Molecular phylogeny in mytilids supports the wooden steps to deep-sea vents hypothesis.

Molecular data were used to study the diversity of mytilids associated with sunken-woods sampled in the Solomon Islands and discuss the 'wooden steps to deep-sea vent' hypothesis proposed by Distel et al. First, COI data used in a barcoding approach confirm the presence of four distinct species. Analyses of the 18S rDNA and COI dataset then confirmed that these sunken-wood mytilids belonged to a monophyletic group including all species from deep-sea reducing environments. Finally, we analyzed the relationships within this monophyletic group that include the Bathymodiolinae using a COI dataset and a combined analysis of mitochondrial COI and ND4 genes and nuclear rDNA 18S and 28S. Our study supported the 'wooden steps to deep-sea vent' hypothesis: one of the sunken-wood species had a basal position within the Bathymodiolionae, and all described vent and seep mussels included in our analyses were derived taxa within Bathymodiolinae.

The phylogenetic position of the 'living fossils' Neoglyphea and Laurentaeglyphea (Decapoda: Glypheidea).

The Glypheidea is a group of lobster-like decapods that appeared in the Triassic and that was thought to be extinct until 1975, when a specimen of the species Neoglyphea inopinata was caught off the Philippines. More recently, in 2005, a specimen of another glypheid species, Laurentaeglyphea neocaledonica, was discovered near New Caledonia. Here, we construct a decapod molecular data set including the two extant glypheid species sequenced from eight nuclear and mitochondrial genes. Our study strongly shows that the two extant genera of glypheids cluster together, and further confirms the status of Glypheidea as a separate infraorder. Moreover the reptantian decapods are divided into two major groups, one including Brachyura, Anomura, and Axiidea, and the other including Astacidea, Polychelida, Achelata, and Glypheidea. Although commonly nicknamed 'Jurassic shrimps' and considered as 'living fossils', glypheids are therefore a derived decapod lineage.

A gleam in the dark: phylogenetic species delimitation in the confusing spring-snail genus Bythinella Moquin-Tandon, 1856 (Gastropoda: Rissooidea: Amnicolidae).

We re-assess the value of morphological specific descriptors within the spring-snail genus Bythinella by sequencing mitochondrial COI and nuclear ITS1 gene fragments. Taxonomic coverage represents 16 nominal species sampled among 35 populations from France. Application of monophyly and cohesive haplotype networks as criteria to delineate species allow us to identify 10 mitochondrial species-level lineages, all but one of which are recovered by ITS1. COI species thresholds that are estimated from newly delimited species (ca. 1.5%) agree with values found among other hydrobioids. Our results strongly suggest that classical morphological descriptors may not constitute valid specific criteria within Bythinella. Our analyses support a complex scenario of invasions of subterranean habitats, as illustrated by the syntopy of several mitochondrial lineages or the conflicting evolutionary histories between COI and ITS1 in caves. In addition, morphological convergence related to subterranean ecological constraints that affect shell shape and size among the hypogean springsnails studied is suspected.

Molecular phylogenies support multiple morphological reductions in the liverwort subclass Marchantiidae (Bryophyta).

The phylogeny of one of the putative basal-most group of land plants, the Marchantiidae, is estimated with morphological characters and with sequences of the nuclear (LSU) rDNA gene (first four domains of the 5' end of the 26S rRNA and four subsequent regions) from 34 species and 27 genera. Molecular and morphological data display high degrees of incongruence. The molecular tree topology predominates in the combined analysis. A trend from complex towards simpler morphological traits is apparent from the molecular and combined trees, whereas a trend from simple towards complex traits prevails in the morphological tree. Previously published molecular data corroborate the molecular results. It is suggested that the incongruence stems from the presence of coherent sets of reduction-related morphological traits varying in concert in the morphological data. Marchantiidae is traditionally subdivided into Marchantiales, Sphaerocarpales and Monocleales, with the majority of taxa referred to the first group. The molecular and the combined data both indicate unequivocally that Sphaerocarpales and Monocleales are nested within Marchantiales, and this result is not explicitly refuted by the morphological data.