A lipid cue drives the subcellular localization of a self-inserting bacterial transmembrane protein

The correct subcellular localization of proteins is a critical step underlying myriad biological processes, but the cues that drive the specific localization of integral membrane proteins in bacteria remain largely undeciphered. During sporulation in Bacillus subtilis , a rod-shaped outer “mother cell” constructs an internal spherical “forespore” cell that eventually matures into the spore. The integral membrane protein ShfA is made in the mother cell cytosol and localizes to the surface of the forespore. Here, we report that, despite being a multi-pass transmembrane protein, ShfA spontaneously inserts into the lipid bilayer via its N-terminal “YabQ” domain without the apparent need for a pre-localized insertase. ShfA preferentially inserts into cell division septa in multiple bacterial species, indicating that a widely conserved septal cue drives ShfA localization. Structural modeling suggested that the YabQ domain harbors a specific intramembrane groove that can bind the universal lipid carrier undecaprenyl phosphate (UndP), and UndP depletion in vivo disrupted proper ShfA localization. We propose that ShfA localizes to sites of active cell wall synthesis by binding to UndP and/or molecules like lipid I and lipid II that contain UndP and speculate that the function of ShfA is to stabilize these precursors of cell wall biogenesis from the harsh cytosolic nanoenvironment that surrounds the forespore during sporulation.