大鳍(鱼矞)基于细胞色素b基因序列的遗传变异及生物地理过程

对采集于长江水系、黑龙江水系及海南岛的36尾大鳍(鱼矞)(Acheilognathus macropterus)的细胞色素b基因序列进行了研究分析.发现有须个体和无须个体在分子系统树中处于混合分布状态,各个体相互间遗传变异远小于与外类群(A.chankaensis、A.tokinensis)间差异,统计了其主要形态度量数据,也显示各主要性状数据无显著差异,结果均支持有须个体和无须个体(曾经被鉴定为A.taenianalis)为同一物种,A.taenianalis为A.macropterus的同物异名.序列分析显示,36个个体明显聚合成5个大的分支,其中clade1分支全部由黑龙江水系类群组成,clade5分支由海南岛的1个个体组成,长江水系的所有个体分散在clade2、clade3、clade4这三个分支中,显示出一定的地理相关性.在clade2、3、4中,clade2包括了长江上游的5个个体和长江中游的2个个体,同时还包括了黑龙江的2个个体;clade3包括了中游的2个个体;clade4包括了中游的12个个体,三个分支间又存在明显的遗传变异率(均＞5%),从21个个体在三个分支中的分布情况来看,三者间这种较大的遗传变异率不能由地理隔离解释,故推测,造成同一水系的A.macropterus间出现较明显遗传分化的原因可能与其特殊的性选择生殖方式有关,该生殖方式限制了不同生殖集群间同种鱼类的基因交流.基于系统分支图,计算了各分支间的遗传距离,由结果推测大鳍(鱼矞)的生物地理过程为:海南岛水系类群同大陆类群较早产生隔离,黑龙江水系类群由长江水系类群在晚近时期向北扩散形成.     

广东地区宽鳍(鱼巤)种群遗传变异和亲缘地理

通过分析88尾采自广东境内9条水系的宽鳍(鱼巤)(Zaccop,platypus)线粒体DNA(mtDNA)细胞色素b(Cyt b)基因全序列,初步研究其种群遗传变异和地理格局,所测定的Cyt b基因全序列长1140 bp,其中变异位点98个,简约信息位点75个.共检测到33个单倍型,除鉴江种群只有1个单倍型外,其余8条水系均有多个单倍型.北江、流溪河、鉴江、北流河和罗定江等5个种群有共亭单倍型Hap11,罗定江和北流河之间共享了单倍型Hap4,东江与流溪河共享Hap6,而韩江和榕江共享单倍型Hap29.种群单倍型多样性的平均值(h)为0.908,核苷酸多样性的平均值(π)为0.01961,表现出较高的遗传多样性.系统发育分析(NJ树)显示,宽鳍(鱼巤)种群33个单倍型可分为2个分支,其中来自珠江水系(北江、东江、流溪河、罗定江和北流河)和广东西部独立人海水系(鉴江和漠阳江)的宽鳍(鱼巤)种群聚为一支(分支A),广东东部独立入海水系(韩江和榕江)种群聚为另外一支(分支B).2分支间的遗传距离和碱基差异率均较高(0.0517-0.0549,5.35%-_6.49%),明显大于分支A内(O.0012-0.0099,0.26%-2.11%)和分支B内的值(0.0027,1.58%),但远小于宽鳍(鱼巤)与外类群间的遗传距离和碱基差异率(0.0945-0.1912,8.77%-17.11%).这表明分支A与B之间已有明显的遗传分化,但分化程度来达到物种级水平,韩江和榕汀的种群相对独立,推测可能与莲花山脉的阻隔有关.根据单倍型网络图推测,流溪河可能是广东中西部地区宽鳍(鱼巤)的扩散中心,分别向珠江水系的西江、北江和东江扩散,再向鉴江和漠阳江扩散:另外由扩散中心经东江到榕汀再向韩江扩散.分子变异分析(AMOVA)表明,种群间的遗传变异占38.50%,种群内的遗传变异占66.24%.中性检验和歧点分布分析皆表明广东境内9条水系的宽鳍(鱼巤)在整个种群上保持相对稳定,没有发生明显的种群扩张.     

