Conversion of the Sensor Kinase DcuS to the Fumarate Sensitive State by Interaction of the Bifunctional Transporter DctA at the TM2/PASC-Linker Region

The membrane-bound C-4-dicarboxylate (C4DC) sensor kinase DcuS of Escherichia coli typically forms a protein complex with the C4DC transporter DctA. The DctA x DcuS complex is able to respond to C4DCs, whereas DcuS without DctA is in the permanent ON state. In DctA, the C-terminal helix 8b (H8b) serves as the site for interaction with DcuS. Here the interaction site in DcuS and the related structural and functional adaptation in DcuS were determined. The Linker connecting transmembrane helix 2 (TM2) and the cytosolic PAS(C) (Per-ARNT-SIM) domain of DcuS, was identified as the major site for interaction with DctA-H8b by in vivo interaction studies. The Linker is known to convert the piston-type transmembrane signaling of TM2 to a tilting motion which relies on a resolution of the Linker-Linker' homodimer in the presence of C4DCs. Absence of DctA caused decreased cross-linking in the Linker, as identified by oxidative Cys-cross-linking. This response resembled structurally and functionally that of fumarate activation in the DctA x DcuS complex. Overall, formation of the DctA x DcuS complex is based on the interaction of the DcuS Linker with DctA H8b; the interaction is required to set DcuS in the C4DC-responsive state by stabilizing the linker-linker' homodimer in DcuS. This work identifies DctA as a structural co-regulator of DcuS sensor kinase.

Automated summary

This study identified the interaction site in the membrane-bound C-4-dicarboxylate (C4DC) sensor kinase DcuS of Escherichia coli and the related structural and functional adaptations in DcuS. The stabilization of the linker-linker' homodimer in DcuS is essential for setting DcuS in the C4DC-responsive state in the DctA x DcuS complex, with DctA serving as a structural co-regulator of DcuS sensor kinase.