探讨两栖纲三个目之间的系统发生关系

现存两栖纲分为3个目,然而它们的系统发生关系仍存在较大的争议.选择Genbank上25种两栖动物线粒体全序列,结合已测定的福建大头蛙(Lim nonectes fujianensis)线粒体基因组全序列,以天鹅和眼镜凯门鳄为外群,用线粒体tRNA基因的合并数据重建系统树.采用P AU P(version 4.0b10)软件构建MP和NJ树,tree-puzzle5.2构建ML树.结果显示,NJ树和ML树以较高的自引导值支持有尾目和蚓螈目为姐妹群,而MP树则支持无尾目和有尾目为姐妹群.     

大头蛙和脆皮大头蛙线粒体3个基因的测定及两栖类亲缘关系研究

现存的两栖类系统发生关系一直存在争议,特别是3个目间的亲缘关系。本文设计了5对引物,扩增和测定了大头蛙和脆皮大头蛙线粒体12S和16S rRNA基因和Cytb基因的全序列。在对所测序列进行分析的同时,基于3个基因全序列的相加数据,运用MEGA 3.1和PHYLIP 3.64软件中的NJ法、MP法和ML法,对两爬类17个物种,以鱼类非洲肺鱼为外群,重建出3个树形完全一致的分子系统树。研究结果显示:现存两栖类中无尾目和有尾目为姐妹群关系,并推断有尾目内小鲵科和隐鳃鲵科亲缘关系较近。此外,在研究两栖类系统发生关系方面,作者分析前人研究中产生两种不同观点的可能原因,同时总结了在此类研究中产生偏差的几种影响因素。     

现生两栖动物的起源

<正>现生的两栖动物包括无尾类（蛙）、有尾类（蝾螈）以及不常见的无足类（蚓螈）。所有现生两栖类被认为是一个单系,1866年由Haeckel命名为滑体两栖类。现生两栖类有一些特有的共同衍征。它们的牙齿带小梗（齿基与齿冠被一个纤维组织带分隔）,有两个尖。在滑体两栖类之外只有离片椎类的几个属种（如Doleserpeton,Amphibamus, Gerobatrachus）存在这种牙齿。     

中国大头蛙属3个种线粒体ND1基因全序列分析与亲缘关系

测定了大头蛙和脆皮大头蛙线粒体ND1基因全序列长度分别为978 bp和958 bp,(对应编码325和319个氨基酸)。对所测基因序列组分进行了分析,并与福建大头蛙同源序列进行比较发现,978个核苷酸位点中,有664个保守位点和多变位点294个。同时发现福建大头蛙与大头蛙该基因序列的同源性最高(核苷酸序列同源性为78.77%,氨基酸序列为92.62%)。基于ND1基因全序列的氨基酸和核苷酸两种数据形式,选用M ega3.1软件中的NJ法对大头蛙属3个种、黑斑蛙、泽陆蛙及外群中国大鲵共6条基因序列进行系统树重建分析,结果表明:所得的2个NJ树均将大头蛙属3个种聚于一支,其中大头蛙与福建大头蛙为姐妹群关系(自检值均高度支持),从而证实了大头蛙与福建大头蛙亲缘关系较近的观点。     

从细胞色素b基因序列变异分析中国鲇形目鱼类的系统发育

采用PCR技术获得中国鲇形目鱼类11科24属27个代表种类细胞色素b基因1138bp全序列,比较分析了来自北美洲、非洲的部分鲇形目鱼类同一基因序列,并选取脂鲤目、鲤形目和鲱形目鱼类作外类群,采用Bayesian方法和最大简约法(MP)构建分子系统树。结果表明：(1)鲇形目鱼类细胞色素b基因序列中,与脂鲤目、鲤形目以及鲱形目鱼类相比存在3bp的缺失;(2)鲇形目鱼类各科代表种类形成一单系群;(3)两种建树方法均支持铫科、粒鲇科和钝头鮠科形成一单系群;而胡子鲇科、刀鲇科、海鲇科、鮰科、长臀鮠科、鲢科、鲇科、棘脂鲿科、鲿科形成一大的单系群;但鳗鲇科的系统位置两种建树方法没有取得一致结果;而其中长臀鲍科与北美的鮰科形成姐妹群,胡子鲇、鮰科、鲇科、鲿科和鮡科是较明显的单系群。     

