[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.

[Primary structure of hairpin 35 and 48 small rRNA is proof that Trefusiidae is a subtaxon of marine Enoplida (Nemotoda)]. / Pervichnaia struktura petel' 35 i 48 maloi rRNK svidetel'stvuet, chto Trefusiidae iavliaiutsia subtaksonom morskikh Enoplida (Nematoda).

A rare nucleotide substitution was found in the evolutionarily conserved loop of hairpin 35 of the 18S rRNA gene of marine free-living nematode, Trefusia zostericola (Nematoda: Enoplida). The same substitution was found in all the marine Enoplida studied but not in other nematodes. Such a molecular synapomorphy indicates that marine enoplids are more closely related to T. zostericola than to freshwater Triplonchida. Maximum parsimony, neighbor-joining, and maximum likelihood analyses of complete nucleotide sequences of the gene, with the heterogeneity of nucleotide sites in evolution rates taken into account, support this conclusion. Hence, the hypothesis of particular primitiveness of Trefusiidae among nematodes should be rejected. Phylogenies based on molecular data support the morphological reduction of metanemes in Trefusiidae. Alongside with the unique change in hairpin 35 loop among marine Enoplida (including T. zostericola), hairpin 48 is also modified by a rare transversion which could be found among Mesorhabditoidea nematodes, in related genera Pelodera, Mesorhabditis, Teratorhabditis, Parasitorhabditis, Crustorhabditis, and Distolabrellus, and in 11 orders of Rhodophyta. Rare mutations in hairpins 35 and 48 tend to be fixed correlatively in evolution and could be found in all the Acanthocephala species. X-Ray data show that these regions (H31 and H43, in alternative nomenclature) are spatially brought together in native ribosomes. The nature and distribution of molecular autoapomorphies in phylogenetic trees of high-rank taxa are discussed.