Interaction of an Engineered [3Fe-4S] Cluster with a Menaquinol Binding Site of Escherichia coli DMSO Reductase

Abstract

We have characterized by EPR the interaction of the Em,7 = -50 mV [4Fe-4S] cluster of Escherichia coli DMSO reductase (DmsABC) with a menaquinol (MQH2) binding site. Potentiometric titrations indicate that in DmsAB(C102S)C, the Em,7 = -50 mV [4Fe-4S] cluster is replaced by an Em,7 = +260 mV [3Fe-4S] cluster. The Q-pool coupling assay in combination with the MQH2 analog HOQNO (2-n-heptyl-4-hydroxyquinoline-N-oxide) was used to examine the effect of the DmsB(Cl02S) mutation on physiological electron transfer through DmsABC. Forward electron transfer through the mutant (MQH2 to DmsA) is blocked in the Q-pool coupling assay, but reverse electron transfer (DmsA to MQ) is not. HOQNO elicits a significant change in the EPR line shape of the oxidized DmsAB(Cl02S)C [3Fe-4S] cluster but has no effect on the line shape of the reduced [4Fe-4S] clusters. We have identified a residue in DmsC involved in MQH2 oxidation. DmsC(H65), and in a double mutant, DmsAB(C102S)C(H65R), the DmsC mutation blocks the HOQNO effect on the [3Fe-4S] EPR line shape, suggesting, that the DmsC(H65R) mutation either blocks HOQNO binding or blocks a conformational link between a HOQNO binding site and the DmsB(C102S) [3Fe-4S] cluster. These results suggest that the MQH2 binding site of DmsC is conformationally and functionally linked to the Em,7 = -50 mV [4Fe-4S] cluster of DmsB.