Abstract
The properties of glucose-6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase from gill tissue of the tanner crab Chionocetes bairdi, and lactate dehydrogenase (LDH) and glyceraldehyde dehydrogenase from skeletal muscle of C. bairdi and the yellowfin sole Limanda aspera were examined over the physiological temperature range of the animals. Both animals were obtained in the Bering Sea in winter, and their enzymes appear to be remarkably cold-adapted. Affinity of sole LDH for substrate appears to increase with decreasing temperature, thus keeping reaction rate essentially independent of temperature at physiological concentrations of the substrate. Calculated values of activation energy are low, in keeping with the argument that organisms from cold environments have enzymes with a reduced energy of activation. In addition, Hill plots of the substrate saturation curves for lactate dehydrogenase from muscle of sole indicate that there is a facilitation of allosteric behaviour at low temperatures. Maximum affinity of sole LDH for substrate in the absence of univalent cations occurs at 3°C, while in the presence of 150 mN K+, it occurs between 0° to-2°C. The effects of Mg2+ on enzyme activity appear to be determined by concentration of substrate and temperature. Thus, glucose-6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase are stimulated more effectively by Mg2+ at low temperature and at low substrate levels whereas, at high concentrations of substrate, they are relatively independent of the bivalent cation. All four dehydrogenases are affected by the univalent cations Na+, K+ and NH4+ in a manner which appears to be determined, in part at least, by concentration of substrate and by temperature. These findings suggest mechanisms for the maintenance and regulation of enzyme activity in poikilothermic tissues at low and changing temperatures.
Published Version
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