Euryhalinity of the estuarine copepod Pseudodiaptomus richardi and its high potential to be employed as live food in aquaculture

The use of copepods in aquaculture has been raising great interest in the last years, especially as live food for larviculture of marine/estuarine fish. The copepod Pseudodiaptomus richardi is a euryhaline species, extremely promising for culture in a vast array of salinities. The survival of P. richardi was thus here evaluated 24h after its abrupt transfer to higher salinities (15 and 30), from control salinity 5. Besides survival, body fluid osmolality and body hydration were also evaluated upon these same hyper-osmotic shocks, but after 5 and 30min, 1 and 24h. The whole body activity of the Na+/K+-ATPase was evaluated after 48h of acclimation to these same salinities. Adult copepods displayed 100% survival upon both hyper-osmotic shocks after 24h; copepodites and nauplii had some mortality in salinity 30 (16–22%). Body hydration decreased in both salinities (78 to 66–70%). In salinity 15 body hydration was maintained after 5min, and recovered after 24h. In the highest salinity (30) the hyper-osmotic shock induced immediate (5min) water loss, coherent with their loss of swimming activity, and there was no trend of recovery, even after 24h. The reduction in body hydration does not necessarily reflect volume reduction, but increases in dry mass, from salt uptake. Copepods transiently lose water when submitted to salinity 30, quickly showing a decrease in body hydration – given the strong outward osmotic gradient – but probably recover volume after intra-and extra-cellular solute (inorganic and organic) concentrations increase, and water uptake. This result is consistent with their recovery of normal swimming behavior after a few hours in salinity 30. Body fluid osmolality at all salinities was always ~200–300mOsm/kg H2O above water osmolality. Na+/K+-ATPase specific activity of adult copepods acclimated to the salinities of 5, 15, or 30 was stable, of ~2nmol ADP/μgprotein·h. P. richardi is thus a hyper-conformer which keeps a constant rate of salt uptake to remain hyper-osmotic at all salinities. In conclusion, it can be safely used as live food for fish larvae grown in salinities 5–30. In salinities approaching full-strength seawater, it shows a transient osmoregulatory disturbance when abruptly exposed, but it is fully able to acclimate, survive and reproduce even in these higher salinities.