基于12S rRNA基因的鹳形目系统发生关系

采用分子系统学的方法探讨鹳形目5个科之间的系统发生关系.文中测出鹳形目鸟类7种mtDNA 12SrRNA基因全序列,并结合来自Genbank的鹳形目另外7个物种及原鸡的同源区序列,经Clustal W软件对位排列后共1 009位点,包含405个变异位点,其中多态性位点381个,260个简约信息位点.基于上述序列数据,以原鸡为外群,使用距离邻接法、最大简约法、最大似然法及贝叶斯法分别重建了鹳形目5科14种的系统发生树.重建的系统发生树显示,内群中的14个种聚合为4支:鹮科构成第一支,聚在系统树的基部;锤头鹳科与鲸头鹳科聚为一支;鹭科和鹳科各自聚成一支.在比较不同建树方法的结果并进行合意树分析后认为:在鹳形目的系统发生中,鹮科可能是最早分化出的一支;锤头鹳科与鲸头鹳科之间的亲缘关系最近,它们祖先与鹭科、鹳科之间的分歧在时间上可能非常接近.鹳形目5个科之间的系统关系可以表示为:(鹮科,(鹭科,鹳科,(锤头鹳科,鲸头鹳科))).     

鹳形目12种鸟类核c-mos 基因和线粒体12S rRNA基因序列分析及其系统发生研究

鹳形目鸟类的传统分类一直存在分歧,而近期的分子系统学研究大多只用单个基因,其结论的可信度需要进一步验证.本文通过核c-mos基因和线粒体12S rRNA基因序列分别和合并分析,采用分子系统学方法探讨了鹳形目6科12种鸟类的系统发生关系.文中测出鹳形目鸟类6种核c-mos基因的片断序列,结合来自Genebank的其他种类的c-mos和12S rRNA基因序列,分别经Clustal W软件对位排列后,以原鸡为外类群用最大似然法、邻接法和最大简约法建立系统树.系统树分析表明, 鹳形目6科之间的系统发生关系总结为：（鹭科,（（鹮科,美洲鹫科）,（鹳科,（鲸头鹳科,锤头鹳科））））.鹭科7个属之间的系统发生关系总结为：（麻（开鸟）属（夜鹭属（池鹭属（苍鹭属（中白鹭属（白鹭属,大白鹭属））））））.分别基于两个单基因的系统树有一定差异,而基于合并数据的系统树支持率和分辨率都高于基于单基因的系统树,表明使用在遗传上相对独立的分子数据合并建立系统树有较高的可信度和分辨率,是一种更好的研究方法.     

基于CHD基因序列的隼形目12种鸟系统发育关系

对12个隼形目物种CHD基因的一段内含子序列进行比较和分析。CHD-W和CHD-Z基因的多态性存在差异,CHD-W基因不适合系统发生学的研究。通过对CHD-Z基因扩增序列构建的NJ和MP树,结果显示隼科鸟类与鹰科和鹳科鸟类关系较远,与传统形态分类和和鸟类新的分类系统不一致。在白腹鹞的分类地位上与传统形态学分类不一致,将白腹鹞归入鹰属一支。NJ树显示鸢属(黑鸢)与鵟属(毛脚鵟)亲缘关系较近,MP树显示鵟鹰属(灰脸鵟鹰)与鵟属(毛脚鵟)亲缘关系较近。NJ和MP树都显示雕属(金雕)和鹰雕属(鹰雕)与其他鹰科各属亲缘关系较远。     

