Conserved GTPase mechanism in bacterial FtsZ and archaeal tubulin filaments.

Self-assembling protein filaments are at the heart of cell function. Among them, tubulin-like proteins are essential for cell division, DNA segregation and cytoskeletal functions across the domains of life. FtsZ and tubulin share their core structures, a characteristic nucleotide-binding pocket and similar protofilament architecture. GTP hydrolysis between consecutive subunits drives their assembly dynamics. Two recent studies provide previously missing, filament atomic structures of bacterial FtsZ and a recently discovered archaeal tubulin in their nucleotide triphosphate-bound states. Both filament structures reveal strikingly conserved interfacial GTPase active sites, with Mg ²⁺ and K ⁺ /Na ⁺ cations and an NxDxxD/E triad of catalytic residues, probably inherited from the common ancestor of FtsZs and tubulins. Moreover, both proteins exhibit nucleotide-regulated subunit association mediated by interfacial water bridges, as well as polymerization-induced structural changes, likely enabling related dynamic assembly mechanisms.
(© 2022 The Authors. The FEBS Journal published by John Wiley & Sons Ltd on behalf of Federation of European Biochemical Societies.)