Identification of a tyrosinase gene potentially involved in early larval shell biogenesis of the Pacific oyster Crassostrea gigas

The larval shell emerges early in embryogenesis of mollusks, but the detailed mechanisms of its biogenesis remain to be determined. In this study, we cloned a tyrosinase gene (cgi-tyr1) that potentially functioned in larval shell biogenesis from the Pacific oyster Crassostrea gigas, a worldwide bivalve species. Sequence analysis of cgi-tyr1 revealed that it had typical copper-binding domains and a signal peptide. Through whole mount in situ hybridization and an electron scanning microscopic observation, we detected the expression of cgi-tyr1 firstly in the saddle-shaped shell field in trochophores, indicating that cgi-tyr1 might participate in the biogenesis of the initial non-calcified shell of trochophores. In the following development to early D-veliger, cells in the central region of shell field exhibited no detectable cgi-tyr1 expression, and cgi-tyr1 expression was sustained only in the edge of the shell field and the hinge region, indicating that cgi-tyr1 might function fundamentally in shell growth from trochophore to early D-veliger. Unexpectedly, cgi-tyr1 expression was not detected after the D-veliger stage. This indicated that other molecules might function in later shell development. Our results suggested a role for a tyrosinase gene that specifically functioned in the initial phase of the larval shell biogenesis of C. gigas. This work would shed light on future studies on larval shell development and might be helpful to understand how the molluscan shell emerged during evolution.     

High genetic load in the Pacific oyster Crassostrea gigas

The causes of inbreeding depression and the converse phenomenon of heterosis or hybrid vigor remain poorly understood despite their scientific and agricultural importance. In bivalve molluscs, related phenomena, marker-associated heterosis and distortion of marker segregation ratios, have been widely reported over the past 25 years. A large load of deleterious recessive mutations could explain both phenomena, according to the dominance hypothesis of heterosis. Using inbred lines derived from a natural population of Pacific oysters and classical crossbreeding experiments, we compare the segregation ratios of microsatellite DNA markers at 6 hr and 2-3 months postfertilization in F(2) or F(3) hybrid families. We find evidence for strong and widespread selection against identical-by-descent marker homozygotes. The marker segregation data, when fit to models of selection against linked deleterious recessive mutations and extrapolated to the whole genome, suggest that the wild founders of inbred lines carried a minimum of 8-14 highly deleterious recessive mutations. This evidence for a high genetic load strongly supports the dominance theory of heterosis and inbreeding depression and establishes the oyster as an animal model for understanding the genetic and physiological causes of these economically important phenomena.     

Characterization of genes involved in ceramide metabolism in the Pacific oyster (Crassostrea gigas)

ABSTRACT: BACKGROUND: The lipid signaling molecule, ceramide, is a key component of the vertebrate stress response, however, there is limited information concerning its role in invertebrate species. In order to identify genes involved in ceramide metabolism in bivalve molluscs, Pacific oyster genomic resources were examined for genes associated with ceramide metabolism and signaling. RESULTS: Several genes were identified including full-length sequences characterized for serine palmitoyltransferase-1, 3-ketodihydrosphingosine reductase, acid ceramidase, and ceramide glucosyltransferase. Genes involved in ceramide synthesis and metabolism are conserved across taxa in both form and function. Expression analysis as assessed by quantitative PCR indicated all genes were expressed at high levels in gill tissue. The role of the ceramide pathway genes in the invertebrate stress response was also explored by measuring expression levels in adult oysters exposed to Vibrio vulnificus. Two genes demonstrated increased expression during the bacterial challenge: a gene involved in hydrolytic breakdown of ceramide (acid ceramidase) and a gene involved in de novo generation of ceramide (3-ketodihydrosphingosine reductase), suggesting a possible role of ceramide in the invertebrate stress and immune responses. CONCLUSIONS: In silico and laboratory results support that Pacific oysters have the basic components of the ceramide metabolism pathway. These results also indicate that ceramide may have analogous functions in vertebrates and invertebrates. The gene expression pattern of acid ceramidase and 3-kethodihydrosphingosine reductase in response to bacterial exposure especially supports that ceramide and sphingolipid metabolism may be involved in the oyster's stress and/or immune responses.     