犁头鳅属鱼类物种地理分化过程

犁头鳅属为中国的特有属,包括犁头鳅和长鳍犁头鳅两个物种,犁头鳅广泛分布于长江中上游,而长鳍犁头鳅则局限分布于闽江水系。本研究对采自长江中上游的犁头鳅20个个体和闽江水系的长鳍犁头鳅8个个体的线粒体细胞色素b（cyt b）基因序列进行分析,以期对犁头鳅属鱼类的物种地理分化过程进行研究。结果显示,犁头鳅不同单倍型之间的遗传变异水平为0.1%—1.8％,平均为0.7%;长鳍犁头鳅各单倍型之间的遗传变异水平为0.6%—1.3%,平均为0.7%;犁头鳅和长鳍犁头鳅单倍型之间的遗传差异也较小,仅为0.2%—1.8%,平均为0.9%。采用邻接(NJ)法和贝叶斯(BI)法构建的分子系统发育树一致显示,该研究中的犁头鳅属鱼类构成一个单系;所有长鳍犁头鳅样本构成一个单系,位于系统发育树的顶部位置;犁头鳅的样本不构成单系,而是形成并系。从形态上看,犁头鳅和长鳍犁头鳅均为有效种。由此推测,在第四纪冰期,长江中下游的犁头鳅沿东海大陆架向南扩散到东南沿海水系,长鳍犁头鳅可能是犁头鳅的一个种群扩散到闽江水系后,由于适应新的环境条件而分化成的一个新物种,剩下的长江流域的犁头鳅种群则构成一个并系类群。本文对于类似的地理物种形成方式也进行了讨论。     

海南岛宽额鳢(Channa gachua)群体遗传变异与生物地理过程

为了解海南岛宽额鳢(Channa gachua)的群体遗传分化和亲缘生物地理过程,采集了云南元江和海南岛5个水系(昌化江、陵水河、藤桥河、万泉河及南渡江)共6个种群168个宽额鳢个体,基于线粒体细胞色素b(Cyt b)基因全序列(1142 bp)对其遗传多样性和遗传分化程度进行了评估,并探讨了地质和气候等因素如何塑造了这一物种的亲缘地理结构及演化历史。基于Cyt b序列构建的系统树结果将所有个体分成两个主要谱系(A和B),谱系A包括海南岛所有种群,其中,部分昌化江个体形成独立的亚支(A2),其余个体聚为另一亚支(A1),谱系B为云南元江的全部个体,各谱系间的遗传分化指数均较高。种群历史动态分析表明,各谱系均没有发生种群扩张,但A1亚支与谱系B曾在约1万年前发生过有效种群数量减小的事件。根据研究结果推测,更新世冰期期间,北部湾因海平面下降而暴露,大陆和海南岛的水系发生接触,越南北部水系(包括元江/红河)通过一条联系雷州半岛和海南岛的古河道流入南海,因而冰期期间宽额鳢有机会从元江(红河)扩散至海南岛西南部,随后在海南岛内部,宽额鳢进一步扩散,并以五指山为种群间基因交流的重要地理障碍,各水系间种群发生基因交流和遗传分化。     

