Kinetic and structural properties of NADP-malic enzyme from sugarcane leaves

Abstract

Oligomeric structure and kinetic properties of NADP-malic enzyme, purified from sugarcane (Saccharam officinarum L.) leaves, were determined at either pH 7.0 and 8.0. Size exclusion chromatography showed the existence of an equilibrium between the dimeric and the tetrameric forms. At pH 7.0 the enzyme was found preferentially as a 125 kilodalton homodimer, whereas the tetramer was the major form found at pH 8.0. Although free forms of L-malate, NADP+, and Mg2+ were determined as the true substrates and cofactors for the enzyme at the two conditions, the kinetic properties of the malic enzyme were quite different depending on pH. Higher affinity for L-malate (Km = 58 micromolar), but also inhibition by high substrate (Ki = 4.95 millimolar) were observed at pH 7.0. L-Malate saturation isotherms at pH 8.0 followed hyperbolic kinetics (Km = 120 micromolar). At both pH conditions, activity response to NADP+ exhibited Michaelis-Menten behavior with Km values of 7.1 and 4.6 micromolar at pH 7.0 and 8.0, respectively. Negative cooperativity detected in the binding of Mg2+ suggested the presence of at least two Mg2+-binding sites with different affinity. The Ka values for Mg2+ obtained at pH 7.0 (9 and 750 micromolar) were significantly higher than those calculated at pH 8.0 (1 and 84 micromolar). The results suggest that changes in pH and Mg2+ levels could be important for the physiological regulation of NADP-malic enzyme.