Parasite histories and novel phylogenetic tools: alternative approaches to inferring parasite evolution from molecular markers

Parasitological research is often contingent on the knowledge of the phylogeny/genealogy of the studied group. Although molecular phylogenetics has proved to be a powerful tool in such investigations, its application in the traditional fashion, based on a tree inference from the primary nucleotide sequences may, in many cases, be insufficient or even improper. These limitations are due to a number of factors, such as a scarcity/ambiguity of phylogenetic information in the sequences, an intricacy of gene relationships at low phylogenetic levels, or a lack of criteria when deciding among several competing coevolutionary scenarios. With respect to the importance of a precise and reliable phylogenetic background in many biological studies, attempts are being made to extend molecular phylogenetics with a variety of new data sources and methodologies. In this review, selected approaches potentially applicable to parasitological research are presented and their advantages as well as drawbacks are discussed. These issues include the usage of idiosyncratic markers (unique features with presumably low probability of homoplasy), such as insertion of mobile elements, gene rearrangements and secondary structure features; the problem of ancestral polymorphism and reticulate relationships at low phylogenetic levels; and the utility of a molecular clock to facilitate discrimination among alternative scenarios in host-parasite coevolution.     

基部藓类分子系统学研究

基部藓类是稳定地处于藓类系统发育树基部的类群.它包括7纲,2亚纲,10目,10科,34属,637种.基部藓类虽然只占藓类种类的5％,但由于其内部各类群孢子体形态极为丰富,因此对于理解整个藓类植物的系统发育具有重要意义.通过对48个种(36个藓类、4个维管植物、2个角苔、4个苔类和2个藻类)的9个DNA片段(NU:26S,18S; MT:nad5,cox1; CP:rbcL,rps4,cp-LSU,cp-SSU,atpB)进行分子系统学分析,综合最大似然法(maximum likelihood)、最大简约法(most parsimony)和贝叶斯分析(Bayesian inference)方法的建树结果,理清了前人研究中存在冲突的类群之间的关系并为已确定的关系提供了更高的支持率.研究结果如下:(1)藻苔纲和泥炭藓纲互为姐妹类群,处于整个藓类的最基部;(2)黑藓纲与黑真藓纲互为姐妹类群(3)长台藓纲和具齿藓类组成单系;(4)四齿藓纲是所有具齿藓类的基部类群;(5)烟杆藓亚纲处于真藓纲的最基部,其次是短颈藓亚纲.以上结论在分子系统树上得到了很高的支持率.     

Higher-level classification of the Archaea: evolution of methanogenesis and methanogens

We used a phylogenetic approach to analyze the evolution of methanogenesis and methanogens. We show that 23 vertically transmitted ribosomal proteins do not support the monophyly of methanogens, and propose instead that there are two distantly related groups of extant archaea that produce methane, which we have named Class I and Class II. Based on this finding, we subsequently investigated the uniqueness of the origin of methanogenesis by studying both the enzymes of methanogenesis and the proteins that synthesize its specific coenzymes. We conclude that hydrogenotrophic methanogenesis appeared only once during evolution. Genes involved in the seven central steps of the methanogenic reduction of carbon dioxide (CO(2)) are ubiquitous in methanogens and share a common history. This suggests that, although extant methanogens produce methane from various substrates (CO(2), formate, acetate, methylated C-1 compounds), these archaea have a core of conserved enzymes that have undergone little evolutionary change. Furthermore, this core of methanogenesis enzymes seems to originate (as a whole) from the last ancestor of all methanogens and does not appear to have been horizontally transmitted to other organisms or between members of Class I and Class II. The observation of a unique and ancestral form of methanogenesis suggests that it was preserved in two independent lineages, with some instances of specialization or added metabolic flexibility. It was likely lost in the Halobacteriales, Thermoplasmatales and Archaeoglobales. Given that fossil evidence for methanogenesis dates back 2.8 billion years, a unique origin of this process makes the methanogenic archaea a very ancient taxon.     

蜘蛛的精子发生

通过研究蜘蛛的精子形态和精子发生来探讨蜘蛛目的的系统发生,目前已越来越受到各国学者的重视。本文介绍国外近二十年来在这一领域的研究进展和成果,希望有助于在我国加速开展这方面的研究,深化对蜘蛛目的系统进化研究工作。     

Phylogenetic relationships among the lepidopteran and trichopteran suborders (Insecta) from the embryological standpoint1

Adopting the cladistic method in comparative embryology, 27 embryonic characters were analyzed to reconstruct the phylogenetic relationships among the lepidopteran and trichopteran suborders, viz., Annulipalpia, Integripalpia, Zeugloptera, Dacnonypha, Exoporia, Monotrysia, and Ditrysia. The resultant cladogram is basically coincident with that proposed by Kristensen . The order Trichoptera and Lepidoptera constitute a monophyletic group on the basis of one synapomorphy, the presence of well developed silk glands in embryos. The Trichoptera are separable from the Lepidoptera by the states of four characters. The Trichoptera, as a whole, are quite homogenous, and embryological data provide no rational ground for the separation of this order into the Annulipalpia and Integripalpia at a subordinal level. On the contrary, the embryonic development of the Lepidoptera becomes divergent from the most primitive condition to a specialized one according to suborders. The Zeugloptera are the sister group of all other Lepidoptera, because they share two apomorphies with the latter. The Dacnonypha are the most primitive next to the Zeugloptera, and have a sister-group relationship with the Exoporia + (Monotrysia + Ditrysia), being held together with the latter by five synapomorphies. Although the Exoporia retain almost as many plesiomorphic characters as the Dacnonypha, they have a sister-group relationship with the Monotrysia + Ditrysia, as inferred on the basis of two synapomorphies. The Monotrysia and Ditrysia have a sistergroup relationship, and are the most advanced groups in the Lepidoptera judging from their shared acquisition of many apomorphic characters.     

