The effects of experimental temperature increase on gametogenesis and heat stress parameters in oysters: Comparison of a temperate-introduced species (Crassostrea gigas) and a native tropical species (Crassostrea corteziensis)

The effect of thermal stress during reproduction was experimentally evaluated in the oyster Crassostrea gigas, a temperate species, and in the tropical oyster Crassostrea corteziensis. The temperature was gradually increased (1 °C day−1) from 20 °C to 34 °C for two weeks. As expected, C. gigas was the species most affected by heat stress, with the highest mortality rate (P < 0.05) starting at 28 °C, while mortality in C. corteziensis was significant only at 34 °C. The reproductive effort at higher temperatures was reflected in C. gigas as the highest index of mature oocytes and the largest rate of atresic and degenerated oocytes. C. corteziensis showed significant increases in the proliferation of early-developing oocytes at maximum temperatures. Lipid peroxidation and lipofuscin accumulation significantly increased in both species at maximum temperatures, with levels in C. gigas being 8-fold higher than in C. corteziensis. A significant loss of biomass and glycogen reserves stored in gonads was found in C. gigas at 34 °C. The mRNA signal of Hsp70 was detected in gonadic tissues from both oysters after thermal stress for in situ hybridization (ISH), with a temperature increase in both species; the cover area of Hsp70 was significantly higher in C. gigas during the experiment. Hemocyte infiltration significantly increased with increasing temperature in both oyster species, and apoptosis was strongly correlated with Hsp70 in both species (r = 0.93; P < 0.05). These results could explain the high tolerance that C. corteziensis has to thermal stress compared to C. gigas and could be used to adapt aquaculture strategies to the use of native species in subtropical climates to reduce summer mortality events

The effect of predator exposure and reproduction on oxidative stress parameters in the Catarina scallop, Argopecten ventricosus

Predation is known to impact growth and reproduction, and the physiological state of the prey, including its susceptibility to oxidative stress. In this study, we investigated how prolonged exposure to predators modulates tissue specific antioxidant defense and oxidative damage in the short-lived epibenthic scallop Argopecten ventricosus (2 years maximum lifespan). Scallops that were experimentally exposed to predators had not only lower antioxidant capacities (superoxide dismutase and catalase), but also lower oxidative damage (protein carbonyls and TBARS = thiobarbituric acid reactive substances including lipid peroxides) in gills and mantle compared to individuals not exposed to predators. In contrast, oxidative damage in the swimming muscle was higher in predator-exposed scallops. When predator-exposed scallops were on the verge of spawning, levels of oxidative damage increased in gills and mantle in spite of a parallel increase in antioxidant defense in both tissues. Levels of oxidative damage increased also in the swimming muscle whereas muscle antioxidant capacities decreased. Interestingly, post-spawned scallops restored antioxidant capacities and oxidative damage to immature levels, suggesting they can recover from spawning-related oxidative stress. Our results show that predator exposure and gametogenesis modulate oxidative damage in a tissue specific manner and that high antioxidant capacities do not necessarily coincide with low oxidative damage