Characterisation and expression of the biomineralising gene Lustrin A during shell formation of the European abalone Haliotis tuberculata.

The molluscan shell is a remarkable product of a highly coordinated biomineralisation process, and is composed of calcium carbonate most commonly in the form of calcite or aragonite. The exceptional mechanical properties of this biomaterial are imparted by the embedded organic matrix which is secreted by the underlying mantle tissue. While many shell-matrix proteins have already been identified within adult molluscan shell, their presence and role in the early developmental stages of larval shell formation are not well understood. In the European abalone Haliotis tuberculata, the shell first forms in the early trochophore larva and develops into a mineralised protoconch in the veliger. Following metamorphosis, the juvenile shell rapidly changes as it becomes flattened and develops a more complex crystallographic profile including an external granular layer and an internal nacreous layer. Amongst the matrix proteins involved in abalone shell formation, Lustrin A is thought to participate in the formation of the nacreous layer. Here we have identified a partial cDNA coding for the Lustrin A gene in H. tuberculata and have analysed its spatial and temporal expression during abalone development. RT-PCR experiments indicate that Lustrin A is first expressed in juvenile (post-metamorphosis) stages, suggesting that Lustrin A is a component of the juvenile shell, but not of the larval shell. We also detect Lustrin A mRNAs in non-nacre forming cells at the distal-most edge of the juvenile mantle as well as in the nacre-forming region of the mantle. Lustrin A was also expressed in 7-day-old post-larvae, prior to the formation of nacre. These results suggest that Lustrin A plays multiple roles in the shell-forming process and further highlight the dynamic ontogenic nature of molluscan shell formation.

Cytotoxicity assessment of antibiofouling compounds and by-products in marine bivalve cell cultures.

Short-term primary cell cultures were derived from adult marine bivalve tissues: the heart of oyster Crassostrea gigas and the gill of clam Ruditapes decussatus. These cultures were used as experimental in vitro models to assess the acute cytotoxicity of an organic molluscicide, Mexel-432, used in antibiofouling treatments in industrial cooling water systems. A microplate cell viability assay, based on the enzymatic reduction of tetrazolium dye (MTT) in living bivalve cells, was adapted to test the cytotoxicity of this compound: in both in vitro models, toxicity thresholds of Mexel-432 were compared to those determined in vivo with classic acute toxicity tests. The clam gill cell model was also used to assess the cytotoxicity of by-products of chlorination, a major strategy of biofouling control in the marine environment. The applications and limits of these new in vitro models for monitoring aquatic pollutants were discussed, in reference with the standardized Microtox test.

Identification of media supplements that improve the viability of primarily cell cultures of Crassostrea gigas oysters.

Media supplements have been investigated for their influence on the viability of primary cell cultures from the heart of Crassostrea gigas oysters. Soluble factors of vertebrate origin were tested, belonging to five families of supplements that had proven to increase the viability of insect and mammal cell cultures. Using two-level complete factorial assays, factors and mutual interactions were screened within each family with a MTT reduction assay. Results pointed out the positive influence of hormones, growth factor, antioxidants and lipids on the mitochondrial metabolism of oyster's heart cells. Consequently, a new concentrated complex supplement was developed. At 10% (v/v) final concentration in modified Leibovitz L-15 medium, it increases by 30% the cellular viability of one-week old cultures as compared with non-supplemented medium, a similar improvement as the one obtained with 10% (v/v) fetal calf serum. Combined with fetal calf serum, this new supplement doubles the cellular viability of one-week old cultures and allows networks of cardiomuscular cells to be maintained functional over three months in vitro.