陕西洋县朱Huan活动区的鸟类

1999年1月至2002年1月,在陕西省洋县进行朱Huan研究过程中,对当地鸟类进行了长期,系统的观察,记录到鸟类16目48科116属,共201种。     

雪鸡属分类地位探讨

以5种鸡形目鸟类,包括4个藏雪鸡Tetraogallus tibetanus、12个喜玛拉雅雪鸡T.himalayensis、1个阿尔泰雪鸡T.altaicus、1个石鸡Alectoris chuckar和1个斑翅山鹑Perdix dauurica为材料.通过P(永扩增线粒体细胞色素6基因513个碱基,同时从GenBank下载25种鸡形目鸟类细胞色素b基因序列.通过对鸡形目24个属线粒体细胞色素b基因序列的分析,结果表明共有214个变异位点,简约信息位点184个.以鸿雁 Anser cygnoides为外群,在运用不同分析方法得到的拓扑结构基础上,构建了最大简约树(MP)和最大似然树(ML),结果表明鸡形目鸟类鹑族和雉族基本上是多系发生的.结合分子钟和遗传信息分析,可以得出雪鸡属在鹑族中形成的时间相对较晚,约在14.6Myr出现石鸡属的祖先种群;而在约12.6Myr属和鹌鹑属开始出现.雪鸡属的祖先足起源于低海拔环境,后来伴随着青藏高原的逐渐降起和更新世冰期事件的发生各自演化形成现今各个种.     

蝗总科部分种类Cyt b基因序列及系统进化研究

蝗总科8个科10个种的线粒体DNA细胞色素b(Cyt b）基因部分序列被测定分析,比较同源性,计算核苷酸使用频率并构建NJ分子系统树。在获得的432bp的序列中,A T约占70.4%,其中177个核苷酸位点存在变异（约占41.0%）,DNA一级序列数据显示,该8科蝗虫间DNA序列变异丰富。用日本蚱作外群构建的NJ树表明：瘤锥蝗科较为原始,而癞蝗科与槌角蝗科关系较近,为比较进化的类群,蝗总科8科的起源关系为：瘤锥蝗科→班翅蝗科和锥头蝗科→斑腿蝗科→剑角蝗科→网翅蝗科→槌角蝗科和癞蝗科,上述研究结果与传统形态分类学结论不完全一致,并就此进行了讨论。     

草鹭染色体的研究

在鸟类中,由于染色体标本制作比较困难,加之含有大量的微小染色体,要得到质优量多的中期分裂相很不容易,以致影响了对鸟类染色体的分带研究。因此,至今有关的报道尚少。本文报告了鹳形目(Ciconiiformes)鹭科(Ardeidae)鹭属草鹭(Ardea purpurea)的核型及G带、C带和Ag-NORs的研究结果。     

中国地鼠线粒体Cyt b基因测序及其分子进化

目的测定中国地鼠线粒体DNA细胞色素b基因部分序列,分析其分子系统进化关系。方法提取中国地鼠肝脏的总基因组DNA。设计合成特异引物进行PCR扩增,经检测进行测序。用Blast与GenBank中啮齿类其他常用实验动物的物种细胞色素b基因进行同源序列比较,分析其碱基组成及变异情况,并用邻接法、最大简约法、最小进化法构建了分子系统树,在分子水平上探讨中国地鼠和常用啮齿类实验动物的进化关系。结果获得了中国地鼠线粒体Cytb基因的部分序列,共936bp。结论中国地鼠和金黄地鼠的亲缘关系最近,与小鼠、大鼠存在的差异相对大,与豚鼠的亲缘关系最远,与传统的分类地位基本吻合。     

鹰科四种鸟类线粒体DNA的差异和分子进化关系的研究

采用聚合酶链反应,从雀鹰、大Kuang鹰4种鸟类中分别扩增出线粒体DNA细胞色素b基因,并测定出1086bp的碱基序列,它们之间的序列差异在10.31%-16.57%之间。DNA一序列数据显示,这4种鸟类DNA序列变异丰富,MEGA1．01数据软件构建了4种鸟类的分子系统树,与化石资料和形态学研究结果相吻合。     

雀形目15种鸟类Co Ⅰ与Cyt b基因序列的比较

对雀形目Passeriformes 6科15种鸟类线粒体DNA的Cyt b基因全序列(1 143 bp)和CoⅠ基因部分序列(1 176 bp)进行了比较,结果显示Cyt b和CoⅠ基因序列的变异位点分别为454个和366个,简约信息位点为337个和303个,而且CoⅠ基因比Cyt b基因略微保守,进化速率也较低.采用邻接法、最大简约法、最大似然法和贝叶斯法分别构建了CoⅠ和Cyt b基因两组数据集的分子系统发生树及其合一树,并对建树结果进行了比较分析.基于以上两点,本文认为CoⅠ基因比Cyt b基因更适合于确定雀形目科级阶元之间的系统发生关系,而且它也能够作为雀形目物种鉴定的分子标记,但在物种鉴定方面不如Cyt b基因稳定和准确.     

