Abstract
Malic enzyme (ME) is a family of enzymes that catalyze a reversible oxidative decarboxylation of l-malate to pyruvate with simultaneous reduction of NAD(P)(+) to NAD(P)H. According to the cofactor specificity, the mammalian enzyme can be categorized into three isoforms. The cytosolic (c) and mitochondrial (m) NADP(+)-dependent MEs utilize NADP(+) as the cofactor. The mitochondrial NAD(P)(+)-dependent ME can use either NAD(+) or NADP(+) as the cofactor. In addition, the m-NAD(P)-ME isoform can be inhibited by ATP and allosterically activated by fumarate. In this study, we delineated the determinants for cofactor specificity and isoform-specific inhibition among the ME isoforms. Our data strongly suggest that residue 362 is the decisive factor determining cofactor preference. All the mutants containing Q362K (Q362K, K346S/Q362K, Y347K/Q362K, and K346S/Y347K/Q362K) have a larger k(cat,NADP) value compared with the k(cat,NAD) value, indicating that the enzyme has changed to use NADP(+) as the preferred cofactor. Furthermore, we suggest that Lys-346 in m-NAD(P)-ME is crucial for the isoform-specific ATP inhibition. The enzymes containing the K346S mutation (K346S, K346S/Y347K, K346S/Q362K, and K346S/Y347K/Q362K) are much less inhibited by ATP and have a larger K(i,ATP) value. Kinetic analysis also suggests that residue 347 functions in cofactor specificity. Here we demonstrate that the human K346S/Y347K/Q362K m-NAD(P)-ME has completely shifted its cofactor preference to become an NADP(+)-specific ME. In the triple mutant, Lys-362, Lys-347, and Ser-346 work together and function synergistically to increase the binding affinity for NADP(+).
Highlights
Enzyme family became available, malic enzyme has been characterized as a new family, distinct from other oxidative decarboxylases [5,6,7,8,9]
ATP can bind at the exo site, site-directed mutagenesis and kinetic studies suggest that ATP is an active-site inhibitor rather than an allosteric inhibitor for the human m-NAD(P)-Malic enzyme (ME) [29, 30]
Kinetic Properties of Recombinant Human m-NAD(P)-ME and c-NADP-ME—Kinetic parameters of human malic enzymes utilizing NADϩ or NADPϩ as the cofactor were determined in the absence and presence of fumarate (Table 1)
Summary
We focused on exploring the contribution of these residues to the cofactor specificity of human m-NAD(P)ME. Site-directed mutagenesis was used in the combination of mutations for the three amino acid residues. The respective amino acid residue in human m-NAD(P)-ME was changed to that in human c-NADP-ME. According to the kinetic analysis, we have successfully demonstrated a mutant human mNAD(P)-ME, which has completely changed to become an NADPϩ-specific and ATP-resistant malic enzyme, just like a c-NADP-ME
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