草鱼中国土著群体与欧美日移居群体遗传差异的线粒体序列分析

草鱼是中国的土著鱼类,自20世纪60年代以来已被移居到100多个国家和地区,主要用来控制水草或水产养殖。本研究通过线粒体D-Loop区（764bp)和COII＋tRNA基因(719bp)序列分析,了解草鱼的中国土著群体（长江、珠江、黑龙江）和国外移居群体（匈牙利多瑙河、美国密西西比河、日本利根川河）之间以及各地方群体间的遗传差异。结果表明,中国土著草鱼群体的遗传变异高于国外移居群体;分子方差分析（AMOVA）表明,不同草鱼群体的遗传变异主要来自群体内,而不同地域间的差异极少;群体两两间Fst值比较表明,大多数群体之间遗传差异极显著;由TCS构建的单倍型网络结构图显示,长江草鱼群体是最原始的群体,其他水系草鱼均由长江群体演化而来;通过基因流分析发现,匈牙利多瑙河群体和日本利根川河群体来自长江和黑龙江群体,美国密西西比河群体除引自长江、黑龙江水系外,还有部分引自于珠江水系。     

我国草鱼野生群体D-Loop序列遗传变异分析

利用线粒体DNA的D-Loop区序列, 对来自长江水系(邗江、吴江、九江、石首、木洞和万州)、珠江水系(肇庆)和黑龙江水系(嫩江)的8个草鱼野生群体开展了遗传变异分析。在424尾鱼中检测到34个变异位点, 34个单倍型, 单倍型多样性介于0.4740.708。群体间Kimura双参数遗传距离介于0.00200.0049。长江下游3个群体间遗传距离最近, 遗传分化不显著(P0.05); 肇庆群体与长江上游3个群体遗传距离较近, 与九江群体遗传分化不显著(P0.05); 嫩江群体与长江上游2个群体遗传距离较近, 与万州群体遗传分化不显著(P0.05)。遗传距离与地理距离存在极显著正相关(R=0.61, P0.01)。分子方差分析显示, 不同流域间遗传变异占总变异26.24%, 差异极显著(P0.01)。34个单倍型分为2个分支, 分化极显著(FST=0.644, P0.01), 推测分化时间为第四纪更新世纪晚期。       

黄颡鱼属两种鱼类的线粒体ND4基因序列变异性分析

以东亚特有种光泽黄颡鱼(Pelteobagrus nitidus)和长须黄颡鱼(Pelteobagrus eupogon)为研究对象,采用PCR技术获得了这两种鱼类的部分线粒体DNA DN4基因及其3′端的tRNA基因碱基共约772个,用MEGA2.1软件分析了此片段序列,采用Kimura双参数模型计算遗传距离,以科属的大鳍(Hemibagrus macropterus)为外类群,用邻接法构建不同水系的光泽黄颡鱼和长须黄颡鱼的分子系统树。不同水系的光泽黄颡鱼的遗传距离在0.000—0.012之间,长须黄颡鱼的遗传距离在0.000—0.003之间,光泽黄颡鱼和长须黄颡鱼种间的遗传距离在0.099—0.108之间,从分子水平上证实了光泽黄颡鱼和长须黄颡鱼为两个有效物种。不同水系的光泽黄颡鱼遗传变异很小,除黑龙江种群外,其他水系的光泽黄颡鱼在分子系统树没有能够按水系区分开来,可能的原因为:(1)不同水系的光泽黄颡鱼之间存在频繁的基因交流;(2)东亚科鱼类的线粒体DNA的进化速率可能较小;(3)人类经济活动可能已影响到光泽黄颡鱼的种群遗传结构。     

华南沿海西部美丽小条鳅基于线粒体控制区的种群遗传变异及亲缘地理格局

为研究其种群遗传变异和亲缘地理格局,分析了107尾采自华南西部和海南岛的12条水系的美丽小条鳅(Micronoema-cheilus pulcher Nichols)控制区934-938 bp的序列,其中有79个核苷酸变异位点。分子变异分析(AMOVA)表明,种群间的遗传变异占46.88%,种群内的遗传变异占55.06%。基于36个单倍型的系统树显示,12条水系的种群聚成两支。其中,广西沿海诸独立水系(防城河、峒中河、北仑河、南流江)和西江水系与广东漠阳江和潭江水系关系密切,而海南岛万泉河和南渡江与广东鉴江水系关系密切。根据嵌套进化枝系地理分析(NCPA)推测,防城河周边地区可能是美丽小条鳅的扩散中心,该物种可由此区域通过两条途径扩散:(1)沿西江水系向广西沿海独立水系至广东漠阳江和潭江水系扩散;(2)向海南岛诸水系再至雷州半岛的鉴江水系扩散。在演化过程中,曾发生片断化事件、长距离建群和持续的分布区扩张。     

