[On the phylogenetic position of Hexapoda within the Pancrustacea].

Contemporary views on the phylogeny of arthropods are at odds with the traditional system, which recognizes four independent arthropod classes: Chelicerata, Crustacea, Myriapoda and Insecta. There is compelling evidence that insects in fact comprise a monophyletic lineage with Crustacea within a larger clade of Pancrustacea (=Tetraconata). Which crustacean group is the closest living relative of insects remains an open question. Recent phylogenetic analyses based on multiple genes suggest their sistership with "lower" crustaceans, the Branchiopoda. This relationship was often impeached to be caused by the long branch attraction artifact. We analyzed concatenated data on 77 ribosomal proteins, elongation factor 1 alpha (EF1A), initiation factor 5 alpha (alF5A) and other selected nuclear and mitochondrial proteins. Nuclear protein data supports the monophyly of Hexapoda, the clade uniting entognath and ectognath insects. Hexapoda and Branchiopoda comprise a monophyletic lineage in most analyses. Maxillopoda occupies the sister position to the Hexapoda + Branchiopoda. "Higher" crustaceans, the Malacostraca, in most reconstructions comprise a more basal lineage withinthe Pancrustacea. Molecular synapomorphies in low homoplastic regions are found for the clades Hexapoda Branchiopoda + Maxillopoda and the monophyletic Malacostraca containing the Phyllocarida. Therefore, the sistership of Hexapoda and Branchiopoda and their position within Entomostraca may in fact represent bona fide phylogenetic relationships.

Do we need many genes for phylogenetic inference?

Fifty-six nuclear protein coding genes from Taxonomically Broad EST Database and other databases were selected for phylogenomic-based examination of alternative phylogenetic hypotheses concerning intergroup relationship between multicellular animals (Metazoa) and other representatives of Opisthokonta. The results of this work support sister group relationship between Metazoa and Choanoflagellata. Both of these groups form the taxon Holozoa along with the monophyletic Ichthyosporea or Mesomycetozoea (a group that includes Amoebidium parasiticum, Sphaeroforma arctica, and Capsaspora owczarzaki). These phylogenetic hypotheses receive high statistical support both when utilizing whole alignment and when only 5000 randomly selected alignment positions are used. The presented results suggest subdivision of Fungi into Eumycota and lower fungi, Chytridiomycota. The latter form a monophyletic group that comprises Chytridiales+Spizellomycetales+Blastocladiales (Batrachochytrium, Spizellomyces, Allomyces, Blastocladiella), contrary to the earlier reports based on the analysis of 18S rRNA and a limited set of protein coding genes. The phylogenetic distribution of genes coding for a ubiquitin-fused ribosomal protein S30 implies at least three independent cases of gene fusion: in the ancestors of Holozoa, in heterotrophic Heterokonta (Oomycetes and Blastocystis) and in the ancestors of Cryptophyta and Glaucophyta. Ubiquitin-like sequences fused with ribosomal protein S30 outside of Holozoa are not FUBI orthologs. Two independent events of FUBI replacement by the ubiquitin sequence were detected in the lineage of C. owczarzaki and in the monophyletic group of nematode worms Tylenchomorpha+Cephalobidae. Bursaphelenchus xylophilus (Aphelenchoidoidea) retains a state typical of the rest of the Metazoa. The data emphasize the fact that the reliability of phylogenetic reconstructions depends on the number of analyzed genes to a lesser extent than on our ability to recognize reconstruction artifacts.

[On the genetic uniformity of the genus Trichoplax (Placozoa)]. / O geneticheskom odnoobrazii v rode Trichoplax (Placozoa).

Fragments of the nuclear and mitochondrial genes for the large-subunit rRNA were compared for Trichoplax sp. and T. adhaerens. High similarity was observed for their sequences, suggesting that different Trichoplax isolates belong to one species.