Structural plasticity of bacterial ESCRT-III protein PspA in higher-order assemblies

Eukaryotic members of the endosome sorting complex required for transport III (ESCRT-III) family have been shown to form diverse oligomeric assemblies. The bacterial phage shock protein A (PspA) has recently been identified as a bacterial member of the ESCRT-III superfamily, and monomeric PspA homo-oligomerizes to form large rod-shaped assemblies. As observed for eukaryotic ESCRT-III, PspA forms different tubular assemblies with varying diameters. Using electron cryo-microscopy (cryo-EM), we determined a total of 61 PspA structures and observed in molecular detail how structural plasticity of PspA rods is mediated by conformational changes at three hinge regions in the monomer and by the fixed as well as changing molecular contacts between protomers. Moreover, we reduced and increased the structural plasticity of PspA rods by removing the loop connecting helices α3/α4 and the addition of nucleotides, respectively. Based on our analysis of PspA-mediated membrane remodeling, we suggest that the observed mode of structural plasticity is a prerequisite for the biological function of ESCRT-III superfamily members.