基于ISSR标记的南方红豆杉野生种群和迁地保护种群的遗传多样性和遗传结构分析

采用ISSR标记方法,对南方红豆杉〔Taxus chinensis(Pilger)Rehd.var.mairei(Lemée et Lévl.)Cheng et L.K.Fu〕3个野生种群(包括江西黄港和黄沙种群以及福建枫溪种群)、2个迁地保护栽培种群及2个迁地保护衍生种群(均位于江苏南京中山植物园和江西庐山植物园)的遗传多样性和遗传结构进行了分析和比较。结果显示:用8个引物从南方红豆杉的基因组总DNA中共扩增出73条带,其中多态性条带62条。2个迁地保护衍生种群的多态性条带百分率(PPB)、Nei’s多样性指数(h)和Shannon信息指数(I)较高,3个野生种群的PPB、h和I值总体上居中,而2个迁地保护栽培种群的PPB、h和I值较低。合并后的迁地保护衍生种群以及野生种群均有较高的遗传多样性,二者的PPB、h和I值相近,分别为78.08%和82.19%、0.207 6和0.205 8、0.322 9和0.325 9;但二者的遗传结构存在差异,迁地保护衍生种群的遗传分化系数(GST)为0.068 9,明显低于野生种群(0.168 5)。合并后的迁地保护栽培种群的遗传多样性相对较低,PPB、h和I值分别为60...     

野生马氏珠母贝子一代的遗传多样性

分析了海南省三亚与广西省北海两地野生贝群体内交配所得子代两群体 (SS、BB)和群体间交配(SS♀ ×BB♂ →BS)所得子代群体 (BS)各 8个个体的遗传多样性。筛选的 2 0个含 1 0碱基的随机引物中 ,其中 1 4个产生稳定的可重复的多态扩增结果 ,共检测出 1 2 4个位点。用修正的Shannon表型多态性指数量化三个群体的遗传多态度 ,SS、BB、BS三群体的多态度分别为 0 2 47,0 2 3 7,0 2 61。SS与BB ,SS与BS ,BB与BS三群体间的遗传相似度分别为 87 2 4% ,80 3 9% ,83 90 %。讨论了不同地域之间进行马氏珠母贝育种及遗传多样性保护工作的可行性     

南方红豆杉迁地保护小种群适应性进化机制研究

为了解南方红豆杉迁地保护种群的适应性进化机制,以南京中山植物园内南方红豆杉迁地保护栽培种群和扩散的衍生种群为材料,以引种初始地江西野生种群为对照,对南方红豆杉群落的结构、遗传多样性及遗传结构进行分析和研究。结果表明,南方红豆杉野生种群和迁地保护种群均维持着较高水平的遗传多样性,其中野生种群遗传多样性稍高于迁地保护小种群,但迁地保护种群中南方红豆杉个体密度大于野生种群。同时,种群内的遗传变异所占比例大于种群间的。整体来看,南方红豆杉迁地保护种群还处于演替早期,存在不明显的奠基者效应,有进一步演替发展的可能。     

不同地理分布区紫椴种群的遗传多样性变化

该文运用ISSR分子标记技术,研究不同纬度、不同海拔紫椴(Tilia amurensis)天然种群的遗传多样性变化规律,探讨紫椴种群的濒危机制,为紫椴遗传资源的有效保护和合理利用提供理论依据。14个ISSR引物扩增结果显示:紫椴种群多态位点百分率(P)为93.85%,基因多样性指数(H)和Shannon多样性指数(I)分别为0.243 3和0.380 3。不同纬度紫椴种群的遗传多样性由高到低依次为:CBS种群>BL种群>NA种群>LS种群>FHS种群>DYS种群;不同海拔紫椴种群的遗传多样性由高到低依次为:H1种群>H2种群>H3种群>H4种群>H6种群>H5种群。紫椴种群的遗传多样性没有随纬度的升高而呈现规律性的变化,但随海拔的升高呈现遗传多样性逐渐降低的趋势。用AMOVA进行分子方差分析表明,紫椴种群间遗传分化较大,遗传变异主要来自种群内部。紫椴种群间遗传距离与地理距离没有相关性,但随着海拔的逐渐增高种群间遗传距离增大。该研究结果揭示,紫椴种群具有较高的遗传多样性,遗传多样性不是导致其种群濒危的主要原因,导致其濒危的主要原因可能与人为采伐、生境破坏和生境退化及其自身生物学特性所导致的自然更新不良有密切关系。因此,应加强对紫椴生境的保护,防止人为因素对紫椴天然种群的进一步破坏。     

