A dimeric form of Escherichia coli succinyl-CoA synthetase produced by site-directed mutagenesis.

Succinyl-CoA synthetase (SCS) catalyzes the substrate-level phosphorylation step of the citric acid cycle. The enzyme from Escherichia coli is an (alphabeta)2-heterotetramer with two active sites, one in each alphabeta-dimer. To determine whether the two active sites could function independently, mutations were made to split the tetramer into alphabeta-dimers. Because two choices for the tetramer (I and II) were possible from the X-ray crystallographic analyses, mutations were made at two different interfaces. All mutations based on tetramer I resulted in an intact tetramer. Of the two mutants based on tetramer II, one was insoluble and the other, where M156beta, Y158beta, R161beta and E162beta were changed to D, D, E and R, respectively, was a dimer. This quaternary structure was confirmed by fast protein liquid chromatography, blue native PAGE and ultracentrifugation. The DDER mutant has kinetic parameters similar to the tetrameric E. coli enzyme. Like the tetrameric enzyme, it shows ATP-facilitated dethiophosphorylation, proving that this property is a single-site effect. The ATP-facilitated dethiophosphorylation is inhibited by phosphate. It is concluded that dimerization of alphabeta-dimers is not a prerequisite for catalytic competency nor for alternating sites cooperativity in the tetramer. The rationale behind the dimer-of-dimers in E. coli SCS is still not known, but increased solubility, increased stability and in vivo interactions of the tetramer with other proteins are still possibilities.