体与一代和二代育种群体间的遗传距离逐渐增大; AMOVA分析结果也表明3个群体间分化较小,变异主要来源于群体内;等位基因频率比较及主坐标分析(PCoA)结果显示种源群体与一代和二代群体的遗传基础存在着明显的差异,将少量种源群体中差异较大的基因型引入二代育种群体中,可有效提高二代育种群体的遗传多样性水平。【结论】北亚热带日本落叶松育种群体的遗传多样性较高,改良代群体遗传变异水平并没有降低,说明目前该区域的育种策略对于维持遗传多样性是合适的。3个群体的材料来源差异、栽培与育种中的花粉污染以及高强度的定向选择,是造成种源群体与一代、二代群体遗传多样性参数及遗传组成上的差异的主要因素,适时地将原产地资源补充到育种群体中,这对日本落叶松这样的外来树种的高轮次育种群体构建尤为重要。     

基于SSR标记的杜仲群体遗传多样性及遗传结构

通过分析杜仲群体的遗传多样性水平和遗传结构,旨在为杜仲资源的管理、保护和利用提供依据。利用9对基因组SSR引物对42个杜仲群体的868份种质资源进行遗传多样性分析、群体遗传结构分析、分子方差分析和聚类分析,主要结果如下:(1)遗传多样性分析表明,42个杜仲群体的遗传多样性水平均较高;(2)遗传结构分析表明,42个群体宜分为2个类群;(3)分子方差分析和聚类分析表明,杜仲的遗传变异主要在群体内,占93%,群体间的遗传变异仅占7%,群体间遗传分化水平低,相似程度高。本研究认为:杜仲群体的遗传多样性较高;杜仲群体间的遗传分化水平低,相似程度高;杜仲的遗传变异以群体内的变异为主,保护杜仲的遗传多样性时,应保存尽可能多的种群和特异单株。     

蒙古栎天然群体遗传多样性的AFLP分析

以黑龙江省小兴安岭嘉荫、内蒙古大青沟和河北省雾灵山的3个蒙古栎群体及北京东灵山辽东栎群体为供试材料,用筛选出的4对荧光引物,对4个群体共计96个个体进行Ant分析,每对AFLP引物扩增出63～113条,共得到346条多态带;群体特异带及群体间共有带的差异与分布揭示了群体间的遗传差异及相似性;蒙古栎遗传多样性主要存在于群体内,群体间的遗传分化系数Gst为0．077。蒙古栎在种级水平的遗传多样性参数略高于群体水平,多态带百分率P分别为96．8％、67．2％,有效等位基因数Ae分别为1．220、1．208,Nei基因多样性指数H分别为0．145、0．134,Shannon多样性指数,分别为0．246、0．208。东灵山辽东栎群体的P为67．6％,Shannon多样性指数,为0．220,Nei基因多样性指数H为0．134。UPGMA聚类分析结果表明,蒙古栎自然群体间的遗传距离有随地理距离跨度增加而递增的趋势。蒙古栎遗传多样性偏低可能与其在历史上长期用作经济树种、人为干预和环境破坏较为严重、现存林分基本上为次生林等因素有关。     

天然珙桐群体的RAPD标记遗传多样性研究

利用RAPD技术 ,通过 13个引物对 5个天然珙桐种群的遗传多样性、种群内和种群间的遗传变异进行了研究。结果表明 :珙桐天然种群具有丰富的遗传多样性 ,但群体间的差异明显 ,2 6 %的遗传变异存在于群体间 ,与我国濒危树种马褂木和银杉等相似 ,而与广布性树种相异。取样方法对遗传多样性参数的影响分析表明 ,有效等位基因数和基因多样度受取样个体数的影响较小 ,群体间的分化系数和基因流的估算受取样个体数的影响较大。研究还将珙桐划分为东南部和西北部两大种源区。通过珙桐遗传多样性的研究 ,为今后有效保存和合理利用珙桐种质资源提供了理论依据     

思茅松天然群体的遗传多样性及遗传分化

采用凝胶电泳技术,检测了思茅松(Pinuskesiyavar.Langbinaensis)种子胚乳的9种同工酶。通过对9种酶系统编码的16个酶位点的遗传分析,揭示了思茅松三个天然群体的遗传多样性和遗传分化情况。思茅松天然群体的遗传多样性较高,群体的多态位点比例为0.667;平均每个位点的等位基因数为2.13;期望杂合度和观察杂合度分别为0.288和0.197。群体间的遗传分化程度较低,分化系数仅为0.052,群体间的遗传距离为0.015。表5参15。     

