Functional implications of the conformational landscape of a multidrug transporter revealed by Zebrafish Abcb4 structures

Abstract The hallmark of multidrug resistance conferred by the human ABC transporter ABCB1 (hP-gp) is the recognition and efflux of a diverse range of drugs, though the precise mechanism of polyspecificity remains unresolved. In aquatic animals such as zebrafish, Abcb4, a functional homolog of hP-gp, plays a vital role in surviving environmental toxicants. Here, we show that DrAbcb4 exhibits comparable basal and drug-stimulated ATPase activity to hP-gp. Using cryo-EM, we capture five inward-facing DrAbcb4 conformations with varying separations between its two lobes, illustrating its open-and-close motion. The range of separation exceeds that seen in published P-gp structures that appear to be conformationally restricted. This global open-and-close motion is coupled with individual helix movement, resulting in a highly fluid substrate-binding pocket. These dynamic changes, likely underlying the polyspecificity of substrate recognition, predict unconventional protein-ligand interactions that are supported by structures of DrAbcb4 bound to the P-gp inhibitors tariquidar and elacridar, and the substrate vincristine.