六足总纲系统发育研究进展与新分类系统

简要综述了昆虫分纲、分目的历史变化,包括昆虫分目多少的变化,昆虫是纲级还是总纲级阶元的变化,昆虫各目分类地位系统排列的变化以及六足总纲系统发育研究进展。根据近10年来形态特征与分子测序数据相结合的系统发育研究,整理出六足总纲与系统发育支序分析相一致的分类系统,对昆虫35目的分类运用了10个分类阶元。在此基础上,删减次要分类阶元,提出简明分类系统,既反映每个高级分类单元的单系性,明晰各目的共祖近度,又减少了分类阶元层次,方便各分类单元的识别与鉴定。六足总纲Hexapoda分为4纲:原尾纲Protura(包括蚖目Acerentomata、华蚖目Sinentomata、古蚖目Eosentomata),弹尾纲Collembola(包括弹尾目Collembola),双尾纲Diplura(包括双尾目Diplura),昆虫纲Insecta。昆虫纲分为单髁亚纲SubclassMonocondylia(包括石蛃目Archaeognatha)与双髁亚纲SubclassDicondylia。双髁亚纲分为衣鱼部DivisionZygentoma(包括衣鱼目Zygentoma)与有翅部DivisionPterygota。有翅部分为10个总目、27目。     

旋唇纲系统发育基因组学分析支持瘦尾虫属归于散毛目

根据传统形态学特征的系统分类学研究,将瘦尾虫属(Uroleptus)归入尾柱目(Urostylida).但是,基于单基因和多基因联合的分子系统发育学分析支持瘦尾虫属与散毛目内部类群的亲缘关系更近.为进一步探讨旋唇纲(Spirotrichea)内部类群的系统发育关系以及瘦尾虫属的系统发育地位,我们对四种旋唇纲纤毛虫(澳大利亚速体虫(Notohymena australis)、瘦尾虫属未定种(Uroleptus sp.)、弹跳虫属未定种(Halteria sp.)和楯纤虫属未定种(Aspidisca sp.))进行单细胞转录组测序,并基于151个直系同源基因的51 596个氨基酸位点对旋唇纲开展更全面的系统发育基因组学分析.分析结果支持旋唇纲中四个亚纲单系:寡毛亚纲与环毛亚纲聚为姐妹枝,腹毛亚纲与这两个亚纲的亲缘关系更近,游仆亚纲位于旋唇纲的基部.尾柱目非单系,瘦尾虫属与散毛目中的尖毛虫科聚为一支,系统发育基因组学分析结果支持瘦尾虫属归于散毛目.     

六足动物分子系统学研究进展

对近期国内外六足总纲动物的原尾纲、弹尾纲、双尾纲和昆虫纲在种群遗传变异及进化、种及种下阶元的分类鉴定、种上阶元的系统发育分析等分子系统学方面的研究进展进行了综述。多基因的联合分子数据研究日益增加。随着分子技术的日益推广,不同类型的基因序列甚至全基因组的联合使用将引导分子系统学走向辉煌的未来。     

六足亚门内颚纲问题浅析

依据近年来在六足动物系统学研究中取得的最新成果,对一些动物学教材中有关六足动物中内颚纲的有效性、进化地位等问题进行浅析,提供原尾纲、弹尾纲和双尾纲的形态、习性和代表物种的相关更新资料,供生物学专业的师生参考.     

跳虫分类简介

简要介绍了目前逐步被国际跳虫分类学界所接受、由Deharveng（2004）提出、Bellinger、Christiansen及Janssens（2009）等共同修改的一个最新跳虫分类系统——“弹尾纲”4目分类系统．供我国相关同行讨论和参考,、     

rDNA在昆虫纲系统发育研究中的应用

昆虫纲是动物界种类最丰富的一个类群,研究昆虫的系统发育对了解生物进化历程及进化机制都有重要意义。传统的系统发育研究主要依赖于物种的生物学性状、形态解剖特征、以及生物地理学信息等。但是,随着学科的发展,也遇到了一些传统方法难以解决的困难,例如：由于物种间可供比较的形态学性状是有限的,一些进化距离较远的类群难以统一分析,这对于高级分类阶元的研究尤为突出;由于超同进化的存在,不同类群的物种可能表现出相似的形态特征;用形态特征定义一个分类阶元,就必须对标本的完整性、性别、生长阶段有严格的要求;此外,对形…     