分子生物学技术在桉树育林中的应用

随着分子生物学的快速发展,分子生物学技术在桉树育林中的应用日益广泛,主要表现:天然群体遗传多样性分析;育种群体的遗传多样性分析;天然林采伐策略的制定;种植材料的遗传多样性分析;无性系指纹、商业注册与鉴定;杂种鉴定;标记辅助选择;标记辅助选配杂交亲本;种子园基因流的监测;病原菌的早期检测与预报;转基因品种的培育。分子生物学技术也将大大推动我国的桉树育林研究。     

毛红椿天然群体遗传多样性及取样策略探讨

[目的]研究毛红椿天然群体遗传多样性取样策略,为其种质资源收集、保存和遗传多样性保护等提供参考依据。[方法]利用8对微卫星分子标记进行毛红椿天然群体遗传多样性和空间自相关分析,综合制定其天然群体合理取样策略。[结果]毛红椿天然群体等位基因数平均为7.5个,期望杂合度(H_e)和多态性信息指数(PIC)均值分别为0.643 7和0.636 0,基因分化系数(G_(ST))均值为0.290 7。在遗传多样性取样策略方面,提出了根据毛红椿群体基因分化系数来确定取样群体遗传变异所占总变异比例的运算公式为1-(G_(ST))~(n-1),其中,n为取样群体的数量。当取样群体达到4个时,基本上能包括该树种97.5%的遗传变异;同时确定了目标群体的选择方法,应选择与其它群体间基因分化系数均值较大的4个群体,即贵州册亨(CH)、浙江遂昌(SC)、浙江仙居(XJ)和云南师宗(SZ)。通过构建云南宾川(BC)、云南师宗(SZ)和江西宜丰(YF)群体内取样单株数量与基因多样性和等位基因之间的捕获曲线,确定了群体内取样单株数量应达到15个以上;毛红椿天然群体内300～520 m范围内的单株间存在相似关系,超出此范围个体间差别较大,说明在进行群体内单株取样时,单株间距应大于520 m。[结论]取样群体数量、群体间遗传分化系数、群体内单株数量以及单株间距离等影响了毛红椿取样群体的遗传多样性。毛红椿天然群体遗传多样性取样策略为取样群体4个、每个群体最少取样15个单株,单株间距大于520 m。     

Genetic diversity and population structure analysis of Pistacia species revealed by phenylalanine ammonia-lyase gene markers and implications for conservation

Information on population genetic structure and crop genetic diversity is important for genetically improving crop species and conserving threatened species.The PAL gene sequence is part of a multigene family that can be utilized to design DNA marker systems for genetic diversity and population structure investigation.In the current study, genetic diversity and population structure of100 accessions of wild Pistacia species were investigated with 78 PAL markers.A protocol for using PAL sequences as DNA markers was developed.A total of 313 PAL loci were recognized, showing 100% polymorphism for PAL markers.The PAL markers produced relatively more observed and effective alleles in Pistacia falcata and Pistacia atlantica, with a higher Shannon's information index and expected heterozygosity in P.atlantica, Pistacia vera and Pistacia mutica.Pairwise assessment of Nei's genetic distance and genetic identity between populations revealed a close association between geographically isolated populations of Pistacia khinjuk and Pistacia chinensis.The accessions of wild Pistacia species had more genetic relationship among studied groups of species.Analysis of molecular variance indicated 19% amongpopulation variation and 81% within-population variation for the PAL gene based DNA marker.Population structure analysis based on PAL revealed four groups with high genetic admixture among populations.The results establish PAL markers as a functional DNA marker system and provide important genetic information about accessions from wild populations of Pistacia species.     

Fine-scale analysis reveals a potential influence of forest management on the spatial genetic structure of Eremanthus erythropappus

Forest management may have significant effects on forest connectivity and natural population sizes.Harvesting old-growth single trees may also change natural patterns of genetic variation and spatial genetic structure.This study evaluated the impacts of forest management using a silvicultural system of seed trees on the genetic diversity and spatial genetic structure of Eremanthus erythropappus(DC.)MacLeish.A complete survey of 275 trees on four plots was undertaken out to compare the genetic variation of a managed stand with an unmanaged stand.We genotyped all adult and juvenile individuals 60 months after the management and compared the genetic diversity and the spatial genetic structure parameters.Genetic diversity was considered high because of an efficient gene flow between stands.There were no genetic differences between stands and no evidence of inbreeding.Genetic clustering identified a single population(K=1),indicating no genetic differentiation between managed and unmanaged stands.Adult and juvenile individuals of the unmanaged stand were more geographically structured than individuals from the managed one.There was a tendency of coancestry among juveniles at the first class of distance of the managed stand,suggesting a drift of genetic structure possibly caused by management.Understanding early responses to management on genetic diversity and stand structure is a first step to ensuring the effectiveness of conservation practices of tree species.The sustainability of forest management of E.erythropappus on genetic diversity,and more accurately,on spatial genetic structure needs evaluation over time to promote effective conservation of the population size and genetic variability.     