基于COI和ND5序列的中国南部唇鱼骨和间鱼骨群体遗传结构

唇鱼骨和间鱼骨均为分布较广的初级淡水鱼类,是理想的亲缘地理研究材料;且两者形态特征较为相似,不易鉴别,故两者的分布记述和物种有效性存在争议.为了解我国南部唇鱼骨和间鱼骨的群体遗传结构并探讨两者的物种有效性,本研究对8条水系的唇鱼骨和9条水系的间鱼骨共130尾个体的COI和ND5基因序列片段进行了测定,并对这两个基因的组合序列(2151 bp)进行了分析.结果表明: 在130尾个体的COI和ND5基因组合序列中,共有196个核苷酸变异位点,共检测出50个单倍型,单倍型多样性为0.964,核苷酸多样性为0.019,遗传多样性较高.基于COI和ND5基因组合序列构建的 NJ 树显示,所有种群可分为两支,支系Ⅰ包含了韩江和九龙江的全部单倍型以及瓯江的部分单倍型,余下的单倍型组成了支系Ⅱ.两支系间的遗传距离为0.036,而唇鱼骨与间鱼骨之间的遗传距离为0.027.单倍型网络图表明,韩江、九龙江种群和其他水系种群分化较大;漠阳江种群由海南岛种群扩散而来;海南岛各种群及漠阳江种群的单倍型分支与珠江水系单倍型的分支之间的亲缘关系较近,与长江水系单倍型分支之间的亲缘关系则较远;湘江、桂江和柳江之间的亲缘关系较近.AMOVA分析结果显示,地理区之间的变异约占71.2%,地理区内种群间变异约占16.6%,种群内的变异占12.2%,表明其遗传分化主要来自地理区之间.错配分析及中性检验结果显示,全部种群、唇鱼骨种群、间鱼骨种群、支系Ⅰ和支系Ⅱ在历史上均没有发生过明显的扩张.     

草鱼野生群体遗传变异的微卫星分析

利用12个微卫星标记, 对来自长江水系(邗江、吴江、九江、石首、木洞和万州)、珠江水系(肇庆)和黑龙江水系(嫩江)的8个草鱼野生地理群体进行了遗传多样性及遗传结构等分析。遗传多样性分析显示, 12个微卫星位点均为高度多态位点(PIC=0.755~0.930), 8个草鱼野生群体显示出较高的遗传多样性水平(Ho=0.839~0.893), 其中长江水系的6个群体和肇庆群体的多样性水平高于嫩江群体。瓶颈效应分析显示, 嫩江、肇庆群体及2个长江上游群体(木洞、万州)近期出现了瓶颈效应, 群体数量发生下降。群体间遗传分化指数F^ST及AMOVA分析显示, 群体间出现极显著遗传分化(P<0.01), 整体分化水平较低(F^ST<0.05)。遗传距离分析结果显示, 长江水系的6个群体与肇庆群体遗传距离较近, 与嫩江群体较远; 基于此的UPGMA聚类树显示, 长江水系下游、中游和上游的群体依次聚类, 然后与肇庆群体聚类, 最后与嫩江群体聚类, 遗传距离与地理距离呈现出较强的正相关性。遗传结构分析显示, 所有样本被划分为5个理论群, 肇庆和嫩江群体中个体的遗传结构相对独立, 而长江上游、中游和下游群体中个体的遗传结构则存在一定程度的混杂。综上所述, 中国草鱼野生资源具有较高的遗传多样性, 地理群体间存在遗传分化, 具有进一步遗传改良的潜力; 但部分群体出现的瓶颈效应也需要引起重视。     