一种改进的小型节肢动物无形态损伤的DNA提取方法

本文介绍了一种改进的小型节肢动物无形态损伤的DNA提取方法,并在双尾纲、原尾纲和弹尾纲中进行了实验验证。结果表明,该方法可以高效的提取三类小型节肢动物的DNA,并用于扩增目标基因序列,凭证标本的回收质量高,有助于进一步的分类鉴定。该方法有望对螨、蚜虫、介壳虫、蚤等其他小型节肢动物的分子鉴定提供方便。     

中国鳞姚属一新种(弹尾纲,鳞姚科)

记述了采自中国四川鳞姚属(弹尾纲,鳞姚科)1新种,模式标本保存在西南科技大学生命科学与工程学院昆虫标本室.九寨鳞姚,新种omocerus jiuzhaiensis sp.nov.(图1～11)该种与f zayuensis Huang and Yin,1981和f ocreatus Dems,1948相似,主要区别是齿节刺结构、胫跗节刺状钝毛数、小爪内齿的有无、握弹器体上刚毛数等.新种主要鉴别特征：齿节刺简单,胫跗节刺状钝毛数为6、6、6,小爪有1内齿、握弹器体上刚毛数为17支,弹器端节间齿数为3～4.词源：新种种名源自模式标本采集地地名.     

弹尾虫单克隆抗体的制备及其在捕食研究中的应用

应用杂交瘤技术制备了针对弹尾虫的单克隆抗体2F10。该抗体的效价为1.024×108,只与灰橄榄长角跳虫、球角跳虫和钩圆跳虫等弹尾虫发生强烈反应而不与稻田常见的其它昆虫和蜘蛛发生交叉反应,具有高度特异性。建立了2F10、HRP-2F10和蜘蛛样品分别稀释4000倍(34.193ng/L)、1500倍(2.4624ng/L)和50倍(50ml/individual)的抗体夹心ELISA检测系统用于检测稻田常见蜘蛛对弹尾虫的捕食作用。其检测灵敏度为1/2头灰橄榄长角跳虫(4.49μg),拟环纹豹蛛捕食1头灰橄榄长角跳虫成虫后,在25℃下猎物的可测定时间为4.5h。应用该检测系统研究了不同稻区常见蜘蛛对2F10的阳性反应率。其中狡蛛、拟环纹豹蛛、纵条蝇狮和纵条蝇虎的阳性反应率显著高于食虫瘤胸蛛、八斑球腹蛛和锥腹肖蛸。     

低等六足动物系统学研究进展

低等六足动物包括原尾纲、弹尾纲和双尾纲三个类群,是探讨六足动物起源和进化问题的关键类群,近十年来成为节肢动物系统进化研究中的焦点之一。低等六足动物的系统发育地位以及它们之间的关系一直是备受争论的问题。通过介绍三类低等六足动物最新的分类系统,从经典分类学和系统发育两个方面对低等六足动物近十年来的研究进展进行了综述。迄今,对于三类低等六足动物都建立了比较完备的分类体系,原尾纲划分为3目10科,弹尾纲划分为4目30科,双尾纲划分为2亚目3总科10科。系统发育研究中,大多数的系统发育分析结果不支持传统的缺尾类假说,缺尾纲应摒弃不用。分子数据分析的结果普遍支持原尾纲与双尾纲近缘,但仍需要进一步探讨。线粒体基因组、比较胚胎学和比较精子学的研究结果表明,原尾纲可能经历了长期的趋异进化历史。最近的比较精子学研究支持了双尾纲的单系性。总之,三类低等六足动物系统学研究均取得了长足的发展,但仍然存在诸如研究人员匮乏和研究水平不均衡等问题。系统发育研究中,分子系统学研究成为关注的焦点,而基于核基因和线粒体基因的数据分别建立的系统发育假说存在分歧,亟需开发更优的数据分析方法。此外,需加强低等六足动物比较形态学、比较胚胎学、发育生物学等方面的研究,以便将来进行全证据的系统发育研究。     