基于线粒体基因对细痣疣螈种组系统发育关系的探讨及物种修订建议

该文基于两段线粒体基因COI和ND1 -ND2部分序列片段构建了细痣疣螈种组的系统发育关系,结果显示该单系群内包含了四个明显的进化支系(A、B、C、D).A支系与B、C支系构成姐妹群关系;A支系包含了细痣疣螈、海南疣螈、老挝疣螈和“越南疣螈”以及另外两个来自越南未被命名的种群;C支系代表了一个新的独立进化支,可能是一个隐存种;C支系与B支系构成姐妹群关系.此外,来自模式产地的越南疣螈单独构成支系D.该文结果不支持以往细痣疣螈种组部分物种的划分,建议对该种组进行新的分类修订.该文强调了在分类研究中应该重视使用来自模式产地的样品并进行广泛的地理居群采样.     

两栖动物线粒体基因组结构特征分析

对2007年6月13日以前公布于GenBank上的78种两栖动物的线粒体基因组全序列进行了总结、比较和分析。78种基因组中基因的数量从35~41个不等;根据基因的数量、种类及其排列顺序的差别将其分为22种基因组类型,其进而聚为3组,其中类型4为两栖纲与其它脊椎动物的常见类型,类型8为两栖纲中现生3个目的公有类型。与类型4比较,其余21种线粒体基因组类型涉及基因变动的基因共有18个,其中变动比较多的是tRNA基因,移位、增多和缺失的发生频率都较大,而蛋白编码基因比较稳定,主要是移位。78种两栖动物中,蚓螈目的线粒体基因组均小于18000bps,多数在15000~16000bps;有尾目和无尾目均大于16000bps,其中有尾目多数在16000~17000bps,无尾目的多数在17000~18000bps。     

凹耳蛙MHCII类B基因第二外显子多态性分析

两栖类正经历全球范围内的种群衰退,很多两栖动物集群灭绝事件与环境病原体(如壶菌(Batrachochytrium dendrobatidis)的侵扰有关。MHC基因的表达产物在有颌脊椎动物免疫应答过程中起关键作用,其多态性通常与动物对疾病的抗性或易感性密切相关,因而被认为是研究动物适应性进化的最佳候选基因之一。本文对中国特有的无尾两栖动物凹耳蛙(Odorrana tormota)MHC II类B基因多态性进行初步研究。首先,利用1对通用引物扩增出凹耳蛙MHC II类B基因exon2长约180bp的DNA片段。在此基础上,利用ligation-mediated PCR进一步获取侧翼未知序列,序列拼接后长2,030bp,包含exon2以及intron1和intron2的部分序列。基于上述序列设计出凹耳蛙B基因exon2特异性引物(IIQ1BU/IIQ1BD),对该物种黄山种群32个样品进行PCR扩增和克隆测序,共获得34个不同的等位基因,等位基因序列核苷酸和氨基酸变异位点的比例分别为16.17%(33/204)和26.87%(18/67),大多数氨基酸变异位点位于推测的抗原结合位点(antigen binding sites,ABS)。每个样品包含2-5个等位基因,结合等位基因序列特征以及cDNA表达分析结果,推测凹耳蛙至少拥有3个可表达的B基因座位。与文献报道的蛙科其他物种比较后发现,尽管凹耳蛙目前的分布区非常狭窄,但其MHC II类B基因多态性明显高于蛙科其他动物。等位基因碱基替换模式提示凹耳蛙MHC II类B基因曾经历过强烈的正选择作用,ABS区的dN值显著大于dS(P<0.05),PAML软件包CODEML程序中不同模型的似然比检测(likelihood rate test)结果同样支持上述推论,贝叶斯经验贝叶斯路径(Bayesian Em-pirical Bayes)共检测出5个显著受正选择作用的氨基酸位点。贝叶斯系统树的拓扑结构显示,无尾两栖类不同科的等位基因分别形成单系群,但蛙科不同属的等位基因未能形成单系群,蛙属绿池蛙(Rana clamitans)的1个等位基因与臭蛙属凹耳蛙的部分等位基因享有共同的谱系关系,提示蛙科不同属间的B基因存在跨种多态性。     

