日本囊对虾4个地理群体线粒体16S rRNA序列及遗传结构分析

对我国东南沿海日本囊对虾(Marsupenaeus japonicus)的4个地理群体广东群体(GD)、台湾群体(TW)、福建群体(FJ)和浙江群体(ZJ)的线粒体16S rRNA基因片段进行PCR扩增,对产物进行测序后分析。经比对获得470bp的核苷酸分析序列,发现了16个变异位点,得到了10种单倍型。广东、台湾、福建和浙江群体的核苷酸多样性依次分别为0.0008、0.0010、0.0051、0.0015,各群体均存在独有的单倍型和共有单倍型。群体遗传距离分析表明各群体间保持着一定的遗传差异,其中福建群体与其他群体之间存在着较远的遗传距离并保持了较高的遗传多样性。另外,利用其423bp的16S rRNA同源序列探讨了对虾科6个属共12种对虾的系统进化关系,囊对虾属与沟对虾属亲缘关系较近聚为一支,其他4个属的10种对虾聚为一支。     

南海野生斑节对虾的线粒体16S rRNA基因序列单倍型分析

采用聚合酶链式反应(PCR)技术对我国南海海域5个地点(三亚、深圳、阳江、湛江、北海)的野生斑节对虾100个个体的mtDNA 16S rRNA序列进行扩增,扩增产物经纯化后进行测序.用Clustal_X排序软件对所得的100个mtDNA 16S rRNA序列进行比对.通过ARLEQUIN软件对所得100个mtDNA 16S rRNA序列进行比较分析,共检测出28个变异位点,19种单倍型.19单倍型序列的碱基组成显示出较高的A T比例(69.0%).19种单倍型序列的遗传距离在0.002～0.033.根据构建的单倍型进化关系网,5个地点群体中的单倍型呈现一种混杂的分布格局.此外,根据单倍型在5个地点群体出现的频率和单倍型进化关系网,单倍型7是最为原始的单倍型,其他18种单倍型均起源于单倍型7.     

基于线粒体COⅠ序列的南海北部栉江珧遗传多样性分析

为了解南海栉江珧(Atrina pectinata)的群体遗传变异特征, 研究利用线粒体DNA COⅠ(细胞色素氧化酶亚单位Ⅰ)基因部分序列对7个群体共191个栉江珧个体进行群体遗传多样性和遗传结构分析。结果显示: 在600 bp长的序列中, 共检测到113个核苷酸变异位点, 定义了73个单倍型。南海北部栉江珧总体呈现较高的单倍型多样性(0.8996)和较高的核苷酸多样性(0.0257), 但L1组内6个群体(汕头、阳江、湛江、海口、琼海、北海)呈现较高的单倍型多样性(0.8133—0.9286)和较低的核苷酸多样性(0.0033—0.0045)。单倍型系统发育树和网络支系图将7个群体划分为L1和L2(防城港群体)两大类群, 但L1组单倍型并未表现出与地理位置相对应的谱系结构。F_st分析显示, L1组内6个群体间不存在明显的遗传分化(F_st= –0.0200— –0.0055, P>0.05), 但L1组与L2组间存在极显著的遗传分化(F_st=0.8729—0.8821, P<0.01)。L1组的Tajima’s D检验(D= –2.3190, P=0)和Fu’s F_s检验(F_s=–26.8316, P=0)均为显著负值, 核苷酸不配对分布呈明显的单峰分布; L2组的Tajima’s D检验(D=–1.4320, P=0.0565)为不显著负值, Fu’s F_s检验(F_s=4.9540, P=0.9620)为不显著正值。以上数据说明, L1组和L2组栉江珧可能已经分化为两个群体, L1组内6个群体具有频繁的基因交流, 导致了较高的遗传同质性。     

淮河水系日本沼虾群体遗传结构和系统演化的线粒体COI序列分析

测定了淮河水系17个日本沼虾(Macrobrachium nipponense)野生群体共248个个体的线粒体细胞色素氧化酶亚基I(COI)部分序列,获得623 bp核苷酸片段,包括48个变异位点,定义了31个单倍型,共享单倍型有12个,整体单倍型多样性和平均核苷酸多样性均处于中间水平。AMOVA分析表明,17个群体间的遗传分化系数Fst=0.041 3(P0.05),群体间遗传分化较小。Kimura 2-paramter遗传距离在五河与焦岗湖、花家湖及瓦埠湖群体间最大,为0.014,在高邮和邵伯湖群体之间最小,为0.003。MP系统树与单倍型进化网络关系图具有较高的一致性,31个单倍型被分为3个进化枝,其中一个进化枝主要以下游群体为主,另外2个进化枝主要以中游群体为主。群体中性检验、错配分析表明,淮河日本沼虾近期曾经历过种群扩张。     

