Native structure of flagellar MS ring is formed by 34 subunits with 23-fold and 11-fold subsymmetries

The bacterial flagellar MS ring is a transmembrane complex acting as the core of the flagellar motor. It not only acts as the template for rod and C ring assembly but also houses the type III protein export gate for assembly of the rod, hook and filament. The cytoplasmic C ring, involved in torque generation and rotation switch, is directly attached to the MS ring, and a symmetry mismatch between 26-fold MS ring and 34-fold C ring had been a long puzzle as to whether this would play some role in motor function. Although this puzzle seemed to have been resolved by the recent high-resolution structure of the MS ring with 33-fold symmetry with a variation from 32-fold to 35-fold because the C ring also shows a similar symmetry variation, it still remained ambiguous whether their symmetries are matched in the native motor structure. Here we show that the native MS ring structure formed by full-length FliF is 34-fold with no symmetry variation whereas the C ring has a small symmetry variation, indicating a flexibility in C ring assembly to generate small symmetry mismatches. We also show two conformations of FliF in part of its periplasmic region to form the 34-subunit ring with 23-fold and 11-fold subsymmetries in the inner and middle M ring, respectively, to accommodate the export gate at the center of the M ring.