Some biological transformations involving unsaturated linkages: the importance of charge separation and charge neutralization in enzyme catalysis

Current status of knowledge on the biological reduction of CC and CO is briefly reviewed. It is Argued that the crucial event in the reduction of CC is the addition of a proton to the more electron-rich terminal of the double bond to produce an electron-deficient species which is then neutralized through hydride transfer from NADPH. The activation for the reduction of a CO group may also be achieved by a related process in which the carbonyl oxygen is polarized by H-bonding to an acidic group on the enzyme, prior to hydride transfer from NAD(P)H.Thus with both these systems an early event in catalysis is the protonation of the substrate for which, normally, strong adds win be required. Since the groups available at the active-met of enzymes are weak acids, a mechanism through which powerful proton donating species could be transiently generated from them is proposed. The salient features of this mechanism may be enuinciatcd as follows: Let us consider the enzyme-substrate complex (A) in which an imidazolium group is about to play a role as a proton donating species. It is argued that rearrngement of initial complex(A)to the catalytic-complex(B), in which the negatively chared counter ion is removed away from the imidazolium cation, would transiently convert the latter group into a powerful proton danating species. the rearrangement (A)→(B) could occur through a protein conformational change or via a charge-relay system or a combination of both processes.