江西毛红椿天然群体的遗传多样性分析

以江西境内的5个毛红椿天然群体为研究对象,开展基于ISSR与SSR分子标记的群体遗传多样性研究。结果显示,5个群体总体表现为杂合子过剩,纯合子不足,总的遗传多样性偏低;物种水平的基因多样度（h）为0.2524,各群体基因多样度按大小排序为：九连山>官山>井冈山>马头山>岩泉。毛红椿群体规模小且林龄结构单一,推测这是造成其杂合子过剩但是基因多样性低下的主要原因。遗传分化指标（GST）显示受检测的毛红椿各群体间已发生显著分化,但群体内的遗传变异约占总变异的70%,仍是变异的主要来源;群体间基因流值（Nm）仅为0.596,多世代后的随机遗传漂变会逐渐加剧毛红椿群体遗传分化。为保证遗传完整性及保持群体的多样性水平,在江西境内可仅选择遗传多样性水平较高的九连山与官山两个群体来开展毛红椿的资源保存以及迁地保护。     

森林生物多样性保护原理概述

热点地区的分析,为我们确定生物多样性保护的策略和优先等级提供了依据;由于人类的剧烈干扰,现在地球上有许多物种和生态系统都处于濒危的境地,热带雨林的生物多样性丧失最为严重;热点地区虽然在地球上所占的面积很小,但却拥有大量的物种,这些地区的生物多样性丧失应特别引起我们注意;每个物种灭绝的难易程度不同,稀有种和长寿命种特别易于灭绝,而关键种一旦受到威胁,依赖于其生存的许多物种也会有灭绝的危险。遗传多样性的丧失也是生物多样性丧失的重要方面,种群内遗传多样性的丧失主要来源于奠基者效应、统计瓶颈效应、遗传漂变和近亲交配４种因素。物种的概念影响到对物种的保护,物种保护应包括物种内遗传多样性的保护;种群的动态调节机制和源—汇种群动态对于生物多样性保护具有重要的意义。种群生存力分析是了解物种濒危机制的崭新手段。群落中的种间关系和自然干扰体系是生物多样性保护中应考虑的重要方面。人为的生境破碎与自然景观的异质性不同,生境破碎会造成边缘效应和拥挤效应等一系列的生物学后果。     

南方红豆杉种源遗传多样性和遗传分化

利用ISSR分子标记对来自10省区15个南方红豆杉代表性种源,研究揭示其种源遗传多样性及地理变化、种源遗传分化等.结果表明:南方红豆杉具有丰富的遗传多样性,物种水平上的遗传多样性为0.419 2,多态百分率(PPL)、Nei's基因多样性(HE)和Shannon信息多样性指数(I)分别变化在80.00%～93.33%、0.339 3～O.3873、O.492 6～O.5615.南方红豆杉种源遗传多样性受其产地经度和纬度非线性共同影响,偏南和偏西地区种源的遗传多样性较低,而偏东和偏北地区种源遗传多样性则较高.因试验的南方红豆杉种源其原产地种群皆是较大的古树群,且片断化的时间较短,加上其特有的繁育特性,种源问基因分化系数为O.1211,仅有8.75%的遗传变异存在于种源间,而91.25%的遗传变异来自于种源内.UPMGA聚类结果还显示,除福建武平和武夷山2个较小种群的种源外,试验种源可按地域大致划分为偏东和偏北,及偏南和偏西2个种源区.     

Population management: potential impacts of advances in genomics

Even with advanced gene technologies continued population improvement remains a key foundation for future genetic gain in forest trees. Currently, this is served by maintaining genetic diversity while capturing genetic improvement, often through structuring populations into a genetic hierarchy, setting population sizes, and managing pedigrees and inbreeding. In the future, information from genomic technologies will complement classical approaches, such as common-garden field experiments, for characterizing the genetic base and measuring and monitoring genetic diversity. This will entail directly measuring DNA sequence diversity of both selectively neutral markers and functional genes. Calibrating neutral marker diversity against functional diversity will become easier with functional genomics. For maintaining pedigree and managing inbreeding, genomic information can be used to relax some traditional tenets of population management. With future knowledge of functional polymorphisms, the better understanding of the nature and origins of genetic variation should enhance management of populations to both conserve genetic diversity and exploit it by more efficient selection. Where fungal diseases threaten biotic crises, very large populations may be needed, the requisite sizes often being very uncertain. Gene discovery holds enormous promise, but depends heavily on comparative genomics, capitalizing on genomic information from Arabidopsis, Populus and Eucalyptus, and the increasing numbers of accessible ESTs. Much greater insights into non-codon mutational processes and rates should also guide population management. A key challenge, however, will be to utilize information and apply tools cost-effectively. Also, very detailed genomic information, exemplified by the poplar-genome sequencing, may allow earlier adaptation of technology and development of new information in angiosperms than in gymnosperms.     