长江中下游褶纹冠蚌10个群体COI基因序列变异分析

以线粒体CO I基因为分子标记,对长江中下游褶纹冠蚌(Cristaria plicata)10个群体共200个个体的遗传多样性进行了研究.获得了620 bp的同源序列,A+T的平均含量为60.1%,明显高于G+C含量(39.9%),有105个核苷酸变异位点,占全部碱基数的17%,转换和颠换之比达到8.7,检测到了58个单倍型(GenBank登录号:EU698893～EU698950),Hap-5是主体单倍型,占总个体数的41%.褶纹冠蚌鄱阳湖群体(PY)平均核苷酸差异数和核苷酸多样性指数均最高,分别为25.426和0.041 01,太湖群体(TH)和衢州群体(QZ)遗传多样性参数较低.基于群体间遗传距离构建的NJ系统树中,洪泽湖内的3个群体与巢湖群体首先聚为一支,然后与由钱塘江群体、太湖群体、衙州群体和洪湖群体聚成的分支聚在一起,而后与洞庭湖群体聚在一起,最外侧一支为鄱阳湖群体.分子方差分析(AMOVA)得出群体间的遗传分化指数(Fst)为0.208 1(P<0.001),说明我国褶纹冠蚌不同群体间存在一定的遗传分化.     

松江鲈线粒体DNA控制区结构和遗传多样性分析

为探讨松江鲈(Trachidermus fasciatus Heckel)线粒体控制区特征及其群体遗传结构, 研究测定分析了中国和日本沿海共8个群体的线粒体控制区序列, 分析了其结构特征, 识别出终止序列区(ETAS)、中央保守区(CD)和保守序列区(CSB)的特征序列。遗传多样性分析结果显示: 69个松江鲈个体共检测到47个单倍型, 呈现出核苷酸多样性(0.0079)较低和单倍型多样性(0.978)较高的特点。单倍型邻接关系树和单倍型网络关系图均显示松江鲈分为中国和日本两大世系。遗传分化系数(Fst)和分子方差分析(AMOVA)结果表明, 松江鲈中国群体和日本群体之间存在的遗传差异较显著, 中国沿海各群体之间亦存在着一定程度的遗传差异, 该分化主要由历史环境变动、当代环境因素和自身生态习性等原因造成。     

长江中游鳊群体的遗传多样性

采用线粒体DNA(mt DNA)细胞色素b基因(cytb)和控制区序列,分析长江中游宜都、沙市、燕窝、团风等4个产卵场鳊种群的遗传多样性和遗传结构。结果表明:长江中游鳊群体cytb序列共检出82个多态位点,86种单倍型,平均单倍型多样性指数(Hd)和核苷酸多样性指数(Pi)分别为0.930和0.00244;控制区序列共检出变异位点46个,单倍型76种,Hd指数和Pi指数分别为0.972和0.00505;构建的单倍型网络结构和分子方差分析(AMOVA)显示,4个群体的遗传变异绝大部分来自群体内部,群体间无显著遗传分化;群体间的分化指数(FST)、平均基因流(Nm)和平均K2-P遗传距离均表明,4个鳊地理群体间存在广泛的基因交流,未发生明显群体遗传分化;中性检验表明,鳊历史上发生了群体扩张,扩张时间在第四纪冰期后期。     

三个野生群体日本囊对虾遗传多样性的SSR分析

为了解野生种群日本囊对虾遗传分化和改良遗传育种,用SSR技术对福建厦门(XM)、广东湛江(ZJ)、广西北海(BH)3个地区野生日本囊对虾进行遗传多样性的研究。采用了10对微卫星引物对3个野生种群进行分析,10个微卫星位点在3个种群中均表现为高度的多态性,每个位点平均检测到3.87个等位基因;平均多态信息含量为0.5893;3个群体的观测杂合度分别为0.6243、0.5704、0.4661,全部群体观测杂合度平均为0.5536;期望杂合度分别为0.7193、0.6189、0.6226,全部群体平均期望杂合度为0.6536。这说明3个野生种群在10个微卫星位点上均具有丰富的遗传多样性。基于Nei's遗传距离的聚类分析显示厦门群体和湛江群体的遗传距离较近。     

