On the interaction of tritiated 2-ketobutyrate with 2-keto-3-deoxygluconate-6P aldolase ofPseudomonas putida. Evidence suggesting enzyme-mediated,uncatalyzed tritium exchange

2-Keto-3-deoxygluconate-6P aldolase ofPseudomonas putida mediates exchange between hydrogen isotope at the methylene carbon of 2-ketobutyrate and water. This occurs with aK _m of 20 mM, 100 times the corresponding value for pyruvate, and a V_max approximating 1/710 that of KDPG cleavage. Ketobutyrate is competitive with both pyruvate and 2-keto-3-deoxygluconate-6P for the enzyme. In addition, there is no evidence for C-C synthesis between ketobutyrate andd-glyceraldehyde-3P. A comparison of relativeV/K values for hydrogen exchange shows pyruvate to be 17,600 times better as a substrate than ketobutyrate. The detritiation of 3-³H]ketobutyrate is stereochemically random. In addition, the reaction proceeds with ak _H/k _T isotope effect of 15.3, consistent with C-H bond turnover being rate-determining. The E-ketobutyrate complex is reductively trapped, inactivating the enzyme. Reductive inactivation kinetics of E-ketobutyrate compared to E-pyruvate suggests more of the complex may be partitioned to ketimine in the ketobutyrate case than in the pyruvate case. A mechanism is considered in which ketobutyrate is bound as a ketimine in an orientation such that the active site acid/basic group cannot mediate catalytic ketimine/eneamine interconversion. Thus, exchange would result from hydrogen ionization at C-3′ of the ketimine, a slow spontaneous step compared to overall complex turnover. This noncatalyzed deprotonation would explain dissymmetry in exchange, the poorV/K compared to pyruvate, and a large tritium isotope effect.