速足目主要类群系统发育的分子证据

文章基于速足目现生主要类群18S rDNA、28S rDNA和COI基因序列,采用贝叶斯法、邻接法和最大简约法,尝试构建速足目的分子系统树;结合形态特征和化石记录,主要对速足目各超科级分类阶元的系统发育关系进行探讨。结果表明,速足目现生超科Bairdiacea、Darwinulacea、Cypridacea和Cytheracea均为单系群,支持形态学上关于上述4个超科的的界定;3种基因均支持形态学上Darwinulacea和Cypridacea具有较近的亲缘关系的观点。18S rDNA序列分析在较显著水平上支持Darwinulacea和Bairdiacea为姐妹群,Darwinulacea可能从Bairdia-cea中的一支演化而来;Bairdiacea和Darwinulacea组成的分支是Cypridacea的姐妹群,支持将三者合并为Bairdio-copina亚目的观点;Cytheracea是Cypridacea(Darwinulacea Bairdiacea)的姐妹群,可提升为Cytheracopina亚目。     

基于12S和16S rRNA序列的湍蛙属部分物种的系统发育关系

测定了湍蛙属 6个种共 10个种群 ,以及 4个外群种的线粒体 12S和 16SrRNA基因片段 ,比对后有94 0bp序列 ,发现 35 2个变异位点、 186个简约性位点。运用NJ法、MP法、ML法构建了系统关系树 ,各系统树一致表明内群为一单系群 ,分为两组 :第一组中 ,四川湍蛙两种群先聚合 ,再和棕点湍蛙聚为一支 ;第二组中 ,香港湍蛙和戴云湍蛙聚为一支 ,而香港大屿山离岛湍蛙种群首先与华南湍蛙相聚 ,再与武夷湍蛙构成姐妹支。研究结果表明 :香港地区增加 1种湍蛙分布 ;戴云湍蛙是一有效种 ;四川湍蛙的石棉和洪雅种群间遗传差异达到或超过其他种间的分歧水平。     

Mitogenomic perspectives on the origin and phylogeny of living amphibians

Establishing the relationships among modern amphibians (lissamphibians) and their ancient relatives is necessary for our understanding of early tetrapod evolution. However, the phylogeny is still intractable because of the highly specialized anatomy and poor fossil record of lissamphibians. Paleobiologists are still not sure whether lissamphibians are monophyletic or polyphyletic, and which ancient group (temnospondyls or lepospondyls) is most closely related to them. In an attempt to address these problems, eight mitochondrial genomes of living amphibians were determined and compared with previously published amphibian sequences. A comprehensive molecular phylogenetic analysis of nucleotide sequences yields a highly resolved tree congruent with the traditional hypotheses (Batrachia). By using a molecular clock-independent approach for inferring dating information from molecular phylogenies, we present here the first molecular timescale for lissamphibian evolution, which suggests that lissamphibians first emerged about 330 million years ago. By observing the fit between molecular and fossil times, we suggest that the temnospondyl-origin hypothesis for lissamphibians is more credible than other hypotheses. Moreover, under this timescale, the potential geographic origins of the main living amphibian groups are discussed: (i) advanced frogs (neobatrachians) may possess an Africa-India origin; (ii) salamanders may have originated in east Asia; (iii) the tropic forest of the Triassic Pangaea may be the place of origin for the ancient caecilians. An accurate phylogeny with divergence times can be also helpful to direct the search for "missing" fossils, and can benefit comparative studies of amphibian evolution.     

