FliI is a Salmonella typhimurium protein that is needed for flagellar assembly and may be involved in a specialized protein export pathway that proceeds without signal peptide cleavage. FliT shows extensive sequence similarity to the catalytic 13 subunit of the FoF1 ATPase (A. P. Vogler, M. Homma, V. M. Irikura, and R. M. Macnab, J. Bacteriol. 173:3564-3572, 1991). It is even more similar to the Spa47 protein of Shigella flexneri (M. M. Venkatesan, J. M. Buysse, and E. V. Oaks, J. Bacteriol. 174:1990-2001) and the HrpB6 protein of Xanthomonas campestris (S. Fenselau, I. Balbo, and U. Bonas, Mol. Plant-Microbe Interact. 5:390-396, 1992), which are believed to play a role in the export of virulence proteins. Site-directed mutagenesis of residues in FliI that correspond to catalytically important residues in the F1 ,3 subunit resulted in loss of flagellation, supporting the hypothesis that Fliu is an ATPase. FliT was overproduced and purified almost to homogeneity. It demonstrated ATP binding but not hydrolysis. An antibody raised against FliI permitted detection of the protein in wild-type cells and an estimate of about 1,500 subunits per cell. An antibody directed against the F1 P subunit ofEscherichia coli cross-reacted with Flil, confirming that the proteins are structurally related. The relationship between three proteins involved in flagellar assembly (FliI, FlhA, and FliP) and homologs in a variety of virulence systems is discussed.The flagellum of Salmonella typhimurium and those of many other bacteria consist of at least three distinct structures: the filament and hook (both of which are completely external to the cell) and the basal body (which spans the cytoplasmic membrane, the periplasmic space, and the outer membrane) (see reference 36 for a review). Thus, many flagellar proteins, following their synthesis inside the cell, need to be exported from the cytoplasm. Only two of these (FlgH and FlgI, from which the outer pair of basal-body rings are constructed) appear to be exported by the conventional signal peptide-dependent pathway (22,26). The rest do not undergo cleavage of a signal peptide and are presumed to be exported by a unique flagellum-specific pathway (36). The major protein in this class, flagellin, is known to assemble at the distal end of the growing filament (10, 25), and it is presumed that the proteins constituting the other substructures such as the rod and hook are also assembled by distal addition, since they are related to flagellin (20, 23) and the order of assembly of these substructures is from cell proximal to cell distal (first rod, then hook, and finally filament) (27,31,48,49). The physical path for travel of subunits to their destination is almost certainly through the hollow channel that exists in the structure (38,42 vicinity of the flagellar base, that transports the proteins across the plane of the cell membrane (although not through the bulk membrane itself) into this channel. This export apparatus must be selective in the proteins it recognizes, but a flagellum-speci...