The phylogenetic positions of three Basal-hexapod groups (protura, diplura, and collembola) based on ribosomal RNA gene sequences

This study combined complete 18S with partial 28S ribosomal RNA gene sequences ( approximately 2,000 nt in total) to investigate the relations of basal hexapods. Ten species of Protura, 12 of Diplura, and 10 of Collembola (representing all subgroups of these three clades) were sequenced, along with 5 true insects and 8 other arthropods, which served as out-groups. Trees were constructed with maximum parsimony, maximum likelihood, Bayesian analysis, and minimum-evolution analysis of LogDet-transformed distances. All methods yielded strong support for a clade of Protura plus Diplura, here named Nonoculata, and for monophyly of the Diplura. Parametric-bootstrapping analysis showed our data to be inconsistent with previous hypotheses (P < 0.01) that joined Protura with Collembola (Ellipura), that said Diplura are sister to true insects or are diphyletic, and that said Collembola are not hexapods. That is, our data are consistent with hexapod monophyly and Collembola grouped weakly with "Protura + Diplura" under most analytical conditions. As a caveat to the above conclusions, the sequences showed nonstationarity of nucleotide frequencies across taxa, so the CG-rich sequences of the diplurans and proturans may have grouped together artifactually; however, the fact that the LogDet method supported this group lessens this possibility. Within the basal hexapod groups, where nucleotide frequencies were stationary, traditional taxonomic subgroups generally were recovered: i.e., within Protura, the Eosentomata and Acerentomata (but Sinentomata was not monophyletic); within Collembola, the Arthropleona, Poduromorpha, and Entomobryomorpha (but Symphypleona was polyphyletic); and in Diplura, the most complete data set (> 2,100 nt) showed monophyly of Campodeoidea and of Japygoidea, and most methods united Projapygoidea with Japygoidea.     

Is Ellipura monophyletic? A combined analysis of basal hexapod relationships with emphasis on the origin of insects

Hexapoda includes 33 commonly recognized orders, most of them insects. Ongoing controversy concerns the grouping of Protura and Collembola as a taxon Ellipura, the monophyly of Diplura, a single or multiple origins of entognathy, and the monophyly or paraphyly of the silverfish (Lepidotrichidae and Zygentoma s.s.) with respect to other dicondylous insects. Here we analyze relationships among basal hexapod orders via a cladistic analysis of sequence data for five molecular markers and 189 morphological characters in a simultaneous analysis framework using myriapod and crustacean outgroups. Using a sensitivity analysis approach and testing for stability, the most congruent parameters resolve Tricholepidion as sister group to the remaining Dicondylia, whereas most suboptimal parameter sets group Tricholepidion with Zygentoma. Stable hypotheses include the monophyly of Diplura, and a sister group relationship between Diplura and Protura, contradicting the Ellipura hypothesis. Hexapod monophyly is contradicted by an alliance between Collembola, Crustacea and Ectognatha (i.e., exclusive of Diplura and Protura) in molecular and combined analyses.     

