Souza, D. P.; Espadas, J.; Chaaban, S.; Moody, E. R. R.; Hatano, T.; Balasubramanian, M.; Williams, T. A.; Roux, A.; Baum, B.

ESCRT-III proteins assemble into composite polymers that undergo stepwise changes in composition and structure to deform membranes across the tree of life. Here, using a phylogenetic analysis we demonstrate that the two ESCRT-III proteins present in our closest archaeal relatives are evolutionarily related to B-type and A-type eukaryotic paralogues, which initiate and execute membrane remodelling, respectively. This deep homology is reflected in ESCRT-III structure and function as demonstrated by the fact that ESCRT-IIIB assembles into parallel arrays on planar membranes to initiate membrane deformation, and is required to recruit ESCRT-IIIA to generate composite polymers. ESCRT-IIIA homopolymers can then remodel membranes into tubes, as a likely prelude to scission. Taken together, this analysis reveals a set of conserved principles governing ESCRT-III-dependent membrane remodelling that first emerged with the evolution of a two-component ESCRT-III system in the Asgard archaea, and which continue to underlie complex multi-component, ESCRT-III-dependent membrane remodelling in eukaryotes.