长江中下游湖泊短颌鲚线粒体控制区遗传多样性分析

为探明长江中下游不同湖泊中短颌鲚(Coilia brachygnathus)遗传多样性水平和遗传分化程度,以洞庭湖、长湖、巢湖3个地理群体作为研究对象,采用线粒体控制区序列为分子标记,分别应用软件Dna SP 5.0、Arlequin3.1.1、MEGA5.0和Network 5.1进行了遗传参数统计和单倍型间分子变异分析(AMOVA),构建邻接系统树及单倍型网络图。对长江中下游短颌鲚野生群体的遗传多样性和遗传结构进行分析。结果显示,用来分析的1 236 bp D-loop区序列中共90个变异位点,54个简约信息位点。长江中下游3个地理群体中共发现58个单倍型,单倍型多样性(h)范围0.949~0.982,核苷酸多样性范围0.004 99~0.006 21,说明长江中下游3个湖泊短颌鲚地理群体具有较高的遗传多样性水平。3个短颌鲚地理群体遗传分化指数(Fst)为0.265 95,呈现出中等程度的分化水平,主要表现在巢湖群体与其他群体之间处于中等程度分化水平。依据遗传距离构建系统发育树及单倍型网络图也出现相类似结果。     

珠江源头入侵种波氏吻虾虎的遗传多样性分析

为了解入侵种波氏吻虾虎Rhinogobius cliffordpopei在珠江源头地区的遗传多样性分布特征及其影响成因,本研究以线粒体细胞色素b(cyt b)基因为分子标记,对珠江源头的9个水库自然种群进行了遗传多样性与遗传分化分析。获得该物种cyt b基因全序列1 141 bp,其中保守位点1 072个,变异位点69个,无插入和缺失位点。96只个体具有5个单倍型,群体单倍型多样性为0.359±0.059,核苷酸多样性为0.021±0.010,表现为低单倍型多样性与高核苷酸多样性的群体遗传特征。以外群子陵吻虾虎R.giurinus、褐吻虾虎R.brunneus和短吻红斑吻虾虎R.rubromaculatus构建的分子系统发育树和网络分支图显示,波氏吻虾虎群体的所有单倍型与外群物种分开,构成一个单系群,并分化为2个明显的系统分支。分子变异分析结果表明,种群间和种群内的遗传变异率分别为62.99%、37.01%,固定指数为0.630(P<0.01),证实波氏吻虾虎群体形成了显著的遗传分化结构。波氏吻虾虎在珠江源头入侵地具有较高的遗传多样性水平与显著的遗传结构,入侵种群可能受到了奠基者事件和遗传瓶颈效应的影响,而多次人为引入和水利大坝的隔离作用可能为该物种扩散分布和积累突变提供了条件。研究结果将为防治波氏吻虾虎的入侵危害及保护土著鱼类物种多样性提供科学指导。     

四种绒螯蟹分子分类与系统发育

利用PCR技术,扩增了中华绒螯解、狭额绒螯蟹线粒体16SrDNA片段,经测序,与GenBank数据库中的日本绒螯解16SrDNA同源序列进行比较。结果显示,在长为376bp的16SrDNA同源序列中有33个多态性核革酸位点（8．78％）,其中种间多态性核苷酸位点28个（7．45％）,种间差异远大于种内差异。引入方蟹科其它近缘种类厚纹蟹、相手蟹和张口蟹的16SrDNA同源序列与上述4种绒螯蟹比较分析,MP法和NJ法构建的分子系统树表明：中华绒螯蟹与日本绒螯蟹亲缘关系最近,首先聚在一起,然后与台湾绒螯蟹聚为一支,狭额绒螯蟹则为相对独立的一支,且进化速度大于前3种绒螯蟹,但最后与前者仍聚在同一组,狭额绒螯蟹只是绒螯蟹属系统进化中的一个侧支,故本研究结果不支持Sakai（1983）和Guo等（1997）把狭额绒螯蟹和台湾绒螯蟹各自立为新属的观点。     