大花黄牡丹遗传多样性的SRAP分析

应用SRAP标记对西藏特有植物大花黄牡丹的遗传多样性进行研究。用16对引物从5个自然居群79个单株中共检测到396个有效位点,其中多态性位点357个。在物种水平上,多态位点百分率(Ppl)为90.15%,Shannon表型多样性指数(Ηsp)平均为0.2521;居群水平上的Ppl为31.82%,Shannon表型多样性指数(Ho)为0.0694～0.3428,平均值(Ηpop)为0.1307。上述遗传参数表明,大花黄牡丹具有丰富的物种遗传多样性,5个居群中自然居群C的遗传多样性最高(Ppl=82.32%,Ho=0.3428)。据AMOVA分析结果,总的变异中有41.58%的变异存在于居群间,58.42%的变异存在于居群内,居群分化较显著(ΦST=0.4158,P<0.001),由POPGENE1.32得到的居群间遗传分化系数GST(0.4309)和Shannon表型多样性指数计算的居群间遗传多样性所占比例(0.4816)也表明了类似的遗传结构。Mantel检测表明地理距离和Nei’s遗传距离间相关不显著(P>0.05)。利用NTSYSPC(2.1)软件构建大花黄牡丹5个居群79个个体的UPGMA聚类图,遗传相似系数变幅在0.47～0.99,大多数居群内的个体表现出较为密切的亲缘关系(如居群B,D,E),但也有一些居群的个体未聚在一起(如居群C)。依据大花黄牡丹居群遗传变异特点,初步探讨其保护和利用策略。     

Genetic and functional leaf traits variability of Quercus laurina along an oak diversity gradient in Mexico

The ecological literature has documented the effects of plant hybridization on phenotypic variation, and dominant, intermediate, or novel morphological, chemical and physiological traits in hybrids. It is important to understand the ecological consequences of hybridization by evaluating their impact on phenotypic expression of functional traits. We evaluated the relationship between genetic diversity of Quercus laurina and functional foliar traits along an oak diversity gradient. We selected five study sites that represent an oak diversity gradient where Q. laurina is present. Using chloroplast and nuclear microsatellites, we evaluated genetic diversity, measured functional foliar traits of Q. laurina in each site and assessed the effects of local climate variables on the oak community and functional traits. We found a greater abundance of Q. laurina in all study sites. We did not find a relationship between the number of accompanying red oak species and the population genetic diversity in Q. laurina, but higher genetic diversity was found in all study sites in comparison with European oak species. Sites with more oak species had more variation of foliar functional traits. Our results do not support the hypothesis that predicts higher levels of genetic diversity of Q. laurina in communities with greater oak diversity from the same section, but we demonstrated an increase in the foliar functional traits of Q. laurina associated with oak richness and climate variables. We highlight the need to consider environmental and ecological variables linkages as regulatory mechanisms of the phenotypic plasticity expressed in changes of some functional attributes of oaks.

     

Genetic diversity of Populus euphratica populations in northwestern China determined by RAPD DNA analysis

Five Populus euphratica Oliver populations in northwestern China were analyzed using RAPD DNA markers to determine genetic diversity among and within populations. One hundred-and-five polymorphic bands were observed, ranging in size from 250 bp to 1700 bp, using 10 primers. Only one population on the north side of the Tianshern Range had a unique band common to all individuals that was not found in individuals from populations in the Tarim River valley. Intra-population genetic diversity was high in two populations along the Tarim River and low in the other three populations. There was no significant correlation between genetic distances and geographic distances. The result of correspondence analysis shows that the individuals from the three populations with low genetic diversity are isolated from each other. The result of cluster analysis based on genetic distance shows that the population in the Tianshern Range is genetically distant from the other populations. These results suggest that the Tianshern Range population was genetically isolated from the other populations.     

Genetic Diversity of RAPD Mark for Natural Davidia involucrata Populations

The genetic diversity and genetic variation within and among populations of five natural Davidia involucrata populations were studied from 13 primers based on random amplified polymorphic DNA (RAPD) analysis. The results show that natural D. involucrata population has a rich genetic diversity, and the differences among populations are significant. Twenty-six percent of genetic variation exists among D. involucrata populations, which is similar to that of the endangered tree species Liriodendron chinense and Cathaya argyrophylla in China, but different from more widely distributed tree species. The analysis of the impacts of sampling method on genetic diversity parameters shows that the number of sampled individuals has little effect on the effective number of alleles and genetic diversity, but has a marked effect on the genetic differentiation among populations and gene flows. This study divides the provenances of D. involucrata into two parts, namely, a southeast and a northwest provenance. Translated from Scientia Silvae Sinicae, 2004, 40(4) (in Chinese)