Morphological and molecular characterization of adults and larvae of Crassicauda spp. (Nematoda: Spirurida) from Mediterranean fin whales Balaenoptera physalus (Linnaeus, 1758).

Crassicauda boopis is known to infect the kidneys and vascular system of mysticetes included Balaenoptera physalus and has been recently reported in Mediterranean waters. Identification at the species level relies on the observation of morphological features of the adult parasites, but field conditions during necropsy and the massive reaction of the host's immune system often prevent optimal conservation of the extremities. Moreover, larval stages of Crassicauda have never been described and no sequences are available in public databases to help such identification. Adult and larvae of Crassicauda were isolated from four specimens of B. physalus and studied with morphological and molecular techniques. Specimens of C. anthonyi, C. grampicola and Crassicauda sp. isolated from Ziphius cavirostris, Grampus griseus, Stenella coeruleoalba and Tursiops truncatus respectively were studied as well. Sequences of nuclear markers 18S and ITS-2 and of mitochondrial gene cox1 were obtained and phylogenetic relationships within the genus Crassicauda were analysed. Analysis of the ITS2 grouped the different species in accordance with morphological identification, as already evidenced in literature for other Spirurida. A higher intra-specific variability was observed for the cox1 gene, for which two species (C. grampicola and C. anthonyi) did not appear as monophyletic in the tree. Well-developed non-attached larval specimens in the intestinal lumen of a whale calf were molecularly identified as C. boopis, allowing new insights on the life cycle of this species. This work broadens the genetic database on cetaceans parasites, allowing species identification even in challenging field conditions or in poor conservation of the samples; moreover, the first morphological description of C. boopis larvae is provided.

Proposed new nomenclature for Bos taurus cytochromes P450 involved in xenobiotic drug metabolism.

The cytochrome P450 (CYP) superfamily of drug metabolizing enzymes (DMEs) plays a central role in the oxidative metabolism of xenobiotics to which living organisms are exposed. In Bos taurus (cattle), a definitive nomenclature for CYP proteins is still lacking, and to unambiguously settle cattle nomenclature a phylogenetic analysis of proteins belonging to CYP 1-4 families was performed. Sequences collected from GenBank and Dr Nelson's P450 homepage databases were analyzed according to the maximum likelihood method. Phylogenetic outputs showed that CYPs sharing the same name and collected from different species did not form, in several instances, monophyletic groups. Some cattle CYPs did not group with their supposed human orthologous counterparts, thus requiring a new nomenclature. Name changes mostly mirrored the orthologous counterparts established for other species, and new names were created when no clear orthologous sequences were identified. The new nomenclature will allow a more appropriate investigation of biochemical and molecular mechanisms involved in the expression and regulation of these DMEs.

Sequence comparison and phylogenetic analysis of fish nodaviruses based on the coat protein gene.

We have amplified by reverse transcription-polymerase chain reaction (RT-PCR) and sequenced a 605-bp fragment covering the variable region of the coat protein gene of fish nodaviruses infecting European sea bass, Dicentrarchus labrax (n = 24), and shi drum, Umbrina cirrosa (n = 2), in the Mediterranean basin. Nine new isolates were identified and their sequences were combined with sequences in the literature to produce three different data sets. The first set, based on amino acid sequences, was used to verify the monophyly of fish nodaviruses. The second and third data sets, based on nucleic acids, were used to resolve the phylogenetic relationships between closely related fish nodaviruses. Phylogenetic analyses were performed according to the maximum parsimony and neighbor-joining methods. Our results support the monophyly of fish nodaviruses. Moreover, they confirm the subdivision of fish nodaviruses into four main clusters, in agreement with the previously suggested phylogeny of the genus Piscinodavirus, that was based on a smaller number of sequences and an alternative phylogenetic approach [14]. All the Mediterranean isolates were clustered in the group of the red-spotted grouper nervous necrosis virus and appear to have a restricted geographic distribution, except for one sequence-type (10 samples) that is widespread throughout the basin.

The primary structure of globin and linker chains from the chlorocruorin of the polychaete Sabella spallanzanii.

Annelid hemoglobins are organized in a very complex supramolecular network of interacting polypeptides, the structure of which is still not wholly resolved. We have separated by two-dimensional electrophoresis the 4-MDa chlorocruorin of Sabella spallanzanii and identified its components by amino-terminal sequencing. This work reveals a high rate of heterogeneity of constituent chains in a single animal as well as in the Sabella population. Using a cDNA library prepared from the hematopoietic tissue of this worm, we have isolated and fully sequenced most globin and linker cDNAs. The primary structure features of these polypeptides have been characterized by comparison with model globin and linker sequences.

The evolution of extracellular hemoglobins of annelids, vestimentiferans, and pogonophorans.

The evolution of extracellular hemoglobins of annelids, vestimentiferans, and pogonophorans was investigated by applying cladistic and distance-based approaches to reconstruct the phylogenetic relationships of this group of respiratory pigments. We performed this study using the aligned sequences of globin and linker chains that are the constituents of these complex molecules. Three novel globin and two novel linker chains of Sabella spallanzanii described in an accompanying paper (Pallavicini, A., Negrisolo, E., Barbato, R., Dewilde, S., Ghiretti-Magaldi, A., Moens, L., and Lanfranchi, G. (2001) J. Biol. Chem. 276, 26384--26390) were also included. Our results allowed us to test previous hypotheses on the evolutionary pathways of these proteins and to formulate a new most parsimonious model of molecular evolution. According to this novel model, the genes coding for the polypeptides forming these composite molecules were already present in the common ancestor of annelids, vestimentiferans, and pogonophorans.

TUBA8: A new tissue-specific isoform of alpha-tubulin that is highly conserved in human and mouse.

We have cloned and sequenced a cDNA from a human adult skeletal muscle cDNA library, encoding for a novel isoform of alpha-tubulin (tuba8) that is preferentially expressed in heart, skeletal muscle, and testis. A genomic DNA sequence from the chromosomal region 22q11 allowed us to determine the complete structure of the TUBA8 gene that mirrors the canonical exon/intron organization of the vertebrate alpha-tubulin genes. We also cloned and sequenced the cDNA of its murine homologue (MMU-TUBA8). The latter encodes for a protein that differs from its human counterpart in only three amino acids, revealing an extreme rate of conservation that is even extended to both the 3' and 5' UTRs of the mRNAs. Sequence comparison of these novel isoforms with other known alpha tubulins shows that tuba8 is the most divergent member of the mammalian alpha-tubulin family. The sequence peculiarity of the human and murine tuba8 strongly suggests that they might have functional significance and, according to the multi-tubulin hypothesis, that they might play specific functional roles in the cell cytoskeleton.