Genetic diversity and the biogeographical process of Acheilognathus macropterus revealed by sequence variations of mitochondrial cytochrome b gene

In this study, thirty-six individuals of Acheilognathus macropterus were collected from the Heilongjiang River,the Yangtze River,and the Nandujiang River.Partial mitochondrial cytochrome b gene region (636 base pair) was sequenced to these samples and 22 haplotypes were found.With A.chankaensis and A.tokinensis as outgroups,their relationships were analyzed.The p-distances were calculated with Mega software and a molecular phyiogenetic tree was constructed using the neighbor-joining (NJ) method.The proportions of main morphological characters were compared as well.P-distances showed that the genetic differences in A.macropterus samples were far smaller than those between these samples and the outgroups.The molecular phylogenetic tree shows that samples with barbels and those without barbels were intermingled.There was no distinctive difference in proportions of morphological characteristics among them.These results suggested that samples with barbels and those without barbels (formally identified as A.taenianalis) are the same species;A.taenianalis is synonymous with A.macropterus.The thirtysix individuals were grouped into five clades and the positions of the samples in the clades were correspondingly grouped within their geographical distributions.Among the five clades,clades 1 and 5 included samples from the Heilongjiang River and Nandujiang River respectively.The samples from the Yangtze River scattered into clades 2,3,and 4.There were distinctive genetic differences (> 5%)among them.Interestingly,the distributions of the 21 samples in these three clades were not correlated to their geographical distributions.It is postulated that these genetic differences were due to the bitterlings' mating choice mechanism,the prozygotic isolation.The genetic differences between the fish from Nandujiang River and those from the mainland indicated that they were separated early.However,the small genetic differences among the samples and the positions of the fish from the Heilonjiang River in the molecular phylogenetic tree indicate that fish in Heilongjiang River might have dispersed from the Yangtze River to that area much later.     

Genetic diversity and the biogeographical process of Acheilognathus macropterus revealed by sequence variations of mitochondrial cytochrome b gene

In this study, thirty-six individuals of Acheilognathus macropterus were collected from the Heilongjiang River, the Yangtze River, and the Nandujiang River. Partial mitochondrial cytochrome b gene region (636 base pair) was sequenced to these samples and 22 haplotypes were found. With A. chankaensis and A. tokinensis as outgroups, their relationships were analyzed. The p-distances were calculated with Mega software and a molecular phylogenetic tree was constructed using the neighbor-joining (NJ) method. The proportions of main morphological characters were compared as well. P-distances showed that the genetic differences in A. macropterus samples were far smaller than those between these samples and the outgroups. The molecular phylogenetic tree shows that samples with barbels and those without barbels were intermingled. There was no distinctive difference in proportions of morphological characteristics among them. These results suggested that samples with barbels and those without barbels (formally identified as A. taenianalis) are the same species; A. taenianalis is synonymous with A. macropterus. The thirtysix individuals were grouped into five clades and the positions of the samples in the clades were correspondingly grouped within their geographical distributions. Among the five clades, clades 1 and 5 included samples from the Heilongjiang River and Nandujiang River respectively. The samples from the Yangtze River scattered into clades 2, 3, and 4. There were distinctive genetic differences (>5%) among them. Interestingly, the distributions of the 21 samples in these three clades were not correlated to their geographical distributions. It is postulated that these genetic differences were due to the bitterlings’ mating choice mechanism, the prozygotic isolation. The genetic differences between the fish from Nandujiang River and those from the mainland indicated that they were separated early. However, the small genetic differences among the samples and the positions of the fish from the Heilonjiang River in the molecular phylogenetic tree indicate that fish in Heilongjiang River might have dispersed from the Yangtze River to that area much later. __________ Translated from Acta Hydrobiologica Sinica, 2006, 39(2): 134–140 [译自: 水生生物学报]     