马氏珠母贝(Pinctada martensii)黑壳色养殖群体SSR遗传多样性分析

本研究利用微卫星分子标记技术,对马氏珠母贝(Pinctada martensii)F8代黑壳色普通养殖群体和黑壳色选育群体2个群体共78个个体的遗传多样性进行分析.结果显示,10个SSR位点共扩增出34个等位基因,各位点的等位基因数为2～6个,平均等位基因数为3.4个,黑壳色普通养殖群体和黑壳色选育群体等位基因数(Na)分别为3.3和3.2,有效等位基因数(Ne)分别为1.993 5和1.931 0;香农多样性指数(Ⅰ)为0.801 3和0.746 4;观测杂合度(Ho)分别为0.330 0和0.286 7;期望杂合度(He)分别为0.469 8和0.434 3;多态信息含量(PIC)分别为0.403和0.377.Hardy-Weinberg平衡检验发现,2个群体分别有6个、7个位点偏离平衡(P＜0.05),其中在4个相同位点中偏离平衡,且均表现为杂合子缺失(Ho＜He).两群体的遗传分化指数(Fst)、近交系数(Fis)、基因流(Nm)分别为0.0372和0.309 0和6.471 7.研究结果显示:经过连续的继代选育,马氏珠母贝黑壳色选育群体仍然保持适中的遗传多样性,具备作为选育材料的潜力.     

基于ISSR分子标记的孑遗濒危植物四合木遗传结构分析

为阐明中国西北干旱区单属种孑遗濒危植物四合木(Tetraena mongolica)种群间的遗传分化和基因流。利用6个不同地理分布的四合木种群作为试验材料,从30条UBC引物中筛选出6条引物,并且对ISSR扩增反应体系和扩增程序进行了合理的优化,6个引物扩增出370个条带,多态性条带占71%。分析结果如下:①Nei’s基因多样性指数(He)为0. 316 8,Shannon’s多态性信息指数(I)为0. 458 6。表明四合木在不同种源间的遗传多样性水平差异较小;②群体多态性位点百分率在70. 00%~83. 33%,Nei’s基因多样性指数范围0. 286 5~0. 350 8,Shannon’s多态性信息指数在0. 423 6~0. 504 9。6个群体间的遗传分化系数Gst为0. 125 3,表明群体间具有一定程度的遗传分化;③6个种群的基因流(Nm)为3. 491 5>1,说明6个种群间存在一定的基因流,可以防止遗传漂变引起的遗传分化;④通过聚类分析,将6个不同地理种群的四合木分为3类,千里沟种群、伊克布拉格种群和巴拉贡种群先聚成第一大类,再与磴口—桃司兔种群聚成第二大类,而四合木自然保护区种群和甘德尔山种群则组成第大三类,这说明距离因素是影响四合木种群间遗传分化的主要原因,但不同生境条件也对四合木种群的遗传分化产生了影响。     

