Intergenic suppression between the flagellar MS ring protein FliF of Salmonella and FlhA, a membrane component of its export apparatus

The MS ring of the flagellar basal body of Salmonella is an integral membrane structure consisting of about 26 subunits of a 61-kDa protein, FliF. Out of many nonflagellate fliF mutants tested, three gave rise to intergenic suppressors in flagellar region II. The pseudorevertants swarmed, though poorly; this partial recovery of motile function was shown to be due to partial recovery of export function and flagellar assembly. The three parental mutants were all found to carry the same mutation, a six-base deletion corresponding to loss of Ala-174 and Ser-175 in the predicted periplasmic domain of the FliF protein. The 19 intergenic suppressors identified all lay in flhA, and they consisted of 10 independent examples at the nucleotide level or 9 at the amino acid level. Since two of the nine corresponded to different substitutions at the same amino acid position, only eight positions in the FlhA protein have given rise to suppressors. Thus, FliF-FlhA intergenic suppression is a fairly rare event. FlhA is a component of the flagellar protein export apparatus, with an integral membrane domain encompassing the N-terminal half of the sequence and a cytoplasmic C-terminal domain. All of the suppressing mutations lay within the integral membrane domain. These mutations, when placed in a wild-type fliF background, had no mutant phenotype. In the fliF mutant background, mutant FlhA was dominant, yielding a pseudorevertant phenotype. Wild-type FlhA did not exert significant negative dominance in the pseudorevertant background, indicating that it does not compete effectively with mutant FlhA for interaction with mutant FliF. Mutant FliF was partially dominant over wild-type FliF in both the wild-type and second-site FlhA backgrounds. Membrane fractionation experiments indicated that the fliF mutation, though preventing export, was mild enough to permit assembly of the MS ring itself, and also assembly of the cytoplasmic C ring onto the MS ring. The data from this study provide genetic support for a model in which at least the FlhA component of the export apparatus physically interacts with the MS ring within which it is housed.     

Genetic characterization of conserved charged residues in the bacterial flagellar type III export protein FlhA

For assembly of the bacterial flagellum, most of flagellar proteins are transported to the distal end of the flagellum by the flagellar type III protein export apparatus powered by proton motive force (PMF) across the cytoplasmic membrane. FlhA is an integral membrane protein of the export apparatus and is involved in an early stage of the export process along with three soluble proteins, FliH, FliI, and FliJ, but the energy coupling mechanism remains unknown. Here, we carried out site-directed mutagenesis of eight, highly conserved charged residues in putative juxta- and trans-membrane helices of FlhA. Only Asp-208 was an essential acidic residue. Most of the FlhA substitutions were tolerated, but resulted in loss-of-function in the ΔfliH-fliI mutant background, even with the second-site flhB(P28T) mutation that increases the probability of flagellar protein export in the absence of FliH and FliI. The addition of FliH and FliI allowed the D45A, R85A, R94K and R270A mutant proteins to work even in the presence of the flhB(P28T) mutation. Suppressor analysis of a flhA(K203W) mutation showed an interaction between FlhA and FliR. Taken all together, we suggest that Asp-208 is directly involved in PMF-driven protein export and that the cooperative interactions of FlhA with FlhB, FliH, FliI, and FliR drive the translocation of export substrate.     

Structural and functional analysis of the C-terminal cytoplasmic domain of FlhA, an integral membrane component of the type III flagellar protein export apparatus in Salmonella

FlhA is an integral membrane component of the Salmonella type III flagellar protein export apparatus. It consists of 692 amino acid residues and has two domains: the N-terminal transmembrane domain consisting of the first 327 amino acid residues, and the C-terminal cytoplasmic domain (FlhAC) comprising the remainder. Here, we have investigated the structure and function of FlhAC. DNA sequence analysis revealed that temperature-sensitive flhA mutations, which abolish flagellar protein export at the restrictive temperature, lie in FlhAC, indicating that FlhAC plays an important role in the protein export process. Limited proteolysis of purified His-FlhAC by trypsin and V8 showed that only a small part of FlhAC near its N terminus (residues 328-351) is sensitive to proteolysis. FlhAC38K, the smallest fragment produced by V8 proteolysis, is monomeric and has a spherical shape as judged by analytical gel filtration chromatography and analytical ultracentrifugation. The far-UV CD spectrum of FlhAC38K showed that it contains considerable amounts of secondary structure. FlhA(Delta328-351) missing residues 328-351 failed to complement the flhA mutant, indicating that the proteolytically sensitive region of FlhA is important for its function. FlhA(Delta328-351) was inserted into the cytoplasmic membrane, and exerted a strong dominant negative effect on wild-type cells, suggesting that it retains the ability to interact with other export components within the cytoplasmic membrane. Overproduced FlhAC38K inhibited both motility and flagellar protein export of wild-type cells to some degree, suggesting that FlhAC38K is directly involved in the translocation reaction. Amino acid residues 328-351 of FlhA appear to be a relatively flexible linker between the transmembrane domain and FlhAC38K.     

