Structural insights into H+-coupled multidrug extrusion by a MATE transporter

Abstract

Multidrug and toxic compound extrusion (MATE) transporters contribute to multidrug resistance by coupling the efflux of drugs to the influx of Na+ or H+. Known structures of Na+-coupled, extracellular-facing MATE transporters from the NorM subfamily revealed twelve membrane-spanning segments related by a quasi-twofold rotational symmetry and a multidrug-binding cavity situated near the membrane surface. Here we report the crystal structure of an H+-coupled MATE transporter from Bacillus halodurans and the DinF subfamily at 3.2 Å-resolution, unveiling a surprisingly asymmetric arrangement of twelve transmembrane helices. We also identified a membrane-embedded substrate-binding chamber by combining crystallographic and biochemical analyses. Our studies further suggested a direct competition between H+ and substrate during DinF-mediated transport, and how a MATE transporter alternates between its extracellular- and intracellular-facing conformations to propel multidrug extrusion. Collectively, our results demonstrated hitherto unrecognized mechanistic diversity among MATE transporters.