青岛近海路氏双髻鲨群体遗传学分析

研究采集了青岛近海23尾路氏双髻鲨(Sphyrna lewini), 通过线粒体DNA控制区片段对其遗传多样性进行分析。研究结果显示: 在23个个体的控制区序列上存在13个变异位点, 未检测到插入/缺失位点; 检测到7个单倍型, 其中3个为个体共享单倍型(Hap1、Hap3和Hap5), 4个为个体独有单倍型; 青岛近海路氏双髻鲨呈现中等水平的单倍型多样度和较低的核苷酸多样度; 与已报道的日照、霞浦群体间的遗传分化指数F_st值分别为–0.0571和–0.0328, 表明青岛群体与其他两个群体间不存在显著差异。以Sphyrna zygaena为外群构建NJ系统树显示本研究中7个单倍型共分成两支, 分别与来自太平洋、印度洋的单倍型类群聚类。中国近海的路氏双髻鲨作为一个具有较低遗传多样性的濒危物种, 其资源保护更应该引起足够的重视。     

Population genetic structure of the tiger prawn (Penaeus monodon) in the coastal waters of South China, based on mitochondrial DNA control region sequences

Genetic variation and population structure of Penaeus monodon in the coastal waters of South China were detected using mitochondrial DNA control region sequences. Eighty individuals were collected at Sanya, Shenzhen, Zhanjiang and Beihai; 69 haplotypes with 157 polymorphic sites were detected. Nucleotide diversity (π) of the combined samples (6.16 ± 3.01%) was much higher than many other species in Chinese seas, such as Penaeus japonicus , Portunus trituberculatus , and Acanthopagrus schlegeli . Genetic differentiation was significant between Beihai and Sanya (pairwise F _ST = 0.09836, P < 0.05), and between Beihai and Shenzhen (pairwise F _ST = 0.12153, P < 0.05). Significant genetic differentiation among all populations was found by analysis of molecular variance ( amova ) ( F _ST = 0.053, P = 0.037 < 0.05). The upgma dendrogram of the four populations showed Sanya and Shenzhen as the closest to each other, with Beihai having the greatest genetic distance from Sanya and Shenzhen. The tiger prawn of the coastal waters of South China should therefore be bred as two separated stocks, avoiding inbreeding or outbreeding selection of P. monodon in the captive breeding program. According to our results one source population is Beihai, and the others are from Sanya and Shenzhen.     

基于ITS2和16S rRNA的西施舌群体遗传差异分析

目前,我国西施舌群体分子遗传差异研究结果存在争议。分析我国南北沿海（9个群体）、与广西北海毗邻的越南（1个群体）西施舌核DNA的内转录间隔区2（ITS2）和线粒体DNA的16S rRNA基因（16S）片段核苷酸序列及其二级结构,为解决争议问题提供分子生物学资料。扩增获得西施舌ITS2片段和16S序列,其长度分别为389-402 bp和306 bp,加之下载序列共147条;序列分析显示,74个ITS2序列共有17种基因型,73个16S序列有15种单倍型,其中,长乐（CL）群体独享9种ITS2基因型和5种16S单倍型,非长乐群体（nCL）多数为群体间交叉共享1种或几种基因（单倍）型;基因（单倍）型核苷酸变异位点占5.7%（ITS2）和11.8%（16S）;基于ITS2和16S的CL群体和nCL群体间的遗传距离与群体内遗传距离之比分别为2.42和11.08,nCL群体间的平均遗传距离均为0.007;二级结构显示CL群体ITS2的9种基因型和16S的5种单倍型均区别于nCL群体,nCL的ITS2和16S二级结构分别相似;ITS2和16S基因的系统发育分析显示,CL西施舌形成支持率很高（98,96）的单系支,而nCL群体则交叉聚为另一支（98,96）。研究结果揭示,福建西施舌是腔蛤蜊属（Coelomactra）的一个新种。     

Molecular phylogeny of a red-snow-crab species complex using mitochondrial and nuclear DNA markers

Nucleotide sequence variation of mitochondrial DNA COI and nuclear rRNA gene regions was used to reconstruct phylogenetic relationships for the red-snow-crab species complex, including the red snow crab, Chionoecetes japonicus, its nominal subspecies, C. japonicus pacificus, and the triangle tanner crab, C. angulatus. The topologies of the Bayesian and neighbor-joining (NJ) trees of the COI and of NJ trees of rRNA sequences placed C. japonicus and C. angulatus in a single clade. The net sequence divergence between these taxa was d(net) = 0.000 in COI, and strongly suggests that these taxa represent a single species. In contrast, haplotypes in C. j. pacificus clustered separately from the C. japonicus - C. angulatus clade. Net sequence divergence from C. japonicus - C. angulatus to C. j. pacificus was d(net) = 0.026 in COI, indicating that C. j. pacificus should be elevated to a separate species, C. pacificus. A 165 bp insert appeared in the rRNA gene of C. j. pacificus, but was absent in the remaining species of Chionoecetes. This autapomorphic condition in C. j. pacificus adds support for an independent evolution of this taxon. Evolutionary divergences between these taxa may reflect contrasting evolutionary process influenced by ocean bathymetry.     