Phylogeny of caecilian amphibians (Gymnophiona) based on complete mitochondrial genomes and nuclear RAG1

We determined the complete nucleotide sequence of the mitochondrial (mt) genome of five individual caecilians (Amphibia: Gymnophiona) representing five of the six recognized families: Rhinatrema bivittatum (Rhinatrematidae), Ichthyophis glutinosus (Ichthyophiidae), Uraeotyphlus cf. oxyurus (Uraeotyphlidae), Scolecomorphus vittatus (Scolecomorphidae), and Gegeneophis ramaswamii (Caeciliidae). The organization and size of these newly determined mitogenomes are similar to those previously reported for the caecilian Typhlonectes natans (Typhlonectidae), and for other vertebrates. Nucleotide sequences of the nuclear RAG1 gene were also determined for these six species of caecilians, and the salamander Mertensiella luschani atifi. RAG1 (both at the amino acid and nucleotide level) shows slower rates of evolution than almost all mt protein-coding genes (at the amino acid level). The new mt and nuclear sequences were compared with data for other amphibians and subjected to separate and combined phylogenetic analyses (Maximum Parsimony, Minimum Evolution, Maximum Likelihood, and Bayesian Inference). All analyses strongly support the monophyly of the three amphibian Orders. The Batrachia hypothesis (Gymnophiona, (Anura, Caudata) receives moderate or good support depending on the method of analysis. Within Gymnophiona, the optimal tree (Rhinatrema, (Ichthyophis, Uraeotyphlus), (Scolecomorphus, (Gegeneophis Typhlonectes) agrees with the most recent morphological and molecular studies. The sister group relationship between Rhinatrematidae and all other caecilians, that between Ichthyophiidae and Uraeotyphlidae, and the monophyly of the higher caecilians Scolecomorphidae+Caeciliidae+Typhlonectidae, are strongly supported, whereas the relationships among the higher caecilians are less unambiguously resolved. Analysis of RAG1 is affected by a spurious local rooting problem and associated low support that is ameliorated when outgroups are excluded. Comparisons of trees using the non-parametric Templeton, Kishino-Hasegawa, Approximately Unbiased, and Shimodaira-Hasegawa tests suggest that the latter may be too conservative.     

Phylogenetic relationships of glyptosternoid fishes (Siluriformes: Sisoridae) inferred from mitochondrial cytochrome b gene sequences

To explore phylogenetic relationships among glyptosternoid fishes, we determined nucleotide sequences of the complete mitochondrial cytochrome b gene region (1138 base pair). Thirteen species of glyptosternoid fishes and six species of non-glyptosternoids represent 10 sisorid genera were examined. Molecular phylogenetic trees were constructed using the maximum parsimony, minimum evolution, maximum likelihood, and Bayesian methods. Bayesian and maximum likelihood analyses support the monophyly of glyptosternoids, but our hypothesis of internal relationships differs from previous hypothesis. Results indicated that glyptosternoid is a monophyletic group and genera Glyptosternum and Exostoma are two basal species having a primitive position among it. Genera Euchiloglanis and Pareuchiloglanis form a sister-group. Then they form a sister-group with Pseudexostoma plus Oreoglanis. Our result also found that Pareuchiloglanis anteanalis might be considered as the synonyms of Parechiloglanis sinensis, and genus Euchiloglanis might have only one valid species, Euchiloglanis davidi.     

Mitochondrial evidence on the phylogenetic position of caecilians (Amphibia: Gymnophiona)

