HDX-MS performed on BtuB in E. coli outer membranes delineates the luminal domain’s allostery and unfolding upon B12 and TonB binding

Abstract

AbstractTo import large metabolites across the outer membrane of Gram-negative bacteria, TonB dependent transporters (TBDTs) undergo significant conformational change. After substrate binding in BtuB, the E. coli vitamin B12 TBDT, TonB binds and couples BtuB to the inner membrane proton motive force that powers transport (1). But, the role of TonB in rearranging the plug domain to form a putative pore remains enigmatic. Some studies focus on force-mediated unfolding (2) while others propose force-independent pore formation (3) by TonB binding leading to breakage of a salt bridge termed the “Ionic Lock”. Our hydrogen exchange/mass spectrometry measurements in E. coli outer membranes find that the region surrounding the Ionic Lock, far from the B12 site, is fully destabilized upon substrate binding. A comparison of the exchange between the B12 bound and the B12&TonB bound complexes indicates that B12 binding is sufficient to unfold the Ionic Lock region with the subsequent binding of a TonB fragment having much weaker effects. TonB binding accelerates exchange in the third substrate binding loop, but pore formation does not obviously occur in this or any region. This study provides a detailed structural and energetic description of the early stages of B12 passage that provides support both for and against current models of the transport process.Significance StatementTonB dependent transporters such as BtuB are found in the outer membranes of Gram-negative bacteria. They import scarce nutrients essential for growth, such as B12, the substrate of BtuB. Many transport steps remain enigmatic. Recent studies have emphasized force-mediated unfolding or the breakage of the “Ionic Lock”, a moiety far from the B12 binding site. A strong dependence on the membrane environment has been noted. Accordingly, we measured hydrogen exchange on BtuB still embedded in native outer membranes and found that B12 binding is sufficient to break the Ionic Lock. The amino terminus then extends into the periplasm to bind TonB. But we find no evidence of pore formation, which likely requires energy transduction from the inner membrane by TonB.