ATP-driven membrane binding and polymerization of bacterial actin MreB promotes local membrane fluidization

The bacterial actin homologue MreB plays a key role in rod cell shape determination. We recently showed that MreB from the Gram-positive bacterium Geobacillus stearothermophilus (MreBGs) polymerizes into straight pairs of protofilaments in the presence of both ATP and a lipid surface. Membrane interaction is thought to be mediated by electrostatic interactions with anionic lipids, with final anchoring relying on two spatially close hydrophobic motifs that protrude from the MreBGs monomers, forming a putative membrane-insertion domain. Here, we determined the binding properties of ATP and ADP to MreBGs using fluorescence anisotropy, and monitored ATP-mediated binding and polymer formation on lipid bilayers using liposome binding assays and AFM, respectively. Finally, we used solid-state NMR to visualize the interaction between the membrane and MreBGs at the atomic level. Our findings reveal that MreBGs has similar affinity for both ATP and ADP, unlike eukaryotic actin. We also show that monomeric MreBGs establishes peripheral contacts with the membrane likely through electrostatic interactions, while ATP-induced MreBGs filaments insert into the lipid bilayer without interfering with the membrane lamellar phase and have a significant local fluidifying effect. Statement of significanceBacteria rely on the actin-like protein MreB to determine and maintain their cell shape, like actin does in eukaryotic cells. To perform its tightly regulated morphogenetic function, MreB forms membrane-associated nanofilaments in vivo, which control the cell wall biosynthetic machinery. We recently demonstrated that, in vitro, MreB from the Gram-positive bacterium Geobacillus stearothermophilus requires both ATP and lipids to polymerize into pairs of filaments. Here, we show that in the presence of ATP, Geobacillus MreB forms membrane-bound filaments that directly impact local membrane fluidity, which could translate into a regulatory effect on cell wall synthetic enzymes. We further reveal that MreB binds both ATP and ADP with similar affinity, unlike eukaryotic actin, which preferentially binds ATP over ADP, and speculate that this could be a mechanism modulating the pool of polymerization-competent MreB in bacteria.