The complete nucleotide sequence (17,005 bp) of the mitochondrial genome of the caecilian Typhlonectes natans (Gymnophiona, Amphibia) was determined. This molecule is characterized by two distinctive genomic features: there are seven large 109-bp tandem repeats in the control region, and the sequence for the putative origin of replication of the L strand can potentially fold into two alternative secondary structures (one including part of the tRNA(Cys)). The new sequence data were used to assess the phylogenetic position of caecilians and to gain insights into the origin of living amphibians (frogs, salamanders, and caecilians). Phylogenetic analyses of two data sets-one combining protein-coding genes and the other combining tRNA genes-strongly supported a caecilian + frog clade and, hence, monophyly of modern amphibians. These two data sets could not further resolve relationships among the coelacanth, lungfishes, and tetrapods, but strongly supported diapsid affinities of turtles. Phylogenetic relationships among a larger set of species of frogs, salamanders, and caecilians were estimated with a mitochondrial rRNA data set. Maximum parsimony analysis of this latter data set also recovered monophyly of living amphibians and favored a frog + salamander (Batrachia) relationship. However, bootstrap support was only moderate at these nodes. This is likely due to an extensive among-site rate heterogeneity in the rRNA data set and the narrow window of time in which the three main groups of living amphibians were originated.     

Mitochondrial genome structure and evolution in the living fossil vampire squid, Vampyroteuthis infernalis, and extant cephalopods

Complete nucleotide sequences of mitochondrial (mt) genomes of the "living fossil" cephalopod Vampyroteuthis infernalis (Vampyromorpha) and the cuttlefish Sepia esculenta (Sepiida) were determined. The V. infernalis mt genome structure is identical to the incirrate octopod Octopus vulgaris mt genome structure, and is therefore more similar to that of the polyplacophoran Katharina tunicata, than to that of the other "living fossil" cephalopod Nautilus macromphalus. The mt genome structure of S. esculenta is identical to that of Sepia officinalis. Molecular phylogenetic analyses based on the mt protein genes from the completely sequenced cephalopod mt genomes suggested the monophyletic relationship of two myopsid squids Loligo bleekeri and Sepiotheuthis lessoniana, and the monophyletic relationship of two oegopsid squids Watasenia scintillans, and Todarodes pacificus. Sepiida appeared as the sister group of Teuthida (Myopsida + Oegopsida). The phylogenetic position of Vampyromorpha appeared as the sister group of Octopoda, although the monophyly of Vampyromorpha and Decapodiformes cannot be rejected outright by our phylogenetic analyses. The hypothesis that Vampyromorpha is basal among the coleoid cephalopods can be rejected because of low statistical support. Therefore, it is reasonable to recognize three major groups in Coleoidea--Vampyromorpha, Octopoda, and Decapodiformes.     

Complete mitochondrial genome DNA sequence for two ophiuroids and a holothuroid: the utility of protein gene sequence and gene maps in the analyses of deep deuterostome phylogeny

The complete mitochondrial genome sequences have been determined for the holothuroid Cucumaria miniata and two ophiuroid species Ophiopholis aculeata and Ophiura lütkeni. In addition, the nucleotide sequence of the mitochondrial protein-coding genes for the asteroid Pisaster ochraceus has been completed. Maximum-likelihood and LogDet distance analyses of concatenated protein-coding sequences produced a series of trees that did not conclusively support generally accepted models of echinoderm phylogeny. The ophiuroid data consistently demonstrated accelerated nucleotide divergence rates and lack of stationarity. This confounds the phylogenetic analyses. Molecular investigations using individual protein-coding gene alignments demonstrated that the cytochrome b gene exhibits the least deviation in rate and stationarity and generated some trees consistent with proposed echinoderm phylogenies. Phylogenies based on echinoderm mitochondrial gene rearrangements also proved problematic because of extensive variation in gene order between and within classes. A comparison of the two distinctive ophiuroid mitochondrial gene orders supports the hypothesis that O. lütkeni has a more derived mitochondrial gene order versus O. aculeata. The variation in the echinoderm mitochondrial gene maps reinforces the limitations of the application of mitochondrial gene rearrangements as a global phylogenetic tool.     

