Mechanism of activation of acyl-CoA substrates by medium chain acyl-CoA dehydrogenase: interaction of the thioester carbonyl with the flavin adenine dinucleotide ribityl side chain

Abstract

The flavin adenine dinucleotide (FAD) cofactor of pig kidney medium-chain specific acyl-coenzyme A (CoA) dehydrogenase (MCADH) has been replaced by ribityl-3'-deoxy-FAD and ribityl-2'-deoxy-FAD. 3'-Deoxy-FAD-MCADH has properties very similar to those of native MCADH, indicating that the FAD-ribityl side-chain 3'-OH group does not play any particular role in cofactor binding or catalysis. 2'-Deoxy-FAD-MCADH was characterized using the natural substrate C8CoA as well as various substrate and transition-state analogues. Substrate dehydrogenation in 2'-deoxy-FAD-MCADH is approximately 1.5 x 10(7)-fold slower than that of native MCADH, indicating that disruption of the hydrogen bond between 2'-OH and substrate thioester carbonyl leads to a substantial transition-state destabilization equivalent to approximately 38 kJ mol-1. The alphaC-H microscopic pKa of the substrate analogue 3S-C8CoA, which undergoes alpha-deprotonation on binding to MCADH, is lowered from approximately 16 in the free state to approximately 11 (+/-0.5) when bound to 2'-deoxy-FAD-MCADH. This compares with a decrease of the same pKa to approximately 5 in the complex with unmodified hwtMCADH, which corresponds to a pK shift of approximately 11 pK units, i.e., approximately 65 kJ mol-1 [Vock, P., Engst, S., Eder, M., and Ghisla, S. (1998) Biochemistry 37, 1848-1860]. The difference of this effect of approximately 6 pK units ( approximately 35 kJ mol-1) between MCADH and 2'-deoxy-FAD-MCADH is taken as the level of stabilization of the substrate carbanionic species caused by the interaction with the FAD-2'-OH. This energetic parameter derived from the kinetic experiments (stabilization of transition state) is in agreement with those obtained from static experiments (lowering of alphaC-H microscopic pKa of analogue, i.e., stabilization of anionic transition-state analogue). The contributions of the two single H-bonds involved in substrate activation (Glu376amide-N-H and ribityl-2'-OH) thus appear to behave additively toward the total effect. The crystal structures of native pMCADH and of 2'-deoxy-FAD-MCADH complexed with octanoyl-CoA/octenoyl-CoA show unambiguously that the FAD cofactor and the substrate/product bind in an identical fashion, implying that the observed effects are mainly due to (the absence of) the FAD-ribityl-2'-OH hydrogen bond. The large energy associated with the 2'-OH hydrogen bond interaction is interpreted as resulting from the changes in charge and the increased hydrophobicity induced by binding of lipophilic substrate. This is the first example demonstrating the direct involvement of a flavin cofactor side chain in catalysis.