Yamama Naciri

A genetic and metabolic basis for faster growth among triploids induced by blocking meiosis I but not meiosis II in the larviparous European flat oyster, Ostrea edulis L.

This study establishes a genetic and metabolic basis to faster triploid growth in the oyster Ostrea edulis. Triploidy was induced using cytochalasin B, and image analysis of biopsied tissue employed to ensure similar ploidy of all animals within each class. Results indicate that lifetime growth in total dry tissue weight over 15 months was more than 60% faster (p<0.001) in meiosis I triploids than in diploid siblings or meiosis II triploids, with no difference between meiosis II triploids and their diploid siblings. For six polymorphic enzyme loci, single-locus heterozygosity was consistently greatest in meiosis I triploids (p<0.001), so that average multiple-locus heterozygosity in meiosis I triploids was 49% higher than in normal diploids, and 55% higher than in meiosis II triploids (p<0.001). This suggests that faster growth resulted from increased allelic diversity, rather than the increased allelic quantity that results from the addition of one entire set of chromosomes among triploids generally. Results also confirm that the faster growth of meiosis I triploids resulted from reduced energy expenditure, associated with lower concentrations of RNA per unit total tissue protein, which infer reduced rates of whole-body protein turnover. Statistical analyses confirmed that differences in oxygen consumption and growth were associated with both ploidy class and average multiple-locus heterozygosity, indicating that performance in meiosis I triploids is not only improved as a result of reduced reproductive output, but also through the metabolic consequences associated with increased heterozygosity.

A novel method to produce triploids in bivalve molluscs by the use of 6-dimethylaminopurine.

Abstract To date, pressure shock, heat shock, and chemical treatment with cytochalasin B have been the major methods used to induce triploid bivalves. In this study, triploid bivalves were induced by a new chemical treatment using 6-dimethylaminopurine (6-DMAP). The capacity of 6-DMAP to produce triploid eggs and larvae was investigated in the Pacific oyster, Crassostrea gigas , the giant sea scallop, Placopecten magellanicus , and the blue mussel, Mytilus edulis . The triploid yields from the 6-DMAP treatments were compared with those of cytochalasin treatments. The highest percentage of triploid production was 90% in the Pacific oysters when the fertilized eggs were treated for 20 min with 300 μM 6-DMAP at 15 min after fertilization and 95% in the giant scallops when treated for 15 min with 400 μM 6-DMAP at 70 min after fertilization. Increasing durations of 6-DMAP treatments improved the efficiency of triploid induction. However, long incubations with 6-DMAP, which overlapped the period of first mitotic cleavage, led to the development of abnormal larvae. These included low percentages of normal veliger larvae in the Pacific oysters and developmental arrest at the trochophore stage in the blue mussels. The percentage of abnormalities increased with increased treatment duration. Triploid larvae of Pacific oysters produced by 6-DMAP or cytochalasin treatments had equivalent growth rates and were similar to those of control diploid larvae. However, triploid larvae showed high mortalities following these two chemical treatments. Overall, the results clearly demonstrate that 6-DMAP was an efficient and practical inducer of triploidy in bivalve molluscs. Moreover, the described procedure is the most simple and reproducible method ever reported. In addition, 6-DMAP is safer to handle than cytochalasin which is classified as a carcinogen.