New phagotrophic euglenoid species (new genus Decastava; Scytomonas saepesedens; Entosiphon oblongum), Hsp90 introns,and putative euglenoid Hsp90 pre-mRNA insertional editing

We describe three new phagotrophic euglenoid species by light microscopy and 18S rDNA and Hsp90 sequencing: Scytomonas saepesedens; Decastava edaphica; Entosiphon oblongum. We studied Scytomonas and Decastava ultrastructure. Scytomonas saepesedens feeds when sessile with actively beating cilium, and has five pellicular strips with flush joints and Calycimonas-like microtubule-supported cytopharynx. Decastava, sister to Keelungia forming new clade Decastavida on 18S rDNA trees, has 10 broad strips with cusp-like joints, not bifurcate ridges like Ploeotia and Serpenomonas (phylogenetically and cytologically distinct genera), and Serpenomonas-like feeding apparatus (8–9 unreinforced microtubule pairs loop from dorsal jaw support to cytostome). Hsp90 and 18S rDNA trees group Scytomonas with Petalomonas and show Entosiphon as the earliest euglenoid branch. Basal euglenoids have rigid longitudinal strips; derived clade Spirocuta has spiral often slideable strips. Decastava Hsp90 genes have introns. Decastava/Entosiphon Hsp90 frameshifts imply insertional RNA editing. Petalomonas is too heterogeneous in pellicle structure for one genus; we retain Scytomonas (sometimes lumped with it) and segregate four former Petalomonas as new genus Biundula with pellicle cross section showing 2–8 smooth undulations and typified by Biundula (=Petalomonas) sphagnophila comb. n. Our taxon-rich site-heterogeneous rDNA trees confirm that Heteronema is excessively heterogeneous; therefore we establish new genus Teloprocta for Heteronema scaphurum.     

Apigenin and amentoflavone glycosides in the psilotaceae and their phylogenetic significance

Documentation of amentoflavone O-glucosides as the predominant flavonoid glycosides in both genera of the Psilotaceae clearly distinguishes this family from all other families of vascular plants. Psilotum and Tmesipteris also possess apigenin C- and O-glycosides as common flavonoid types. Apigenin 7-O-rhamnoglucoside occurs in both genera and the previously undocumented apigenin 7-O-rhamnoglucoside-4′-O-glucoside, although identified only in Tmesipteris, may also be present in Psilotum. The existence of flavone C-glycosides in both genera may provide a phytochemical relationship between the Psilotaceae and some ferns. The phylogenetic significance of these results is discussed.     

鸡形目鸟类系统发生研究现状

综合形态学、行为学、分子系统发生等方面研究成果,对世界鸡形目鸟类科的系统关系以及属、种间系统发生的研究进展进行了阐述,侧重介绍与我国鸡形目鸟类相关类群的系统发生研究现状。与传统的系统关系比较,新的研究结果主要有:凤冠雉科和冢雉科不再是互为姊妹群;传统分类中的雉族和鹑族被证明并非单源而是多源的;雉族的原鸡属与鹑族的竹鸡属有很近的亲缘关系;灰山鹑、火鸡和松鸡类的系统发生关系可能很近。分子进化的研究表明雉科各属的起源主要集中在上新世。     

Molecular Phylogeny and Coevolution

Abstract Recent advances in molecular phylogenetic estimation in diverse organisms have improved our understanding of coevolution. From the phylogenies of interacting organisms, we can interpret the evolution of adaptive characters, and the history of interaction. Molecular approaches are generally more informative than these based solely on phenotypic characters. Molecular genetic method can be applied to organisms that have only simple morphological features and can be used for comparisons at any taxonomic level. Estimation of divergence time is also possible but still difficult because evolutionary rates of macromolecules are not always constant and suitable fossil records are often not available for calibrating rates of change. Here I review recent progress in the application of molecular techniques to the interpretation of coevolutionary relationships.     

Shifting ditypic site analysis: Heuristics for expanding the phylogenetic range of nucleotide sequences in Sankoff analyses

Summary We describe and illustrate a simple heuristic approach to the Sankoff methods for construction of parsimonious evolutionary trees from nucleotide sequence data. The procedure is intended to permit more valid inferences, particularly from relatively short sequences, concerning relationships among taxa separated for long time intervals. The procedure is based on the freat variability of evolutionary plasticity among sites in the molecules and removes from consideration the more highly variable sites. Editing is accomplished after classifying sites in carefully aligned arrays of sequences. Only “ditypic sites,” i.e., sites observed in only two evolutionary states within the array, are used in making phylogenetic inferences. This strategy makes possible the construction of good approximations to the most parsimonious Steiner strees, by means of efficient programs that require “dense species arrays,” i.e., species sets that differ from each other by relatively small numbers of differences in conservative sites. The technique is illustrated with 5S and 5.8S rRNA sequence data from published catalogs.