Interaction of FliI, a component of the flagellar export apparatus, with flagellin and hook protein.

FliI is a key component of the flagellar export apparatus in Salmonella typhimurium. It catalyzes the hydrolysis of ATP which is necessary for flagellar assembly. Affinity blotting experiments showed that purified flagellin and hook protein, two flagellar axial proteins, interact specifically with FliI. The interaction of either of the two proteins with FliI, increases the intrinsic ATPase activity. The presence of either flagellin or hook protein stimulates ATPase activity in a specific and reversible manner. A Vmax of 0.12 nmol Pi min-1 microgram-1 and a Km for MgATP of 0.35 mM was determined for the unstimulated FliI; the presence of flagellin increased the Vmax to 0.35 nmol Pi min-1 microgram-1 and the Km for MgATP to 1.1 mM. The stimulation induced by the axial proteins was fully reversible suggesting a direct link between the catalytic activity of FliI and the export process.     

Components of the Salmonella flagellar export apparatus and classification of export substrates

Until now, identification of components of the flagellar protein export apparatus has been indirect. We have now identified these components directly by establishing whether mutants defective in putative export components could translocate export substrates across the cytoplasmic membrane into the periplasmic space. Hook-type proteins could be exported to the periplasm of rod mutants, indicating that rod protein export does not have to precede hook-type protein export and therefore that both types of proteins belong to a single export class, the rod/hook-type class, which is distinct from the filament-type class. Hook-capping protein (FlgD) and hook protein (FlgE) required FlhA, FlhB, FliH, FliI, FliO, FliP, FliQ, and FliR for their export to the periplasm. In the case of flagellin as an export substrate, because of the phenomenon of hook-to-filament switching of export specificity, it was necessary to use temperature-sensitive mutants and establish whether flagellin could be exported to the cell exterior following a shift from the permissive to the restrictive temperature. Again, FlhA, FlhB, FliH, FliI, and FliO were required for its export. No suitable temperature-sensitive fliQ or fliR mutants were available. FliP appeared not to be required for flagellin export, but we suspect that the temperature-sensitive FliP protein continued to function at the restrictive temperature if incorporated at the permissive temperature. Thus, we conclude that these eight proteins are general components of the flagellar export pathway. FliJ was necessary for export of hook-type proteins (FlgD and FlgE); we were unable to test whether FliJ is needed for export of filament-type proteins. We suspect that FliJ may be a cytoplasmic chaperone for the hook-type proteins and possibly also for FliE and the rod proteins. FlgJ was not required for the export of the hook-type proteins; again, because of lack of a suitable temperature-sensitive mutant, we were unable to test whether it was required for export of filament-type proteins. Finally, it was established that there is an interaction between the processes of outer ring assembly and of penetration of the outer membrane by the rod and nascent hook, the latter process being of course necessary for passage of export substrates into the external medium. During the brief transition stage from completion of rod assembly and initiation of hook assembly, the L ring and perhaps the capping protein FlgD can be regarded as bona fide export components, with the L ring being in a formal sense the equivalent of the outer membrane secretin structure of type III virulence factor export systems.     

Type III flagellar protein export and flagellar assembly

Bacterial flagella, unlike eukaryotic flagella, are largely external to the cell and therefore many of their subunits have to be exported. Export is ATP-driven. In Salmonella, the bacterium on which this chapter largely focuses, the apparatus responsible for flagellar protein export consists of six membrane components, three soluble components and several substrate-specific chaperones. Other flagellated eubacteria have similar systems. The membrane components of the export apparatus are housed within the flagellar basal body and deliver their substrates into a channel or lumen in the nascent structure from which point they diffuse to the far end and assemble. Both on the basis of sequence similarities of several components and structural similarities, the flagellar protein export systems clearly belong to the type III superfamily, whose other members are responsible for secretion of virulence factors by many species of pathogenic bacteria.     