马氏珠母贝4个壳色选育系F_1遗传结构的AFLP分析

本研究从湛江流沙港马氏珠母贝养殖群体中挑选不同壳色个体为亲本,共构建了黑(BS)、红(RS)、黄(YS)和白壳色(WS)4个壳色选系F1,然后分别在4个壳色选育系F1中随机取样,利用3对AFLP引物分析其遗传结构与遗传分化。结果表明,每对引物的扩增位点数在104～109之间,共得到331个扩增位点;BS、RS、YS和WS壳色选系F1的多态位点比例分别为49.2%、49.5%、51.6%和63.4%,Shannon's多样性指数分别为0.1884、0.1886、0.1896和0.1954,4个壳色选育系F1的遗传分化系数(Fst)为0.1972。本研究说明经过一代壳色纯化4个壳色选育系F1出现显著遗传分化,也为马氏珠母贝壳色系选育或选育系间杂交提供了参考依据。     

中国北方球孢白僵菌的遗传多样性和种群遗传结构

将在中国北方13省采集分离的622株球孢白僵菌按省份划分成13个亚种群,其中寄主可以鉴定到目的8目昆虫和蜘蛛目的568株按目划分成9个亚种群,用ISSR(简单重复序列区间)分子标记技术进行遗传多样性和种群遗传结构分析.结果表明:各多样性指数皆显示我国北方地区球孢白僵菌的遗传多样性水平较高,种群的异质性较强.其中内蒙古亚种群的遗传多样性和种群异质性最高,河南亚种群最低;鳞翅目亚种群的遗传多样性和种群异质性最高,蜘蛛目亚种群最低.河南与辽宁亚种群间以及蜘蛛目与螳螂目亚种群间的遗传分化系数以及遗传距离最大,宁夏与陕西亚种群间以及鞘翅目与膜翅目亚种群间最小.按寄主目划分的亚种群间的平均遗传分化系数和平均遗传距离均低于按省份划分的亚种群.这些结果以及基于遗传距离的亚种群聚类分析都证明我国北方球孢白僵菌的遗传谱系与寄主来源和地理来源均无关系.我国北方球孢白僵菌的变异主要是由各不同寄主目内科间及属间的变异造成的,也是由各省不同采集地以及采集地内部不同微生境间的差异造成的.     

基于ISSR分子标记的西藏杓兰种群遗传多样性分析

西藏杓兰(Cypripedium tibeticum)是具有很高观赏和药用价值的兰科植物,已被列为中国优先保护的濒危植物。该研究采用ISSR分子标记技术,对采自中国西部地区的7个西藏杓兰种群进行遗传结构及遗传多样性分析,为中国野生西藏杓兰种质资源的保护提供理论依据。结果显示:(1)从100条ISSR引物中共筛选出12条多态性高、重复性好的引物,共检测出136个位点,多态位点百分率(PPB)达100%,总体Nei's基因多样性指数(H_e)和Shannon信息指数(I)分别为0.318 6和0.484 3,种群间的Nei's遗传距离在0.033 3～0.170 1之间,Nei's遗传相似度在0.843 5～0.967 3之间,总体遗传分化系数(G_(st))和基因流(N_m)分别为0.222 9和1.743 0。(2)基于UPGMA法和邻接法的种群系统聚类结果均显示出四川种群与陕西种群之间存在遗传分化。总体上西藏杓兰种群间遗传分化与地理隔离之间相关性不显著。研究认为,西藏杓兰种群在分子水平上具有丰富的遗传多样性,且四川种群与陕西种群已产生了遗传分化;ISSR分子标记可用于西藏杓兰种群遗传多样性、遗传结构及种群间遗传分化等方面的研究。     

