Studies of Glutamate Dehydrogenase. Regulation of Glutamate Dehydrogenase from Candida utilis by a pH and Temperature‐Dependent Conformational Transition

Abstract

Glutamate dehydrogenase from C. utilis undergoes a reversible conformational transition between an active and an inactive state at low pH and low temperature. This conformational transition can be followed by fluorescence measurements. The temperature-dependent equilibrium between the active and the inactive state is characterized by a transition temperature of 10.7.degree. C and a .DELTA.H [enthalpy] value of 148 kcal/mol (620 kJ/mol.) The temperature dependence of the enzymic activity above 15.degree. C yields an activation energy of 15 kcal/mol (63 kJ/mol), a larger value than that for the beef liver enzyme (9 kcal/mol; 38 kJ/mol). In contrast to the yeast enzyme the Arrhenius plot is linear; therefore, the beef liver enzyme is not transformed into an inactive conformation at low temperatures. Sedimentation analysis shows that the inactivation of the C. utilis enzyme is not caused by change in the quaternary structure. The pH dependence of the conformational transition at low pH measured by fluorescence change is characterized by a pK value of 7.01 for the enzyme in the absence and of 6.89 for the enzyme in the presence of 2-oxoglutarate with a Hill coefficient of 3.4 in both cases. Similar results are found when the pH dependence of the enzymic activity is analyzed. With the beef liver enzyme the same pK value is obtained but with a Hill coefficient of 1 indicating cooperativity only in the case of the Candida utilis enzyme. The best fit of the pH dependence of the rate constants of the fluorescence changes was obtained with pK values of 7.45 and 6.45 for the active and the inactive state, respectively. In this model the lowest time constant which is obtained at the pH of the equilibrium was found to be 0.05 s-1. Preincubation experiments with the substrate 2-oxoglutarate but not with the coenzyme shift the equilibrium to the active conformation. The coenzyme obviously reduces the rate constant of the conformational transition. The sedimentation coefficient .**GRAPHIC**. and the mw were found to be 11.0 S and 276000, respectively. The enzyme molecule is built up by 6 polypeptide chains each having a mw of 470,00.