Genetic and geographical differentiation of <Emphasis Type="Italic">Pandaka</Emphasis> gobies in Japan

The mitochondrial DNA (mtDNA) phylogeny of Japanese Pandaka species (Perciformes: Gobiidae) was inferred from partial nucleotide sequences of the mitochondrial 12S and 16S rRNA genes (1083bp). The resultant mtDNA tree showed two major clades (clade I and clade II), which were inconsistent with the present taxonomic classification. One of the major clades was further divided into two geographical groups, distributed on the Japanese Major Islands (clade I-A) and from Amami-oshima Island to Iriomote Island (clade I-B). The mtDNA haplotypes in clade II were found only on Iriomote Island. The mtDNA divergences in clade I indicated that the Japanese Major Island (clade I-A) and Ryukyu (clade I-B) groups have been geographically isolated from each other for millions of years, based on the putative molecular divergence rate. The geographical distributions of mtDNA haplotypes in clade I-A and clade I-B also suggested that Pandaka gobies had not dispersed to distant offshore islands, indicating that their geographical differentiation may be closely associated with the geological history of the Japanese and Ryukyu Archipelagos.This revised version was published online in January 2005 with corrections to the repetition of the 1st authors name.     

Phylogenetics and population genetics of the louse fly,Lipoptena mazamae,from Arkansas,U.S.A.

Louse flies, also known as deer keds (Lipoptena mazamae Rondani), infest cervids such as white‐tailed deer, Odocoileus virginianus and vector pathogens such as Anaplasma and Bartonella schoenbuchensis to cattle and humans, respectively. The population genetic structure of 30 L. mazamae collected from white‐tailed deer in four regions of Arkansas, U.S.A., designated by county boundaries, was examined using DNA sequences of a 259‐bp region of the mitochondrial DNA rRNA 16S gene. Of the 259 nucleotide characters, 33 were variable and 6 haplotypes were identified. Two haplotypes occurred only once (haplotype 3 and 4), whereas two other haplotypes occurred in 43% (haplotype 1 in two regions) and 40% (haplotype 6 in three regions) of the samples. Phylogenetic relationships of the six L. mazamae haplotypes were constructed with other Hippoboscid and Glossinid samples and two clades resulted. Clade 1 was located in the north and western Ozarks whereas clade 2 was found in the northern and eastern Ozarks. Results from the present study indicate that Lipoptena may be a polyphyletic genus; consequently, more research into genetic variation within this genus is necessary.     

A Phylogenetic Study of the Origin of the Domestic Pig Estimated from the Near-Complete mtDNA Genome

The near-complete pig mtDNA genome sequence (15,997 bp) was determined from two domestic pigs (one Chinese Meishan and one Swedish Landrace) and two European wild boars. The sequences were analyzed together with a previously published sequence representing a Swedish domestic pig. The sequences formed three distinct clades, denoted A, E1, and E2, with considerable sequence divergence between them (0.8–1.2%). The results confirm our previous study (based on the sequence of the cytochrome B gene and the control region only) and provide compelling evidence that domestication of pigs must have occurred from both an Asian and a European subspecies of the wild boar. We estimated the time since the divergence of clade A (found in Chinese Meishan pigs) and E1 (found in European domestic pigs) at about 900,000 years before present, long before domestication about 9000 years ago. The pattern of nucleotide substitutions among the sequences was in good agreement with previous interspecific comparisons of mammalian mtDNA; the lowest substitution rates were observed at nonsynonymous sites in protein-coding genes, in the tRNA and rRNA genes, while the highest rates were observed at synonymous sites and in the control region. The presence of Asian clade A in some major European breeds (Large White and Landrace) most likely reflects the documented introgression of Asian germplasm into European stocks during the 18th and 19th centuries. The coexistence of such divergent mtDNA haplotypes for 100+ generations is expected to lead to the presence of recombinant haplotypes if paternal transmission and recombination occur at a low frequency. We found no evidence of such recombination events in the limited sample studied so far. Received: 19 April 2000; Accepted: 15 November 2000