冷蒿种群在放牧干扰下遗传多样性的变化

通过随机扩增多态性 DNA(RAPD)方法检测了放牧干扰下冷蒿种群遗传多样性的变化。 17条 (组 )引物进行 RAPD分析 ,扩增共产生 2 5 4条带 ,其中 2 4 0条为多态性带 ,多态位点百分率达 94 .4 9%。随着放牧强度的增加 ,冷蒿种群多态位点百分数 ,Nei遗传多样性指数、Shannon信息指数均下降 ,种群内个体平均遗传一致度增加。放牧梯度上 4个冷蒿种群 H t=0 .2 116 ,Hs=0 .170 0 ,Dst=0 .0 4 16 ,种群间基因分化系数 Gst=0 .196 5 ,基因流 N*m=2 .0 4 5 1;同时随着放牧强度的增加 ,种群间的 Dst、Gst增加 ,N*m 降低。说明放牧限制了种群间的基因交流 ,使种群发生遗传分化。放牧梯度上的 4个冷蒿种群的遗传距离很小 ,但是随着放牧强度的增加 ,遗传距离在缓慢的增加 ,种群间的遗传一致度降低。根据遗传距离所构建的 U PGMA聚类图中冷蒿 4个种群随着牧压的增加 ,逐级聚在一起。这表明冷蒿种群的遗传分化与放牧强度的关系     

草鱼野生与选育群体线粒体DNA控制区D-loop遗传变异分析

为探究经过2个选育世代后选育群体遗传多样性和遗传结构的变化, 研究对4个野生群体(邗江、九江、石首和吴江)和2个选育世代(F1和F2)进行了线粒体DNA控制区(D-loop)序列的遗传变异分析。实验结果表明, 4个野生群体在单倍型数目(H)、单倍型多样性(H_d)、核苷酸多样性(π)、平均核苷酸差异数(K)水平上均高于2个选育世代, 在2个选育世代内表现为F1代群体的核苷酸多样性(π)和平均核苷酸差异数(K)大于F2代群体, 但单倍型多样性(H_d)小于F2代群体; 单倍型分析结果表明, 6个群体间无共享单倍型, 4个野生群体间共发现2种共享单倍型(Hap1和Hap3), 石首群体和2个选育世代共享1种单倍型(Hap15); 遗传分化指数(F_st)分析结果表明, 邗江、九江、吴江3个野生群体和2个选育世代间存在较大的遗传分化(F_st范围为0.41475—0.55128), 石首群体与F1代群体之间存在较小的遗传分化, 与F2代群体之间存在中等水平的遗传分化, 同时F1代群体与F2代群体之间存在较小的遗传分化; 基于6个群体276个个体构建的邻接(Neighbor-Joining, NJ)进化树和基于27种单倍型构建的单倍型网络图也得到了相似的结论, 即邗江、九江、吴江3个野生群体和2个选育世代间的亲缘关系较远, 石首群体和2个选育世代两两之间的亲缘关系较近。以上结果表明, 经过2个世代的选择育种, 选育群体的遗传结构已发生了变化, 并且随着选育的进行, 选育世代的遗传多样性下降的较为明显, 这警示着我们在今后的育种工作中应适当改变现有的选育方案, 并实时监测选育群体的遗传多样性, 以便为今后进一步的选育工作打下坚实的基础。     

Genetic diversity in wild and reared populations of the Japanese bitterling <Emphasis Type="Italic">Tanakia tanago</Emphasis> (Cyprinidae)

 The Japanese bitterling Tanakia tanago is an endangered cyprinid species; thus, captive breeding programs are being conducted in various facilities as ex situ conservation. To examine the genetic diversity in one wild and three reared populations, and its changes during the process of captive breeding, sequences of the mitochondrial cytochrome b gene and control region were determined. The wild population, collected in 1993, was monomorphic. Although the reared population that originated from the wild population was almost monomorphic, a rare haplotype, distinct from all others by a relatively large sequence divergence, was also observed. In the other reared populations, some degree of genetic diversity had been maintained. A reared hybrid population, which originated from a mixture of three distinct populations, showed the greatest genetic diversity. These results suggest considerable genetic diversity within and among populations of T. tanago in the past. Although a loss of genetic diversity was observed in some year-classes of reared populations, there was no tendency for genetic diversity to decrease as a result of captive breeding, probably because offspring were obtained from multi-year-class parents in the captive breeding program. Accordingly, this breeding method should be appropriate for conserving the genetic diversity of T. tanago. Received: June 12, 2002 / Revised: December 3, 2002 / Accepted: December 16, 2002     