Monophyly of clade III nematodes is not supported by phylogenetic analysis of complete mitochondrial genome sequences

Background

The orders Ascaridida, Oxyurida, and Spirurida represent major components of zooparasitic nematode diversity, including many species of veterinary and medical importance. Phylum-wide nematode phylogenetic hypotheses have mainly been based on nuclear rDNA sequences, but more recently complete mitochondrial (mtDNA) gene sequences have provided another source of molecular information to evaluate relationships. Although there is much agreement between nuclear rDNA and mtDNA phylogenies, relationships among certain major clades are different. In this study we report that mtDNA sequences do not support the monophyly of Ascaridida, Oxyurida and Spirurida (clade III) in contrast to results for nuclear rDNA. Results from mtDNA genomes show promise as an additional independently evolving genome for developing phylogenetic hypotheses for nematodes, although substantially increased taxon sampling is needed for enhanced comparative value with nuclear rDNA. Ultimately, topological incongruence (and congruence) between nuclear rDNA and mtDNA phylogenetic hypotheses will need to be tested relative to additional independent loci that provide appropriate levels of resolution.

Results

For this comparative phylogenetic study, we determined the complete mitochondrial genome sequences of three nematode species, Cucullanus robustus (13,972 bp) representing Ascaridida, Wellcomia siamensis (14,128 bp) representing Oxyurida, and Heliconema longissimum (13,610 bp) representing Spirurida. These new sequences were used along with 33 published nematode mitochondrial genomes to investigate phylogenetic relationships among chromadorean orders. Phylogenetic analyses of both nucleotide and amino acid sequence datasets support the hypothesis that Ascaridida is nested within Rhabditida. The position of Oxyurida within Chromadorea varies among analyses; in most analyses this order is sister to the Ascaridida plus Rhabditida clade, with representative Spirurida forming a distinct clade, however, in one case Oxyurida is sister to Spirurida. Ascaridida, Oxyurida, and Spirurida (the sampled clade III taxa) do not form a monophyletic group based on complete mitochondrial DNA sequences. Tree topology tests revealed that constraining clade III taxa to be monophyletic, given the mtDNA datasets analyzed, was a significantly worse result.

Conclusion

The phylogenetic hypotheses from comparative analysis of the complete mitochondrial genome data (analysis of nucleotide and amino acid datasets, and nucleotide data excluding 3^rd positions) indicates that nematodes representing Ascaridida, Oxyurida and Spirurida do not share an exclusive most recent common ancestor, in contrast to published results based on nuclear ribosomal DNA. Overall, mtDNA genome data provides reliable support for nematode relationships that often corroborates findings based on nuclear rDNA. It is anticipated that additional taxonomic sampling will provide a wealth of information on mitochondrial genome evolution and sequence data for developing phylogenetic hypotheses for the phylum Nematoda.

     

The complete mitochondrial genome of Tupaia belangeri and the phylogenetic affiliation of scandentia to other eutherian orders

The complete mitochondrial genome of Tupaia belangeri, a representative of the eutherian order Scandentia, was determined and compared with full-length mitochondrial sequences of other eutherian orders described to date. The complete mitochondrial genome is 16, 754 nt in length, with no obvious deviation from the general organization of the mammalian mitochondrial genome. Thus, features such as start codon usage, incomplete stop codons, and overlapping coding regions, as well as the presence of tandem repeats in the control region, are within the range of mammalian mitochondrial (mt) DNA variation. To address the question of a possible close phylogenetic relationship between primates and Tupaia, the evolutionary affinities among primates, Tupaia and bats as representatives of the Archonta superorder, ferungulates, guinea pigs, armadillos, rats, mice, and hedgehogs were examined on the basis of the complete mitochondrial DNA sequences. The opossum sequence was used as an outgroup. The trees, estimated from 12 concatenated genes encoded on the mitochondrial H-strand, add further molecular evidence against an Archonta monophyly. With the new data described in this paper, most of both the mitochondrial and the nuclear data point away from Scandentia as the closest extant relatives to primates. Instead, the complete mitochondrial data support a clustering of Scandentia with Lagomorpha connecting to the branch leading to ferungulates. This closer phylogenetic relationship of Tupaia to rabbits than to primates first received support from several analyses of nuclear and partial mitochondrial DNA data sets. Given that short sequences are of limited use in determining deep mammalian relationships, the partial mitochondrial data available to date support this hypothesis only tentatively. Our complete mitochondrial genome data therefore add considerably more evidence in support of this hypothesis.