不同群体鳙的生长性能与遗传分析

1982至1986年,在上海与广东两地精养鱼池中,对来源于不同繁殖群体的鳙,即长江水系天然繁殖的鳙和人工繁殖的鳙,珠江水系天然繁殖和人工繁殖的鳙,用随机区组成试验法观察比较了2龄和3龄阶段的生长速度,结果一致表明：在同一环境里,天然繁殖鳙比人工繁殖鳙长得快,长江天然繁殖鳙比珠江天然繁殖鳙长得快,长江人工繁殖鳙比珠江人工殖鳙长得快,差距约5％左右,方差组分和遗传相关分析进一步揭示,遗传因子在不同繁殖群体鳙的生长差异上起有重要作用。     

河南省淮河流域鳑鲏亚科5种鱼形态差异分析

为进一步从可量性状比较中华鳑鲏(Rhodeus sinensis)、越南鱊(Acheilongnathus tonkinensis)、大鳍鱊(A. macropterus)、兴凯鱊(A. chankaensis)和斑条鱊(A. taenianalis)的种间形态差异, 丰富鳑鲏亚科鱼类的形态分类特征, 研究采用多变量形态度量学方法对河南省淮河流域这5种鱼的形态进行比较分析。结果表明: 这5种鱼在体宽/体长、头长/体长、吻长/体长、尾柄长/体长、背鳍基底长/体长、腹鳍长/体长、臀鳍长/体长和头长/吻长8个比值性状上存在极显著性差异(P< 0.01), 在全长/体长、体高/体长2个比值性状上存在显著性差异(P<0.05), 这些差异主要集中在鱼体的头部、尾部和鳍等部位。主成分分析、聚类分析和判别分析显示5种鱼存在显著性形态差异, 斑条鱊与越南鱊的差异程度最大, 与大鳍鱊差异程度最小。判别分析获得的判别准确率在82.35%—100.00%变化, 可以从一定的角度区分这5种鱼。     

两种(鱼尝)科鱼类在长江和珠江流域Cytb基因序列变异性分析

采用PCR技术获得了长江和珠江流域的两种鲿科鱼类1137bp Cytb基因的片段,进行了序列测定,并用Mega软件进行了序列分析。研究发现两种鲿科鱼类的全序列从第十位碱基起有一个三联体密码子的缺失,推测为鲇形目鱼类Cytb序列所特有特征。黄颡鱼和大鳍鳠种群间的序列差异分别为0．4％和1．6％,介于一般淡水鱼类mtDNA种内序列的变异范围,而高于洄游鱼类序列变异。黄颡鱼属和鲮属Cytb基因序列间的差异为17．6％-18．0％,大大高于种间的序列差异率,也从分子水平上证实了二者属级分类单元的有效性。依据分子进化速率推测,长江和珠江两水系间大鳍鳠的分歧时间为距今27万年左右的更新世中晚期,黄颡鱼的分歧时间在距今7万年左右的更新世末期。推测造成二者有着不同分歧时间的可能原因是：大鳍鳠属暖水性鱼类,在第四纪冰川期间,由于全球性气候变冷,大鳍鳠退至长江以南,并在各水系间产生隔离,各自独立分化至今。而黄颡鱼具有很强的适应性,在第四纪数次冰川期间可能进行过广泛的交流。     

长江,珠江,黑龙江鲢,鳙和草鱼原种种群形态差异

对长江、珠江、黑龙江的鲢、鳙、草鱼原种种群的十项形态特征,于高维空间上用统计方法进行判别分析,发现种群间具有显著差异,不同江河鲢、鳙的侧线鳞数也有明显不同。这些形态特征上的差异的大小与种群间的地理距离呈正相关。 根据上述显著性差异的特征,用模式分类法推导得鉴别程序,可在IBM-PC-AT计算机上对鱼逐尾自动判别鉴定其种群,除长江鲢外,准确率在75％～100％。     