The complete mitochondrial genome sequence of the little egret (Egretta garzetta)

Many phylogenetic questions in the Ciconiiformes remain unresolved and complete mitogenome data are urgently needed for further molecular investigation. In this work, we determined the complete mitogenome sequence of the little egret (Egretta garzetta). The genome was 17,361 bp in length and the gene organization was typical of other avian mtDNA. In protein-coding genes (PCGs), a C insertion was found in ND3, and COIII and ND4 terminated with incomplete stop codons (T). tRNA-Val and tRNA-Ser (AGY) were unable to fold into canonical cloverleaf secondary structures because they had lost the DHU arms. Long repetitive sequences consisting of five types of tandem repeats were found at the 3′ end of Domain III in the control region. A phylogenetic analysis of 11 species of Ciconiiformes was done using complete mitogenome data and 12 PCGs. The tree topologies obtained with these two strategies were identical, which strongly confirmed the monophyly of Ardeidae, Threskiorothidae and Ciconiidae. The phylogenetic analysis also revealed that Egretta was more closely related to Ardea than to Nycticorax in the Ardeidae, and Platalea was more closely related to Threskiornis than to Nipponia in the Threskiornithidae. These findings contribute to our understanding of the phylogenetic relationships of Ciconiiformes based on complete mitogenome data.     

The mitochondrial genome of the Cinnamon Bittern, Ixobrychus cinnamomeus (Pelecaniformes: Ardeidae): sequence, structure and phylogenetic analysis

Ixobrychus cinnamomeus is a member of the large wading bird family, known as Ardeidae. In the present study, we determined the complete mitochondrial genome of I. cinnamomeus for use in future phylogenetic analysis. This circular mitochondrial genome is 17,180 bp in length and composed of 13 protein-coding genes, 22 tRNA genes, two rRNA genes and one putative control region. Three conserved domains and a minisatellite of 17 nucleotides with 22 tandem repeats were detected at the end of the control region. Phylogenetic relationships were reconstructed using the nucleotide and corresponding amino acid datasets of 12 concatenated protein-coding genes from the mitochondrial genome. Using maximum likelihood, maximum parsimony and Bayesian inference methods, the monophyly of Ciconiidae, Ardeidae and Threskiornithidae were confirmed; however, the monophyly of traditional Ciconiiformes and Pelecaniformes failed to be recovered. Although further studies are recommended to clarify relationships among and within the orders of Ciconiiformes, Pelecaniformes, Suliformes and Phaethontiformes, our results provide preliminary exploratory results that can be useful in the current understanding of avian phylogenetics.     

Molecular characterization of Gonatocerus tuberculifemur (Ogloblin) (Hymenoptera: Mymaridae), a prospective Homalodisca vitripennis (Germar) (Hemiptera: Cicadellidae) biological control candidate agent from South America: divergent clades

We genetically characterized the prospective South American egg parasitoid candidate, Gonatocerus tuberculifemur, of the glassy-winged sharpshooter (GWSS), Homalodisca vitripennis, for a neoclassical biological control program in California. Two molecular methods, inter-simple sequence repeat-polymerase chain reaction DNA fingerprinting and a phylogeographic approach inferred from the mitochondrial cytochrome oxidase subunit I gene (COI), were utilized. Five geographic populations from South America were analyzed; in addition, a phylogenetic analysis was performed with several named and one unnamed Gonatocerus species using the COI gene. DNA fingerprinting demonstrated a fixed geographic banding pattern difference in the population from San Rafael, Mendoza Province, Argentina. The COI analysis uncovered haplotype or geographic structure in G. tuberculifemur. A neighbour-joining distance (NJ) and a single most parsimonious tree (MP) clustered the populations into two well-supported distinct clades with strong bootstrap values (97-99% and 92-99%, respectively) with populations from San Rafael clustering into clade 2 and the rest of the populations clustering into clade 1. No haplotype sharing was observed between individuals from the two clades. Phylogenetic analyses performed by NJ and MP methods with 15 Gonatocerus species confirmed species boundaries and again uncovered two distinct clades in G. tuberculifemur with strong bootstrap support (95-100% and 68-100%, respectively). However, the NJ tree supported the morphologically defined relationships better than the MP tree. The molecular evidence in the present study is suggestive of a species level divergence. Because G. tuberculifemur is under consideration as a potential biological control agent for GWSS in California, understanding cryptic variation in this species is critical.     