Brain organization in Collembola (springtails)

Arthropoda is comprised of four major taxa: Hexapoda, Crustacea, Myriapoda and Chelicerata. Although this classification is widely accepted, there is still some debate about the internal relationships of these groups. In particular, the phylogenetic position of Collembola remains enigmatic. Some molecular studies place Collembola into a close relationship to Protura and Diplura within the monophyletic Hexapoda, but this placement is not universally accepted, as Collembola is also regarded as either the sister group to Branchiopoda (a crustacean taxon) or to Pancrustacea (crustaceans + hexapods). To contribute to the current debate on the phylogenetic position of Collembola, we examined the brains in three collembolan species: Folsomia candida, Protaphorura armata and Tetrodontophora bielanensis, using antennal backfills, series of semi-thin sections, and immunostaining technique with several antisera, in conjunction with confocal laser scanning microscopy and three-dimensional reconstructions. We identified several neuroanatomical structures in the collembolan brain, including a fan-shaped central body showing a columnar organization, a protocerebral bridge, one pair of antennal lobes with 20-30 spheroidal glomeruli each, and a structure, which we interpret as a simply organized mushroom body. The results of our neuroanatomical study are consistent with the phylogenetic position of Collembola within the Hexapoda and do not contradict the hypothesis of a close relationship of Collembola, Protura and Diplura.     

The phylogenetic interrelationships of the higher taxa of apterygote hexapods

The phylogeny of the basal hexapods, the so-called apterygote insects, was studied using parsimony analysis procedures. Most analyses took into account 47 characters mainly based on external morphology, and 19 taxa including 14 apterygote representatives, 3 pterygotes and also 2 distantly related myriapods were used as outgroups. The binary and multistate characters are discussed in detail and treated as unordered and equally weighted. Other analyses were performed using a second data set in which 28 characters, based on internal anatomy and already used in a previous work ( Bitsch & Bitsch 1998 ), were added to the first data set. This second matrix was restricted to 12 terminal taxa, the same as those of our previous work. The results of the different analyses are generally congruent. They strongly support the monophyly of several orders (Protura, Collembola, Archaeognatha) and of two groupings (Ectognatha, Dicondylia). Three other assemblages (Ellipura, Diplura, Entognatha) appear as parsimonious phylogenetic hypotheses, but they are never supported by the cladistical analyses and are based on a very small number of autapomorphies; so, the monophyly of each of them is not firmly established. Archaeognatha appears as the sister group of the Dicondylia. The three unresolved representatives of the Zygentoma are found as the sister group of the Pterygota. The results are discussed in the light of current concepts in hexapod phylogeny.     

Towards an 18S phylogeny of hexapods: accounting for group-specific character covariance in optimized mixed nucleotide/doublet models

The phylogenetic diversification of Hexapoda is still not fully understood. Morphological and molecular analyses have resulted in partly contradicting hypotheses. In molecular analyses, 18S sequences are the most frequently employed, but it appears that 18S sequences do not contain enough phylogenetic signals to resolve basal relationships of hexapod lineages. Until recently, character interdependence in these data has never been treated seriously, though possibly accounting for the occurrence of biased results. However, software packages are readily available which can incorporate information on character interdependence within a Bayesian approach. Accounting for character covariation derived from a hexapod consensus secondary structure model and applying mixed DNA/RNA substitution models, our Bayesian analysis of 321 hexapod sequences yielded a partly robust tree that depicts many hexapod relationships congruent with morphological considerations. It appears that the application of mixed DNA/RNA models removes many of the anomalies seen in previous studies. We focus on basal hexapod relationships for which unambiguous results are missing. In particular, the strong support for a “Chiastomyaria” clade (Ephemeroptera+Neoptera) obtained in Kjer's [2004. Aligned 18S and insect phylogeny. Syst. Biol. 53, 1–9] study of 18S sequences could not be confirmed by our analysis. The hexapod tree can be rooted with monophyletic Entognatha but not with a clade Ellipura (Collembola+Protura). Compared to previously published contributions, accounting for character interdependence in analyses of rRNA data presents an improvement of phylogenetic resolution. We suggest that an integration of explicit clade-specific rRNA structural refinements is not only possible but an important step in the optimization of substitution models dealing with rRNA data.     