Analysis of the cytoplasmic domains of Salmonella FlhA and interactions with components of the flagellar export machinery

Most flagellar proteins are exported via a type III export apparatus which, in part, consists of the membrane proteins FlhA, FlhB, FliO, FliP, FliQ, and FliR and is housed within the membrane-supramembrane ring formed by FliF subunits. Salmonella FlhA is a 692-residue integral membrane protein with eight predicted transmembrane spans. Its function is not understood, but it is necessary for flagellar export. We have created mutants in which potentially important sequences were deleted. FlhA lacking the amino-terminal sequence prior to the first transmembrane span failed to complement and was dominant negative, suggesting that the sequence is required for function. Similar effects were seen in a variant lacking a highly conserved domain (FHIPEP) within a putative cytoplasmic loop. Scanning deletion analysis of the cytoplasmic domain (FlhAc) demonstrated that substantially all of FlhAc is required for efficient function. Affinity blotting showed that FlhA interacts with several other export apparatus membrane proteins. The implications of these findings are discussed, and a model of FlhA within the export apparatus is presented.     

Interactions of FliJ with the Salmonella type III flagellar export apparatus

FliJ, a 17-kDa protein, is a soluble component of the Salmonella type III flagellar protein export system that has antiaggregation properties and several other characteristics that suggest it may have a chaperone-like function. We have now examined this protein in detail. Ten-amino-acid scanning deletions covering the entire 147-amino-acid sequence were tested for complementation of a fliJ null strain; only the first and last deletions complemented. A few of the deletions, especially towards the C terminus, exerted a dominant negative effect on wild-type cells, indicating that they were actively interfering with function. Two truncated versions of FliJ, representing its N- and C-terminal halves, failed to complement and were not dominant. We tested for FliJ self-association by several techniques. Size-exclusion chromatography (Superdex 200) indicated an apparent molecular mass of around 50 kDa, which could reflect either multimerization or an elongated shape or both. Multiangle light scattering gave a peak value of 20 kDa, close to the molecular mass of the monomer. Analytical ultracentrifugation gave evidence for weak self-association as a trimer or tetramer. It was known from previous studies that FliJ interacts with the N-terminal region of FliH, a negative regulator of the ATPase FliI. Using both truncation and deletion versions of FliJ, we now show that it is its C-terminal region that is responsible for this interaction. We also show that FliJ interacts with the soluble cytoplasmic domain of the largest membrane component of the export apparatus, FlhA; although small deletions in FliJ did not interfere with the association, both truncated versions failed to associate, indicating that a substantial amount of the central region of the FliJ sequence participates in the association. We present a model summarizing these multiple interactions.     

Interactions among membrane and soluble components of the flagellar export apparatus of Salmonella

Interactions among several components of the flagellar export apparatus of Salmonella were studied using affinity chromatography, affinity blotting, and fluorescence resonance energy transfer (FRET). The components examined were two integral membrane proteins, FlhA and FlhB, and two soluble components, FliH and the ATPase FliI. Affinity chromatography and affinity blotting demonstrated a heterologous interaction between FlhA and FlhB but not homologous FlhA-FlhA or FlhB-FlhB interactions. Both FlhA and FlhB consist of N-terminal transmembrane domains and C-terminal cytoplasmic domains (FlhA(C) and FlhB(C)). To study the interactions among the cytoplasmic components (FlhA(C), FlhB(C), FliH, and FliI), FRET measurements were carried out using fluorescein-5-isothiocyanate (FITC) as donor and tetramethylrhodamine-5- (and 6-) isothiocyanate (TRITC) as acceptor. To reveal the nature of the binding interactions, measurements were carried out in physiological buffer, at high salt (0.5 M NaCl) and in 30% 2-propanol. The results indicated that FlhA(C) could bind to FlhB(C) and both FlhA(C) and FlhB(C) could bind to themselves. Both FlhA(C) and FlhB(C) bound to FliH and FliI. Several in-frame deletion mutants of FliH were examined and found to have only minor effects of decreased binding to FlhA(C) and FlhB(C); deletions in the interior of the FliH sequence had a greater effect than those at the N terminus. The FliI mutants examined bound FlhA(C) and FlhB(C) about the same as or slightly more weakly than wild-type FliI. FliH bound more weakly to FliI carrying the N-terminal double mutation R7C/L12P than it did to wild-type FliI, confirming the importance of the N terminus of FliI for its interaction with FliH.     