Postglacial population expansion of Dacrydium pectinatum(Podocarpaceae)in Hainan,southern China,based on cpDNA tmL-F nocoding sequence data

This study determined the sequences of chloro plast DNA(cpDNA)trnL-F non-coding regions of indiViduals of a tropical coniferous species,Dacrydium pectinatum,collected from 12 natural populations located in Hainan Province,southern China.Sequence length varied from 868 bp to 876 bp,indicating length polymorphism.Base composition in the sequences was high in A+T content between 64.17% and 64.95%.and no recombination event occurred (Rm=0).Thirty haplotypes were identified based on statistical parsimony algorithm by running the TCS program.Populations of D.pectinatum in Hainan were lacking genetic differentiation.Such a deduction was supported by the observed FST values(0.00),AMOVA(24.17% of molecular variance attributed to difference among populations,P＞0.05),high values of Nm(ranging from 1.92 to 2.50)and the branching structure in neighbor-joining(NJ)tree conin the TCS network of trnL-F haplotypes,and majority of the haplotypes coalesced near the tips in NJ tree.Gene genealogies of cpDNA haplotypes proposed a recent population expansion of D.pectinatum in Hainan,which was further supported by the results from Tajima's D test and mismatch distribution analysis.Our data.in COnjunction with geological and palynological evidences,showed that in the Holocene,due to global warming,refugee populations of D.pectinatum in Hainan might experience a range expansion.     

Phylogeny of the Avian Family Ciconiidae (Storks) Based on CytochromebSequences and DNA–DNA Hybridization Distances

This study is a phylogenetic analysis of the avian family Ciconiidae, the storks, based on two molecular data sets: 1065 base pairs of sequence from the mitochondrial cytochromebgene and a complete matrix of single-copy nuclear DNA–DNA hybridization distances. Sixteen of the nineteen stork species were included in the cytochromebdata matrix, and fifteen in the DNA–DNA hybridization matrix. Both matrices included outgroups from the families Cathartidae (New World vultures) and Threskiornithidae (ibises, spoonbills). Optimal trees based on the two data sets were congruent in those nodes with strong bootstrap support. In the best-fit tree based on DNA–DNA hybridization distances, nodes defining relationships among very recently diverged species had low bootstrap support, while nodes defining more distant relationships had strong bootstrap support. In the optimal trees based on the sequence data, nodes defining relationships among recently diverged species had strong bootstrap support, while nodes defining basal relationships in the family had weak support and were incongruent among analyses. A combinable-component consensus of the best-fit DNA–DNA hybridization tree and a consensus tree based on different analyses of the cytochromebsequences provide the best estimate of relationships among stork species based on the two data sets.     