Infectious diseases of the Pacific oyster,Crassostrea gigas

The Pacific oyster, Crassostrea gigas, is known for not having been affected by major epizootics of infectious diseases, unlike many other commercially important oysters worldwide. Nonetheless, review of the scientific literature reveals more than ten infectious diseases of this species including those with viral, bacterial, protozoan, and metazoan etiologies. These include diseases of larval, juvenile, and adult oysters. Diseases such as oyster velar virus disease, herpes-like infection, and ligament disease are known because of their importance in intensive husbandry systems of this bivalve. Nocardiosis, Marteilioides infection, haplosporidiosis, Denman Island disease, and others are primarily known from their effect on extensively cultured populations of the Pacific oyster. These diseases are reviewed in terms of their disease manifestations, etilogy, epizootiology and economic importance, prevention, and management and diagnosis.     

Haplosporidiosis of the Pacific oyster, Crassostrea gigas.

Haplosporidan parasites were observed in 10/100 spat and 1/171 adult Pacific oysters, Crassostrea gigas, reared in Matsushima Bay, Japan. Eight of the infected spat contained mild to severe plasmodial infections. The multinucleated plasmodia were 6-12 microm x 7-15 microm and were associated with an infiltration of hemocytes that occurred throughout the vesicular connective tissues of all infected oysters. Two oysters, one adult and one spat, contained advanced sporogonic infections. These were characterized by the presence of sporocysts and immature and mature operculated spores that measured 5.6-6.0 microm x 6.0-8.0 microm and were found exclusively within the digestive tubule epithelium. Electron microscopic examination revealed that mature spores contained a hinge operculum, striated and layered wall, spherule, single nucleus, and haplosporosome formative regions. Parasite morphology and infection pattern closely resemble that of Haplosporidium nelsoni, a pathogen of American oysters (C. virginica).     

A tolloid homologue from the Pacific oyster Crassostrea gigas

The genes governing mesoderm specification have been extensively studied in vertebrates, arthropods and nematodes. The latter two phyla belong to the Ecdysozoan clade but little is understood of the role that these genes might play in the development of the other major protostomal clade, the Lophotrochozoa. As part of a wider project to analyze the functions associated with transforming growth factor beta superfamily members in Lophotrochozoa, we have cloned a gene encoding a tolloid homologue from the bivalve mollusc Crassostrea gigas. Tolloid is a key developmental protein that regulates the activity of bone morphogenetic proteins (BMPs). We have determined the intron-exon structure of the gene encoding C. gigas tolloid and have compared it with those of homologous genes from both protostomes and deuterostomes. In order to analyze the functionality of oyster tolloid the zebrafish embryo has been employed as a reporter organism and we show that over-expression of this protein results in the ventralization of zebrafish embryos at 24h post fertilization. The expression of the C. gigas tolloid gene during embryonic and larval development as well as in adult tissues is also explored.     

Reproductive patterns of the Pacific oyster Crassostrea gigas in France

Summary

In France, national management programs focus research on understanding reproductive factors in Crassostrea gigas to confront problems of the oyster industry. However, little information has been documented in which reproductive patterns include sexual changes. The reproductive cycle of oysters at three sites of the Atlantic coast of France was examined from 1996 to 1998, and the seasonal variations in oocyte size-frequencies, and sex ratio were described. The results showed a synchronism within the population concerning reproductive behavior. Young oocytes are generated after spawning and show no apparent changes during winter. Growth of oocytes begins in spring and cells reach maturity in April-May and are ready for a single spawning season in June-July. Oocytes that were not released during spawning are reabsorbed within the gonad. The significant difference between sites is that spawning occurred 1 month later in the southern area. A modal analysis showed that oocyte populations in the sample individuals are primordially bimodal, but with polymodal occurrences in June-July, in some cases. Irregular alternative sexuality was detected at all sites, and hermaphrodites appear to be a transition phase that allows changes from male to female during early spring. Previous observations, together with the study of the development of oocyte cohorts over time, permit a hypothetical model concerning the kinetics of gametogenesis in C. gigas. The model suggests that primary oocytes are generated from energy supplied from degenerating, as well as young oocytes that do not reach the mature stage within the gonad during autumn-winter. It seems that, during vitellogenesis, there is disintegration of smaller cells coupled with transfer of energy to the larger oocytes, which continue to grow and mature.     

