Conformational cycle and small-molecule inhibition mechanism of a plant ABCB transporter in lipid membranes.

Abstract

In plants, ATP-binding cassette (ABC) transporters are crucial for nutrient uptake, phytohormone transport, and environmental response. It is of great interest to understand the mechanisms of these transporters and develop small-molecule modulators to regulate plant growth. <i>Arabidopsis</i> ABCB19 was recently shown to transport brassinosteroid, shaping hormone dynamics and plant architecture. However, the conformational cycle and inhibitor mechanism of ABCB transporters remain elusive. We reconstituted ABCB19 into lipid nanodiscs, where activity was drastically higher than in detergents, and determined its cryo-electron microscopy structures in substrate-free, substrate-bound, vanadate-trapped, and inhibitor-bound states. Inward-facing ABCB19 moved inward upon substrate binding and fully closed with vanadate trapping, unexpectedly temperature dependent. Two inhibitor molecules locked ABCB19 in the inward-facing conformation. Mutagenesis identified key residues for substrate and inhibitor binding, revealing differential contributions to transporter function and inhibition. These results deepen knowledge of plant ABCB transporters, laying a foundation for targeted manipulation to enhance plant resilience and productivity.