Testing for misleading effects in the phylogenetic reconstruction of ancient lineages of hexapods: influence of character dependence and character choice in analyses of 28S rRNA sequences

The present analyses employ the almost complete sequence of the 28S rRNA gene to investigate phylogenetic relationships among Pancrustacea, placing special emphasis on the position of basal hexapod lineages. This study utilizes a greater number of characters and taxa of Protura, Collembola and Diplura than previous analyses to focus on conflicts in the reconstruction of the early steps in hexapod evolution. Phylogenetic trees are mainly based on Bayesian approaches, but likewise include analyses with Maximum Likelihood and Maximum Parsimony. Different analyses, including the application of a mixed DNA/RNA substitution model, were performed to narrow possible misleading effects of non-stationarity of nucleotide frequencies, saturation and character independence down to a minimum. This is the first time that a mixed DNA/RNA model is applied to analyse 28S rRNA sequences of basal hexapods. All methods yielded strong support for the monophyly of Collembola, Diplura, Dicondylia and Insecta s.str. , as well as for a cluster composed of Diplura and Protura ('Nonoculata-hypothesis'). However, the last cluster may be an artifact caused by a shared GC bias of the 28S sequences between these orders, in combination with a long branch effect. The instability of the position of the 'Nonoculata' within Pancrustacea further bears out the misleading effect of non-stationarity of nucleotide frequencies. Protura and Diplura either form the sister-group to Collembola (Entognatha) or cluster with branchiopod crustaceans. Overall, the phylogenetic signal of the complete sequences of the 28S rRNA gene favours monophyly of Hexapoda over paraphyly. However, further corroboration from independent data is needed to rule out the competing hypothesis of mutually paraphyletic Crustacea and Hexapoda.     

The spermatogenesis and sperm structure of Acerentomon microrhinus (Protura, Hexapoda) with considerations on the phylogenetic position of the taxon

The spermatogenesis of the proturan Acerentomon microrhinus Berlese, (Redia 6:1–182, 1909) is described for the first time with the aim of comparing the ultrastructure of the flagellated sperm of members of this taxon with that of the supposedly related group, Collembola. The apical region of testes consists of a series of large cells with giant polymorphic nuclei and several centrosomes with 14 microtubule doublets, whose origin is likely a template of a conventional 9-doublet centriole. Beneath this region, there are spermatogonial cells, whose centrosome has two centrioles, both with 14 microtubule doublets; the daughter centriole of the pair has an axial cylinder. Slender parietal cells in the testes have centrioles with nine doublet microtubules. Spermatocytes produce short primary cilia with 14 microtubule doublets. Spermatids have a single basal body with 14 microtubule doublets. Anteriorly, a conical dense material is present, surrounded by a microtubular basket, which can be seen by using an α-anti-tubulin antibody. Behind this region, the basal body expresses a long axoneme of 14 microtubule doublets with only inner arms. An acrosome is lacking. The nucleus is twisted around the apical conical dense structure and the axoneme; this coiling seems to be due to the rotation of the axoneme on its longitudinal axis. The posterior part of the axoneme forms three turns within the spermatid cytoplasm. Few unchanged mitochondria are scattered in the cytoplasm. Sperm consist of encysted, globular cells that descend along the deferent duct lumen. Some of them are engulfed by the epithelial cells, which thus have a spermiophagic activity. Sperm placed in a proper medium extend their flagellar axonemes and start beating. Protura sperm structure is quite different from that of Collembola sperm; and on the basis of sperm characters, a close relationship between the two taxa is not supported.     

Sequence of mitochondrial DNA cytochrome oxidase II inCryptopygus nanjiensis and Phylogeny of Apterygota

The mitochondrial cytochrome oxidase II (Co II) from four different apterygotens Cryptopygus nanjiensis (Collembola), Neanura latior (Collembola), Gracilentulus maijiawensis (Protura) and Lepidocampa weberi (Diplura) were sequenced. Their A T content, number of nucleotide substitutions, TV/TV ratio, and Tamura-Nei's distance were calculated. A series of phylogenetic trees were constructed by parsimony and distance methods using a crustacean Artemia franciscana as outgroup. Finally the evolutionary trend A T content of CO II genetic divergence and phylogenetic relationship of apterygotan groups were discussed.