Identification of candidate AFLP markers for shell color of the Pacific oyster (Crassostrea gigas) under artificial selection

The shell color of the Pacific oyster (Crassostrea gigas) is a desirable trait, but only a few genetic studies on shell color have been documented. Through successive selective breeding, four shell color variants of white (W), gold (G), black (B) and purple (P) C. gigas have been developed. The amplified fragment length polymorphism (AFLP) technique was used to scan the genomes of the four variants with different shell colors and one wild population (C) to identify candidate markers for shell polymorphism. Fifteen AFLP primer combinations were used, 1079 loci were scored as polymorphic loci, and the percentage of polymorphic bands was 95.5%. In the gold, white, black, purple and wild populations, the percentages of polymorphic loci were estimated to be 90.5% (G), 90.0% (W), 91.1% (B), 95.3% (P) and 93.2% (C); the expected heterozygosity values were 0.3115 (G), 0.3044 (W), 0.3102 (B), 0.3285 (P) and 0.3105 (C). The white shell variant was observed to have slightly lower genetic diversity than others, with a F_ST value of 0.1483. These results indicated that the four different shell color variants had high genetic diversity and that the genetic differentiation of populations mostly results from genetic diversity of individuals within populations. Furthermore, 11 outlier loci were considered candidate markers for shell color. This work provides new insights on relationships among color variants of C. gigas.     

Chromosome inheritance in triploid Pacific oyster Crassostrea gigas Thunberg

Reproduction and chromosome inheritance in triploid Pacific oyster (Crassostrea gigas Thunberg) were studied in diploid female x triploid male (DT) and reciprocal (TD) crosses. Relative fecundity of triploid females was 13.4% of normal diploids. Cumulative survival from fertilized eggs to spat stage was 0.007% for DT crosses and 0.314% for TD crosses. Chromosome number analysis was conducted on surviving progeny from DT and TD crosses at 1 and 4 years of age. At Year 1, oysters from DT crosses consisted of 15% diploids (2n=20) and 85% aneuploids. In contrast, oysters from TD crosses consisted of 57.2% diploids, 30.9% triploids (3n=30) and only 11.9% aneuploids, suggesting that triploid females produced more euploid gametes and viable progeny than triploid males. Viable aneuploid chromosome numbers included 2n+1, 2n+2, 2n+3, 3n-2 and 3n-1. There was little change over time in the overall frequency of diploids, triploids and aneuploids. Among aneuploids, oysters with 2n+3 and 3n-2 chromosomes were observed at Year 1, but absent at Year 4. Triploid progeny were significantly larger than diploids by 79% in whole body weight and 98% in meat weight at 4 years of age. Aneuploids were significantly smaller than normal diploids. This study suggests that triploid Pacific oyster is not completely sterile and cannot offer complete containment of cultured populations.     

Xenobiotic biotransformation in the Pacific oyster (Crassostrea gigas)

1. Oyster visceral mass and gill tissues possessed measurable flavin-containing monooxygenase (FMO) activity. 2. FMO activity was confirmed in visceral mass microsomes by oxygen uptake experiments utilizing various nitrogen and sulfur-containing chemicals along with measurement of N,N-dimethylaniline (DMA) N-oxidase and methimazole oxidation activities. DMA N-oxidase and methimazole oxidation activities also were present in gill microsomes. 3. Excluding oyster gill methimazole oxidation, there were no consistent seasonal differences in FMO activity in oyster gill or visceral mass microsomes. 4. Although lacking spectral evidence for cytochrome P-450, a peak at 418 nm was observed along with NADPH-cytochrome c reductase activity in visceral mass and gill microsomes suggesting the presence of a denatured cytochrome P-450 system. 5. NADPH-independent benzo(a)pyrene hydroxylase (BPH) activity was observed in both oyster visceral mass and gill microsomes suggesting a co-oxidation pathway possibly involving a one electron transfer of oxygen from a lipid hydroperoxide.     