Reduced genetic diversity and significant genetic differentiation after translocation: Comparison of the remnant and translocated populations of bridled nailtail wallabies (Onychogalea fraenata)

Loss of genetic diversity and increased population differentiation from source populations are common problems associated with translocation programmes established from captive-bred stock or a small number of founders. The bridled nailtail wallaby is one of the most endangered macropods in Australia, having been reduced to a single remnant population in the last 100 years. A translocated population of bridled nailtail wallabies was established using animals sourced directly from the remnant population (wild-released) as well as the progeny of animals collected for a captive breeding programme (captive-bred). The aims of this study were to compare genetic diversity among released animals and their wild-born progeny to genetic diversity observed in the remnant population, and to monitor changes in genetic diversity over time as more animals were released into the population. Heterozygosity did not differ between the translocated and remnant population; however, allelic diversity was significantly reduced across all released animals and their wild-born progeny. Animals bred in captivity and their wild-born progeny were also significantly differentiated from the source population after just four generations. Wild-released animals, however, were representative of the source population and several alleles were unique to this group. Both heterozygosity and allelic diversity among translocated animals decreased over time with the additional release of captive-bred animals, as no new genetic stock was added to the population. Captive breeding programmes can provide large numbers of animals for release, but this study highlights the importance of sourcing animals directly from remnant populations in order to maintain genetic diversity and minimise genetic drift.     

Mallard–Black Duck Hybridization and Population Genetic Structure in North Carolina

North Carolina, USA, represents the southern extent of the American black duck's (Anas rubripes) breeding range. Mallards (A. platyrhynchos) are present on the breeding grounds of the American black duck and hybridization is observed between these species; therefore, we assessed the genetic integrity, hybridization rates, and population structure of this local breeding population. We extracted genomic and mitochondrial DNA from chorioallantoic membranes and contour feathers from monitored black duck nests. We then prepared the extracted DNA for analysis using high-throughput DNA sequencing methods (ddRAD-seq). First, we assessed nuclear and mitochondrial population structure, genetic diversity, and differentiation across samples from North Carolina, and compared them against 199 genetically vetted mallards, black ducks, and mallard × black duck hybrids that served as genetic references. Next, we tested for parentage and sibling relationship and overall relatedness of black ducks in North Carolina. We recovered strong population structure and high co-ancestry across genetic markers due to interrelatedness among sampled nests in North Carolina and concluded that black ducks have been locally breeding in this area for a prolonged period of time. Despite a high level of interrelatedness among our samples, nucleotide diversity was similar to the reference continental black duck population, suggesting little effect of genetic drift, including inbreeding. Additionally, we conclude that molecular diversity of black ducks in North Carolina is maintained at reference population levels through the influx of genetic material from unrelated, migrating male black ducks. Finally, we report a hybridization level of 47.5%, covering 3 filial generations. Of identified hybrids, 54.7% and 53% were the direct result of interbreeding between black ducks and captive-reared or wild mallards, respectively. We conclude that because of high rates of interspecific hybridization and successive backcrossing events, introgression from wild and feral mallards is occurring into this population of breeding black ducks and requires careful consideration in future management efforts. © 2021 The Wildlife Society.     

Multi-generational evaluation of genetic diversity and parentage in captive southern pygmy perch (<Emphasis Type="Italic">Nannoperca australis</Emphasis>)

