中国鸟类的DNA分类及系统发育研究概述

鸟类分类是鸟类学其他研究领域的基础,近年来分子技术的发展,以及计算机技术的应用为鸟类分类学和鸟类系统演化研究提供了新的研究手段,给传统的系统分类研究带来了新的机遇.Tautz等于2002年首先提出运用DNA序列作为生物分类系统的主要平台,即DNA分类学(DNA Taxonomy).而Hebert等于2003年则首次提出了DNA条形码(DNA Barcoding)的概念,并对其物种分类和鉴定意义予以肯定,建议利用线粒体细胞色素C氧化酶亚单位Ⅰ(COI)的特定区段来做DNA条形编码的基础.在鸟类DNA分类方面,国内学者应用线粒体基因Cut b,COI,c-mos,c-myc,12s rRNA,16s rRNA,ND2,ND3,CR,RAG-1以及核基因myoglobin introⅡ等不同片段对很多类群进行了分类探讨和系统发育研究.但是主要集中在鸡形目及雀形目鸟类.中国是鸟类多样性极其丰富的国家,近年来很多亚种、种及以上分类阶元依然存在问题,因此,中国鸟类物种的分类地位、系统发育与演化关系等依然有很多问题等待深入研究.目前国内基于COI的鸟类分类及系统发育研究有了一些报道,但是真正的DNA条形码工作尚需继续、深入地开展.

小鲵属分子系统发育研究

小鲵属为亚洲特有的有尾两栖类，是小鲵科之模式属。现记载小鲵属动物有29种，占全科物种数一半以上（Frost, 2007），为小鲵科第一大属。该属分布跨越古北界和东洋界，分布于中国、朝鲜、韩国、日本等地区，其系统学研究一直以来颇为中外学者所关注。澄清该属的物种分类问题，阐明其种间的系统发育关系对整个小鲵科的系统演化与分布格局关系的研究具有关键性意义。 本论文以中国及周边地区的小鲵属物种为主要对象，主要利用分子生物学实验与生物信息学途径相结合的手段，运用支序系统学与分子进化生物学理论及分析方法，展开系统发育的研究。在此基础上诠释现存的分类问题，并探讨该属系统发育关系。 研究材料上，本研究采用野外采集与网络下载数据相结合的方法，获取了较为全面的小鲵属物种DNA序列资料。技术手段上，选取了线粒体DNA的Cytb、12S、16S、NADH 2、COI等多个基因部分片段序列，对小鲵属开展了较为全面系统的研究。分析方法上，针对小鲵属物种各类群的具体情况，运用了处于领域前沿的多种分析方法。应用PAUP、MrBayes、Modeltest、Mega等软件，采用了最大简约法（MP）、邻接法（NJ）、贝叶斯推断（BI）及K2P遗传距离分析等方法。 本研究对小鲵属进行了较为全面的系统发育研究，弥补了有关小鲵属系统发育研究的不足，并得出了以下结果： （1）关于豫南小鲵Hynobius yunanicus的有效性，基于细胞色素b序列的系统发育关系联合形态和染色体组型等证据证明了豫南小鲵是商城肥鲵的同物异名。 （2）获得了较为全面的小鲵属物种系统发育树，并以此解释了北海道滞育小鲵、东北小鲵、中国小鲵与义乌小鲵等存在的分类问题。 （3）本研究利用DNA条形码技术对小鲵属及小鲵科物种进行了鉴定，再次证明豫南小鲵为商城肥鲵的同物异名；并认为猫儿山小鲵与挂榜山小鲵为同物异名。 综上，本研究较为完整地勾勒了小鲵属的系统发育关系全貌，并对小鲵属物种的起源进行了推测。 Hynobius, the type genus of the Family Hynobiidae, is the only exclusively Asian salamander genus. This genus which contains 29 species (beyond half of total Family), is the key group in Hynobiidae. The genus distributed across Palaearctic and Oriental Realm, and was found in China, Korea, and Japan. Systematics of genus Hynobius draws attention of researchers all the times. Resolving the taxonomic and phynogenetic questions of Hynobius is very important to the evolutionary research of Family Hynobiidae. Firstly, studies on systematics of genus Hynobius based on morphology, karyotype and molecular phylogeny of Hynobius are reviewed along with existing questions of this genus. The sequential reaserch project of phylogenetics is perspectively outlined. Using molecular data, we compared Hynobius yunanicus with a sympatric species Pachyhynobius shangchengensis. Our cytb sequences associating with karyotypic and morphological data supportted that H. yunanicus is not a valid species, but a synonym of P. shangchengensis. Because of phenotypic plasticity, some morphological characters are not even suitable for identifying hynobiids. The taxonomy of hynobiids is still controversial to a certain extent (Zhao et al. 1993; Fei, 1999; Chen et al. 2001; Zeng et al. 2006) and needs to be resolved by a new method. Here we examined the utility of COI barcoding for the discrimination of hynobiids. Meantime, the taxonomy of this Family was looked-over again. Our result show that the DNA Barcoding based on COI is easier and more rapidly than classic methods. And the DNA Barcodes data supported the actual taxonomy of Hynobiidae. Based on the achievements of our research, the phylogeny of Hynobius was reconstructed including some new species (H. maoershanensis, H. guabangshanensis, etc). Besides the phylogenetics of Hynobius was outlined, some questions and the hypothesis about the origin of genus Hynobius was put out.

Using the ribosomal internal transcribed spacer (ITS) as a complement marker for species identification of red macroalgae

Barcodes based on mitochondrial cytochrome oxidase (mtDNA CO1) sequences are being used for broad taxonomic groups of animals with demonstrated success in species identification and cryptic species discovery, but it has become clear that complementation by a nuclear marker system is necessary, in particular for the barcoding of plants. Here, we propose the nuclear internal transcribed spacer (ITS) as a potentially usable and complementary marker for species identification of red macroalgae, as well as present a primary workflow for species barcoding. Data show that for most red macroalgal genera (except members of the family Delesseriaceae), the size of ITS region ranges from 600 to 1200 bp, and contains enough variation to generate unique identifiers at either the species or genus levels. Consistent with previous studies, we found that the ITS sequence can resolve closely related species with the same fidelity as mtDNA CO1. Significantly, we confirmed that length polymorphism in the ITS region (including 5.8S rRNA gene) can be utilized as a character to discriminate red macroalgal species. As a complementary marker, the verifiable nuclear ITS region can speed routine identification and the detection of species, advance ecological and taxonomic inquiry, and permit rapid and accurate analysis of red macroalgae.