Distribution of multiple peptidoglycan recognition proteins in the tissues of Pacific oyster, Crassostrea gigas

Peptidoglycan recognition proteins (PGRPs) are pattern recognition receptors that specifically bind to peptidoglycans, a major component of bacterial cell wall. Generally, PGRPs are responsible for recognition of bacterial invasion in invertebrates. Full length cDNAs of PGRP, designated as CgPGRP-S1S, -S1L, -S2 and -S3, were identified from the Pacific oyster, Crassostrea gigas. Homology and domain searches classified these CgPGRPs as short-type PGRPs for extracellular PGN recognition. Amidase activity was predicted in all CgPGRPs, and defensin-like domains were found in CgPGRP-S1S and -S1L, suggesting that they may also function as antimicrobial proteins. Although phylogenetic analysis indicated that CgPGRPs are closely related to each other, they showed different tissue expression patterns; CgPGRP-S1S in the mantle and the gill, -S1L in the mantle, -S2 in the hemocytes and -S3 in the digestive diverticula. The CgPGRPs seem to survey bacterial invasion in their corresponding expression tissues. This is the first report of the possibility that bivalve mollusks have PGN recognition systems as suggested by the identification of multiple PGRPs distributed in various tissues.     

First evidence of laccase activity in the Pacific oyster Crassostrea gigas

Phenoloxidases (POs) are a family of enzymes including tyrosinases, catecholases and laccases, which play an important role in immune defence mechanisms in various invertebrates. The aim of this study was to thoroughly identify the PO-like activity present in the hemolymph of the Pacific oyster Crassostrea gigas, by using different substrates (i.e. dopamine and p-phenylenediamine, PPD) and different PO inhibitors. In order to go deeper in this analysis, we considered separately plasma and hemocyte lysate supernatant (HLS). In crude plasma, oxygraphic assays confirmed the presence of true oxidase activities. Moreover, the involvement of peroxidase(s) was excluded. In contrast to other molluscs, no tyrosinase-like activity was detected. With dopamine as substrate, PO-like activity was inhibited by the PO inhibitors tropolone, phenylthiourea (PTU), salicylhydroxamic acid and diethyldithio-carbamic acid, by a specific inhibitor of tyrosinases and catecholases, i.e. 4-hexylresorcinol (4-HR), and by a specific inhibitor of laccases, i.e. cetyltrimethylammonium bromide (CTAB). With PPD as substrate, PO-like activity was inhibited by PTU and CTAB. In precipitated protein fractions from plasma, and with dopamine and PPD as substrates, PTU and 4-HR, and PTU and CTAB inhibited PO-like activity, respectively. In precipitated protein fractions from hemocyte lysate supernatant, PTU and CTAB inhibited PO-like activity, independently of the substrate. Taken together, these results suggest the presence of both catecholase- and laccase-like activities in plasma, and the presence of a laccase-like activity in HLS. To the best of our knowledge, this is the first time that a laccase-like activity is identified in a mollusc by using specific substrates and inhibitors for laccase, opening new perspectives for studying the implication of this enzyme in immune defence mechanisms of molluscs of high economic value such as C. gigas.     

Assessment of female gamete quality in the Pacific oyster Crassostrea gigas

Summary

The possible relationship between certain oocyte and embryo characteristics and larvae viability was investigated with reference to the following aspects: (1) morphological—oocyte diameter and shape; (2) cytological—overall ultrastructure and membrane integrity; (3) biochemical—content of lipids, proteins and carbohydrates; and (4) physiological—respiration. The rate of survival and incidence of abnormality were estimated 24 h after fertilization. The first results showed that 80–90% of oocytes were cytologically viable before fertilization. Eighty to 90% of oocytes are apparently viable before fertilization on the basis of staining with Trypan blue, but this parameter shows little correlation with larval viability. However, Trypan blue staining is of value in allowing the recognition of oocytes with damaged membranes. Respiration was measured for unfertilized oocytes 5 min after stripping, after 6 h, and for 3-h embryos. Positive correlations were found between the O₂-consumption of embryos and both the rate of fertilization and the hatching rate of 24-h larvae. In contrast, no correlation was found between hatching parameters and the O₂-consumption of unfertilized oocytes. These results suggest that embryos possess quality indicators, relating to metabolic characteristics, which can be quantified more easily than those of oocytes.