Limits of the thermal tolerance of two lentic crustaceans: The role of lactate dehydrogenase.

Abstract

Limits of thermal tolerance in animal life is dependent on energy supply. Accordingly, the lowered ATP production capacity in ectotherms at high temperatures, which arises from a mismatch between oxygen supply and demand and the consequent switch from aerobic to anaerobic metabolism, affects the thermal resistance of these animals. The anaerobic ATP production capacity depends on the functional properties of the enzymes that reduce pyruvate. Thus, the present study focused on the role of the lactate dehydrogenase (LDH) of two daphnid species for anaerobic energy production at warm temperatures and the implications for their specific heat tolerances. Daphnia magna showed a higher thermal limit (indicated by immobilization time at 37°C) than Daphnia pulex, and in both species, this limit increased with rising acclimation temperature. In contrast to D. pulex, D. magna accumulated significant amounts of lactate at higher ambient temperatures. The intensity of anaerobic metabolism was also affected by acclimation temperature. Studying the functional enzyme properties revealed altered maximal reaction rates and substrate inhibitions of the LDH suites of the two daphnid species. D. magna LDH showed a significantly lower substrate inhibition than D. pulex LDH. The LDH isoform composition and the temperature-induced changes differed between both species. The detected qualitative modulations of the LDH suites may have resulted from differential isoform expression and different maturation processes. The species-specific LDH characteristics imply a higher anaerobic energy production at warm temperatures in D. magna, which likely contributes to the higher heat tolerance of this species.