Cloning and characterization of neoplasia-related genes in flat oyster Ostrea edulis.

Bonamiosis and disseminated neoplasia (DN) are the most important diseases affecting cultured flat oysters Ostrea edulis in Galicia (NW Spain). Previous research using suppresive substraction hybridisation that had been performed addressing the molecular basis of DN as well as the induction and development of the disease in oysters, yielded the whole open reading frame of nine genes: XBP-1, RACK, NDPk, C1qTNF, RPA3, SAP18, p23, ubiquitin and ferritin. These nine genes were characterized in this study. The phylogenetic relationships for each gene were studied using minimum-evolution methods. Quantitative-PCR assays were also developed to analyse the modulation of the expression of these genes by bonamiosis and disseminated neoplasia. Gene expression profiles were studied in haemolymph cells and in various organs (gill, gonad, mantle and digestive gland) of oysters affected by bonamiosis, disseminated neoplasia, both diseases and in non-affected oysters (control). The expression of XBP-1, NDPk, RPA3, SAP18 and ferritin increased in haemolymph cells of oysters with heavy bonamiosis. The expression of C1qTNF; SAP18 and p23 increased in haemolymph cells of oysters with DN. The expression of XBP-1, RACK, NDPk, RPA3 and p23 significantly increased in haemolymph cells of oysters affected by both diseases. There were changes in the expression of a number of genes in different organs depeding on disease stage: RACK expression increased in gills of oysters with bonamiosis, XBP-1 increased in mantle and digestive organs of oysters with light DN and RPA3 expression increased in gonads of oysters with heavy bonamiosis and heavy neoplasia.

Molecular characterisation of TNF, AIF, dermatopontin and VAMP genes of the flat oyster Ostrea edulis and analysis of their modulation by diseases.

Bonamiosis and disseminated neoplasia (DN) are the most important diseases affecting cultured flat oysters (Ostrea edulis) in Galicia (NW Spain). Previous research of the response of O. edulis against bonamiosis by suppression subtractive hybridisation yielded a partial expressed sequence tag of tumour necrosis factor (TNF) and allograft inflammatory factor (AIF), as well as the whole open reading frame for dermatopontin and vesicle-associated membrane (VAMP). Herein, the complete open reading frames of TNF and AIF genes were determined by the rapid amplification of cDNA, and the deduced amino acid sequences of the four genes were characterised. Phylogenetic relationships for each gene were studied using maximum likelihood parameters. Quantitative-PCR assays were also performed in order to analyse the modulation of the expression of these genes by bonamiosis and disseminated neoplasia. Gene expression profiles were studied in haemolymph cells and in various organs (gill, gonad, mantle and digestive gland) of oysters affected by bonamiosis, DN, and both diseases with regard to non-affected oysters (control). TNF expression in haemolymph cells was up-regulated at heavy stage of bonamiosis but its expression was not affected by DN. AIF expression was up-regulated at heavy stage of bonamiosis in haemolymph cells and mantle, which is associated with heavy inflammatory response, and in haemolymph cells of oysters affected by DN. AIF expression was, however, down-regulated in other organs as gills and gonads. Dermatopontin expression was down-regulated in haemolymph cells and digestive gland of oysters affected by bonamiosis, but DN had no significant effect on its expression. Gills and gonads showed up-regulation of dermatopontin expression associated with bonamiosis. There were significant differences in the expression of TNF and VAMP depending on the bonamiosis intensity stage whereas no significant differences were detected between light and heavy severity degrees of DN for the studied genes. VAMP expression showed also differences among haemolymph cells and the organs studied. The occurrence of both diseases in oysters involved haemolymph cell gene expression patterns different from those associated to each disease separately: no significant effect was observed in TNF expression, dermatopontin was up-regulated and marked up-regulation of AIF and VAMP was recorded, which suggests a multiplier effect of the combination of both diseases for the latter two genes.

New insights in flat oyster Ostrea edulis resistance against the parasite Bonamia ostreae.

Bonamiosis due to the parasite Bonamia ostreae has been associated with massive mortality in flat oyster stocks in Europe. Control of the disease currently relies on disease management practices and transfer restriction. Previously, massal selections based on survival to challenge to infection with B. ostreae have been applied to produce flat oyster families with resistant progeny. In an attempt to understand the molecular mechanisms involved in disease resistance, differentially expressed sequence tags between resistant and wild Ostrea edulis haemocytes, both infected with the parasite, were identified using suppression subtractive hybridisation. Expression of seven ESTs has been studied using quantitative reverse-transcriptase PCR. The base-line expression of an extracellular superoxide dismutase, inhibitor of apoptosis (OeIAP), Fas ligand (OeFas-ligand) and Cathepsin B was significantly increased, whilst cyclophilin B appeared significantly decreased in resistant oysters. Considering their great interest for further studies, the open reading frames of the OeFas-ligand and OeIAP were completely sequenced.

Cloning of cDNAs and hybridization analysis of lysozymes from two oyster species, Crassostrea gigas and Ostrea edulis.

In bivalve molluscs including oysters, lysozymes play an important role in the host defense mechanisms against invading microbes. However, it remains unclear in which sites/cells the lysozyme genes are expressed and which subsequently produced the enzyme. This study cloned lysozyme cDNAs from the digestive organs of Pacific oyster Crassostrea gigas and European flat oyster Ostrea edulis. Both complete sequences of two oysters' lysozymes were composed of 137 amino acids. Two translated proteins present a high content in cysteine residues. Phylogenetic analyses showed that these oysters' lysozymes clustered with the invertebrate-type lysozymes of other bivalve species. In the Pacific oyster, lysozyme mRNA was expressed in all tissues except for those of the adductor muscle. In situ hybridization analyses revealed that lysozyme mRNA was expressed strongly in basophil cells in the digestive gland tubule of C. gigas, but not in digestive cells. Results indicated that the basophil cells of the oyster digestive gland are the sites of lysozyme synthesis.