Maintaining genetic diversity within captive breeding populations is a key challenge for conservation managers. We applied a multi-generational genetic approach to the captive breeding program of an endangered Australian freshwater fish, the southern pygmy perch (Nannoperca australis). During previous work, fish from the lower Murray-Darling Basin were rescued before drought exacerbated by irrigation resulted in local extinction. This endemic lineage of the species was captive-bred in genetically designed groups, and equal numbers of F1 individuals were reintroduced to the wild with the return of favourable habitat. Here, we implemented a contingency plan by continuing the genetic-based captive breeding in the event that a self-sustaining wild population was not established. F1 individuals were available as putative breeders from the subset of groups that produced an excess of fish in the original restoration program. We used microsatellite-based parentage analyses of these F1 fish to form breeding groups that minimized inbreeding. We assessed their subsequent parental contribution to F2 individuals and the maintenance of genetic diversity. We found skewed parental contribution to F2 individuals, yet minimal loss of genetic diversity from their parents. However, the diversity was substantially less than that of the original rescued population. We attribute this to the unavoidable use of F1 individuals from a limited number of the original breeding groups. Alternative genetic sources for supplementation or reintroduction should be assessed to determine their suitability. The genetic fate of the captive-bred population highlights the strong need to integrate DNA-based tools for monitoring and adaptive management of captive breeding programs.     

五个罗氏沼虾群体遗传多样性的微卫星分析

利用16对微卫星标记对来自泰国(CP)、缅甸(MN)、孟加拉(BD)和中国(MP和DP)的共5个罗氏沼虾群体进行了遗传多样性和遗传结构的分析。结果显示, 16个微卫星位点均具有较高的多态性, 平均等位基因数(N_a)、期望杂合度(H_e)、Shannon信息指数(I)和多态信息含量(PIC)分别为17.563、0.8316、2.1662和0.7328。5个群体的期望杂合度(H_e)介于0.7025—0.8594, 多态信息含量(PIC)介于0.6538—0.8048, 表明所有群体均具有高度遗传多样性, 遗传多样性水平CP>MP>BD>MN>DP。遗传分化指数(F_st)值介于0.03430—0.17333, 表明所有群体间均有不同程度的遗传分化。16个微卫星位点的F_st值均大于0.05, 均值为0.0977, 与群体间有遗传分化相符。AMOVA分析显示群体间变异占总变异的6.22%, 群体内个体间的变异占总变异的40.72%, 个体内部的遗传变异占总变异的53.07%。基于Nei氏遗传距离构建的UPGMA系统进化树显示, MN群体首先与MP群体聚为一类, 再与DP群体聚为一类, 之后再与BD群体聚为一类, 最后与CP群体聚为一类, 表明中国群体与泰国群体亲缘关系较远。遗传结构分析显示, 参试样本被划分为5个理论群体, 除MP群体中个体遗传结构混杂外, 其余群体中个体遗传结构相对独立。研究为罗氏沼虾种质资源的开发利用和优良品种的选育提供了参考数据。     

华南鲤选育群体不同世代遗传多样性与遗传结构的微卫星分析

为了解人工选育对华南鲤(Cyprinus carpio rubrofuscus)选育群体遗传结构的影响, 采用微卫星技术分析了华南鲤4个连续选育世代(F₁、F₂、F₃和F₄)的遗传多样性和遗传结构。结果显示:在4个选育群体中, 16对微卫星引物共扩增得到99个等位基因, 每个微卫星座位检测到的等位基因数为3—10个, 平均为6.1875个。随着人工连续选育的进行, F₁到F₄的平均等位基因数(N_a)从5.6875下降到4.6755, 平均观测杂合度(H_o)从0.7943下降到0.7135, 平均多态信息含量(PIC)从0.6577下降到0.5834。F₁与其后各代的遗传距离逐代增加(从0.1486上升到0.2181), 遗传相似系数逐代减小(从0.8619下降到0.8041), 而相邻世代间的遗传分化指数(F_st)逐代变小(F₁与F₂为0.062, F₂与F₃为0.058, F₃与F₄则为0.051), 遗传相似性逐步升高。世代间F_st值配对比较结果显示4个世代间的遗传分化处于中等水平, 表明人工选育已对华南鲤选育群体的遗传结构产生了影响。实验结果表明, 华南鲤经过4代选育后, 虽然遗传杂合度和遗传多样性存在下降的现象, 但遗传多样性水平依然较高, 还具有进一步选育的潜力。研究结果为下一步制定华南鲤新品种选育计划提供基础遗传数据。     

