Evolutionary Relations of Hexanchiformes Deep-Sea Sharks Elucidated by Whole Mitochondrial Genome Sequences

Hexanchiformes is regarded as a monophyletic taxon, but the morphological and genetic relationships between the five extant species within the order are still uncertain. In this study, we determined the whole mitochondrial DNA (mtDNA) sequences of seven sharks including representatives of the five Hexanchiformes, one squaliform, and one carcharhiniform and inferred the phylogenetic relationships among those species and 12 other Chondrichthyes (cartilaginous fishes) species for which the complete mitogenome is available. The monophyly of Hexanchiformes and its close relation with all other Squaliformes sharks were strongly supported by likelihood and Bayesian phylogenetic analysis of 13,749 aligned nucleotides of 13 protein coding genes and two rRNA genes that were derived from the whole mDNA sequences of the 19 species. The phylogeny suggested that Hexanchiformes is in the superorder Squalomorphi, Chlamydoselachus anguineus (frilled shark) is the sister species to all other Hexanchiformes, and the relations within Hexanchiformes are well resolved as Chlamydoselachus, (Notorynchus, (Heptranchias, (Hexanchus griseus, H. nakamurai))). Based on our phylogeny, we discussed evolutionary scenarios of the jaw suspension mechanism and gill slit numbers that are significant features in the sharks

Immunoreceptor tyrosine-based inhibition motifs : a quest in the past and future

International audienceSince an immunoreceptor tyrosine-based inhibition motif (ITIM) was first identified in the intracytoplasmic domain of Fc gammaRIIB, ITIMs have been found in a large number of inhibitory molecules that were shown to negatively regulate cell activation. Due to their wide tissue distribution and to the variety of their extracellular ligands, ITIM-containing molecules are involved in the control of a large spectrum of biological functions, mostly but not exclusively related to immunity. On the basis of sequence comparison, ITIMs were structurally defined as 6-amino acid sequences containing a tyrosine (Y) with loosely conserved N-terminal (Y-2) and C-terminal (Y+3) residues. Molecular analysis of signaling events demonstrated that when coaggregated with activating receptors, ITIMs are phosphorylated by Src-family tyrosine kinases, which enables them to recruit Src homology 2 domain-containing phosphatases that antagonize activation signals. Because ITIM-dependent negative regulation seems to be a fundamental regulatory mechanism, both in rodents and in humans, and because it can be used either as a target or as a powerful tool in various diseases, we undertook (i) a genome-wide search of potential novel ITIM-containing molecules in humans, mice, frogs, birds, and flies and (ii) a comparative analysis of potential ITIMs in major animal phyla, from mammals to protozoa. We found a surprisingly high number of potential ITIM-containing molecules, having a great diversity of extracellular domains, and being expressed by a variety of immune and non-immune cells. ITIMs could be traced back to the most primitive metazoa. The genes that encode ITIM-containing molecules that belong to the immunoglobulin superfamily or to the C-lectin family seem to derive from a common set of ancestor genes and to have dramatically expanded and diverged in Gnathostomata (from fish to mammals)