Phylogeny of Hydrophiloidea (Coleoptera: Staphyliniformia) using characters from adult and preimaginal stages

A phylogenetic analysis using characters from egg cases, larvae, pupae and adults was conducted; the outgroups included the beetle families Silphidae, Hydraenidae and Histeridae. Characters from the immature stages were obtained mostly from material reared in the laboratory, those from the adults were obtained from Hansen's generic revision for the superfamily. The results support the position of Hydraenidae within the Staphylinoidea, and not as part of Hydrophiloidea; Histeroidea is proposed as the sister group of Hydrophiloidea. At family level two clades are distinguished; the relationships within the first clade are ((Georissidae Epimetopidae) Helophoridae), those within the second are ((Hydrophilidae Spercheidae) Hydrochidae). Larval characters were most informative at the base of the tree, especially those associated with the spiracular atrium; adult characters were most informative at the apex of the tree.     

Rivers as barriers for high elevation amphibians: a phylogeographic analysis of the alpine stream frog of the Hengduan Mountains

At high altitude, rivers may function as barriers for amphibians. We examined 21 populations of Scutiger boulengeri from the Hengduan Mountains with 1038 base pairs of mitochondrial cytochrome b gene sequences. The haplotypes of S. boulengeri formed three clades on the gene tree, and each clade was restricted to one mountain ridge separated by two major river systems, the Yalong River and the Dadu River. The vicariant pattern of the gene tree suggests that these rivers functioned as effective barriers during population differentiation. On the other hand, mountain ridges may have facilitated amphibian movement. Populations within the uninterrupted mountain ranges of clades II and III, revealed little genetic structure. The northern clade I, harboured a substantial amount of genetic variation, which might be the consequence of the rugged terrain and heterogeneous habitat of this area. Furthermore, one outgroup species, Scutiger glandulatus , formed the fourth clade and nested within S. boulengeri , suggesting that S. boulengeri is likely a paraphyletic species or a species complex.     

基于COI和ND5序列的中国南部唇鱼骨和间鱼骨群体遗传结构

唇鱼骨和间鱼骨均为分布较广的初级淡水鱼类,是理想的亲缘地理研究材料;且两者形态特征较为相似,不易鉴别,故两者的分布记述和物种有效性存在争议.为了解我国南部唇鱼骨和间鱼骨的群体遗传结构并探讨两者的物种有效性,本研究对8条水系的唇鱼骨和9条水系的间鱼骨共130尾个体的COI和ND5基因序列片段进行了测定,并对这两个基因的组合序列(2151 bp)进行了分析.结果表明: 在130尾个体的COI和ND5基因组合序列中,共有196个核苷酸变异位点,共检测出50个单倍型,单倍型多样性为0.964,核苷酸多样性为0.019,遗传多样性较高.基于COI和ND5基因组合序列构建的 NJ 树显示,所有种群可分为两支,支系Ⅰ包含了韩江和九龙江的全部单倍型以及瓯江的部分单倍型,余下的单倍型组成了支系Ⅱ.两支系间的遗传距离为0.036,而唇鱼骨与间鱼骨之间的遗传距离为0.027.单倍型网络图表明,韩江、九龙江种群和其他水系种群分化较大;漠阳江种群由海南岛种群扩散而来;海南岛各种群及漠阳江种群的单倍型分支与珠江水系单倍型的分支之间的亲缘关系较近,与长江水系单倍型分支之间的亲缘关系则较远;湘江、桂江和柳江之间的亲缘关系较近.AMOVA分析结果显示,地理区之间的变异约占71.2%,地理区内种群间变异约占16.6%,种群内的变异占12.2%,表明其遗传分化主要来自地理区之间.错配分析及中性检验结果显示,全部种群、唇鱼骨种群、间鱼骨种群、支系Ⅰ和支系Ⅱ在历史上均没有发生过明显的扩张.