Genetic structure and diversity of Portunus trituberculatus in Chinese population revealed by microsatellite markers

By using six polymorphic microsatellite loci, the population genetic diversity and structure of 120 individuals of Portunus trituberculatus were examined in five wild populations representing different geographical and ecological ranges along the coast of China. Middle level of genetic diversity of P. trituberculatus was revealed by observed heterozygosity, allele number and Shannon information index. Pairwise population differentiations were found between all pairs of populations except Beihai (BH) and Qingdao (QD) (P < 0.05). The greatest differentiation was detected between Yingkou (YK) and QD populations. It was inconsistent with the result in previous study using mitochondrial control region, which showed no differentiation between QD and YK population. Recent bottleneck was identified in Ningbo (NB) population under TPM and IAM models, as well as Dandong (DD) and QD populations under IAM model. Additionally, compared with YK, QD, DD and BH populations, lower historical effective population size with lower genetic diversity were detected in NB population, which called for urgent assessment of the ecological and economic potential of NB fisheries.     

Quantifying and managing the loss of genetic variation in a free-ranging population of takahe through the use of pedigrees

Pedigree analysis has clear benefits for the genetic management of threatened populations through the evaluation of inbreeding, population structure and genetic diversity. The use of pedigrees is usually restricted to captive populations and few examples exist of their exclusive use in managing free-ranging populations. One such example is the management of the takahe (Porphyrio hochstetteri), a highly endangered, flightless New Zealand rail at risk from introduced mammalian predators and habitat loss. During the 1980’s and 90’s, as part of the takahe recovery programme, birds were translocated from the sole remnant population in Fiordland to four offshore islands from which introduced predators had been eradicated. The subsequent “island” population, now numbering 83 and thought to be at carrying capacity, has been closely monitored since founding. Detailed breeding records allow us to analyse the island pedigree, which is up to 7 generations deep. Gene-drop analysis indicated that 7.5% of genetic diversity has been lost over the relatively short timeframe since founding (2.1 generations on average; total genetic founders = 31) due to both a failure to equalise founder representation early on and subsequent disproportionate breeding success (founder equivalents = 12.5; founder genome equivalents = 6.6). A high prevalence of close inbreeding will have also impacted on genetic diversity. Predictions from pedigree modelling suggest that 90% genetic diversity will be maintained for only 12 years, but by introducing a low level of immigration from the Fiordland population and permitting the population to grow, 90% GD could be maintained over the next 100 years. More generally, the results demonstrate the value of maintaining pedigrees for wild populations, especially in the years immediately after a translocation event.     

濒危植物秦岭石蝴蝶的SCoT遗传多样性分析

利用筛选到的24条SCoT引物,分析秦岭石蝴蝶人工繁育和野生种群60份材料的遗传多样性和遗传结构,为秦岭石蝴蝶的濒危机制和制定种群保护与修复策略提供理论依据。结果显示:(1)60份秦岭石蝴蝶供试样品的观察等位基因数平均为1.51,有效等位基因数平均为1.31,Nei's基因多样性平均为0.2305,Shannon指数平均为0.3703,表明供试材料种群的遗传多样性较低。(2)种群间的遗传距离与遗传相似系数分析结果表明,3个种群60份供试材料间的遗传相似系数为0.9551~0.9705,平均相似系数0.9634,进一步表明供试材料之间的遗传相似性极高,遗传背景较为狭窄。(3)秦岭石蝴蝶种群分子方差分析结果显示15%的变异来自于种群间,而85%的变异来自于种群内部。综合分析表明,秦岭石蝴蝶各种群内和种群之间的遗传多样性较低,遗传背景狭窄,这可能是秦岭石蝴蝶适应环境能力差,从而导致其濒危的重要原因之一。