INFERRING PHYLOGENIES FROM mtDNA VARIATION: MITOCHONDRIAL-GENE TREES VERSUS NUCLEAR-GENE TREES

An accurately resolved gene tree may not be congruent with the species tree because of lineage sorting of ancestral polymorphisms. DNA sequences from the mitochondrially encoded genes (mtDNA) are attractive sources of characters for estimating the phylogenies of recently evolved taxa because mtDNA evolves rapidly, but its utility is limited because the mitochondrial genes are inherited as a single linkage group (haplotype) and provide only one independent estimate of the species tree. In contrast, a set of nuclear genes can be selected from distinct chromosomes, such that each gene tree provides an independent estimate of the species tree. Another aspect of the gene-tree versus species-tree problem, however, favors the use of mtDNA for inferring species trees. For a three-species segment of a phylogeny, the branching order of a gene tree will correspond to that of the species tree if coalescence of the alleles or haplotypes occurred in the internode between the first and second bifurcation. From neutral theory, it is apparent that the probability of coalescence increases as effective population size decreases. Because the mitochondrial genome is maternally inherited and effectively haploid, its effective population size is one-fourth that of a nuclear-autosomal gene. Thus, the mitochondrial-haplotype tree has a substantially higher probability of accurately tracking a short internode than does a nuclear-autosomal-gene tree. When an internode is sufficiently long that the probability that the mitochondrial-haplotype tree will be congruent with the species tree is 0.95, the probability that a nuclear-autosomalgene tree will be congruent is only 0.62. If each of k independently sampled nuclear-gene trees has a probability of congruence with the species tree of 0.62, then a sample of 16 such trees would be required to be as confident of the inference based on the mitochondrial-haplotype tree. A survey of mtDNA-haplotype diversity in 34 species of birds indicates that coalescence is generally very recent, which suggests that coalescence times are typically much shorter than internodal branch lengths of the species tree, and that sorting of mtDNA lineages is not likely to confound the species tree. Hybridization resulting in transfer of mtDNA haplotypes among branches could also result in a haplotype tree that is incongruent with the species tree; if undetected, this could confound the species tree. However, hybridization is usually easy to detect and should be incorporated in the historical narrative of the group, because reticulation, as well as cladistic events, contributed to the evolution of the group.     

Polymorphic heterologous microsatellite loci for population genetics studies of the white-faced ibis Plegadis chihi (Vieillot, 1817) (Pelecaniformes, Threskiornithidae)

We screened 44 heterologous microsatellites isolated in species of the families Threskiornithidae, Ciconiidae and Ardeidae for their use in a migratory waterbird, the white-faced ibis Plegadis chihi (Vieillot, 1817) (Threskiornithidae). Of the screened loci, 57% amplified successfully and 24% were polymorphic. In two breeding colonies from southern Brazil (N = 131) we detected 32 alleles (2-10 alleles/locus). Average He over all loci and colonies was 0.55, and the combined probability of excluding false parents, 98%. There was no departure from HWE in any loci or population. Eru6 and Eru4 loci were in non-random association in the Alvorada colony, and NnNF5 and Eru5 in both populations. AMOVA analysis indicated that most of the genetic diversity was contained within populations. Structure analysis suggested a single population, and F(ST) value showed weak genetic structuring (F(ST) = 0.009, p = 0.05). The two populations are apparently connected through gene-flow. The panel of six microsatellites optimized here was sufficiently informative for characterizing the genetic diversity and structure in these natural populations of the white-faced ibis. The information generated could be useful in future studies of genetic diversity, relatedness and the mating system in Plegadis chihi and related species.     

Data Concatenation,Bayesian Concordance and Coalescent-Based Analyses of the Species Tree for the Rapid Radiation of Triturus Newts

The phylogenetic relationships for rapid species radiations are difficult to disentangle. Here we study one such case, namely the genus Triturus, which is composed of the marbled and crested newts. We analyze data for 38 genetic markers, positioned in 3-prime untranslated regions of protein-coding genes, obtained with 454 sequencing. Our dataset includes twenty Triturus newts and represents all nine species. Bayesian analysis of population structure allocates all individuals to their respective species. The branching patterns obtained by data concatenation, Bayesian concordance analysis and coalescent-based estimations of the species tree differ from one another. The data concatenation based species tree shows high branch support but branching order is considerably affected by allele choice in the case of heterozygotes in the concatenation process. Bayesian concordance analysis expresses the conflict between individual gene trees for part of the Triturus species tree as low concordance factors. The coalescent-based species tree is relatively similar to a previously published species tree based upon morphology and full mtDNA and any conflicting internal branches are not highly supported. Our findings reflect high gene tree discordance due to incomplete lineage sorting (possibly aggravated by hybridization) in combination with low information content of the markers employed (as can be expected for relatively recent species radiations). This case study highlights the complexity of resolving rapid radiations and we acknowledge that to convincingly resolve the Triturus species tree even more genes will have to be consulted.