Soluble components of the flagellar export apparatus,FliI, FliJ,and FliH,do not deliver flagellin,the major filament protein,from the cytosol to the export gate

Flagella, the locomotion organelles of bacteria, extend from the cytoplasm to the cell exterior. External flagellar proteins are synthesized in the cytoplasm and exported by the flagellar type III secretion system. Soluble components of the flagellar export apparatus, FliI, FliH, and FliJ, have been implicated to carry late export substrates in complex with their cognate chaperones from the cytoplasm to the export gate. The importance of the soluble components in the delivery of the three minor late substrates FlgK, FlgL (hook–filament junction) and FliD (filament-cap) has been convincingly demonstrated, but their role in the transport of the major filament component flagellin (FliC) is still unclear.     

The ATPase FliI can interact with the type III flagellar protein export apparatus in the absence of its regulator,FliH

Salmonella FliI is the ATPase that drives flagellar protein export. It normally exists as a complex together with the regulatory protein FliH. A fliH null mutant was slightly motile, with overproduction of FliI resulting in substantial improvement of its motility. Mutations in the cytoplasmic domains of FlhA and FlhB, which are integral membrane components of the type III flagellar export apparatus, also resulted in substantially improved motility, even at normal FliI levels. Thus, FliH, though undoubtedly important, is not essential.     

The FliP and FliR proteins of Salmonella typhimurium, putative components of the type III flagellar export apparatus, are located in the flagellar basal body

Most of the structural components of the flagellum of Salmonella typhimurium are exported through a flagellum-specific pathway, which is a member of the family of type III secretory pathways. The export apparatus for this process is poorly understood. A previous study has shown that two proteins, about 23 and 26 kDa in size and of unknown genetic origin, are incorporated into the flagellar basal body at a very early stage of flagellar assembly. In the present study, we demonstrate that these basal body proteins are FliP (in its mature form after signal peptide cleavage) and FliR respectively. Both of these proteins have homologues in other type III secretion systems. By placing a FLAG epitope tag on FliR and the MS-ring protein FliF and immunoblotting isolated hook basal body complexes with anti-FLAG monoclonal antibody, we estimate (using the FLAG-tagged FliF as an internal reference) that the stoichiometry of FliR is fewer than three copies per basal body. An independent estimate of stoichiometry was made using data from an earlier quantitative radiolabelling analysis, yielding values of around four or five subunits per basal body for FliP and around one subunit per basal body for FliR. Immunoelectron microscopy using anti-FLAG antibody and gold–protein A suggests that FliR is located near the MS ring. We propose that the flagellar export apparatus contains FliP and FliR and that this apparatus is embedded in a patch of membrane in the central pore of the MS ring.     

Secretion of virulence proteins from Campylobacter jejuni is dependent on a functional flagellar export apparatus

Campylobacter jejuni, a gram-negative motile bacterium, secretes a set of proteins termed the Campylobacter invasion antigens (Cia proteins). The purpose of this study was to determine whether the flagellar apparatus serves as the export apparatus for the Cia proteins. Mutations were generated in five genes encoding three structural components of the flagella, the flagellar basal body (flgB and flgC), hook (flgE2), and filament (flaA and flaB) genes, as well as in genes whose products are essential for flagellar protein export (flhB and fliI). While mutations that affected filament assembly were found to be nonmotile (Mot-) and did not secrete Cia proteins (S-), a flaA (flaB+) filament mutant was found to be nonmotile but Cia protein secretion competent (Mot-, S+). Complementation of a flaA flaB double mutant with a shuttle plasmid harboring either the flaA or flaB gene restored Cia protein secretion, suggesting that Cia export requires at least one of the two filament proteins. Infection of INT 407 human intestinal cells with the C. jejuni mutants revealed that maximal invasion of the epithelial cells required motile bacteria that are secretion competent. Collectively, these data suggest that the C. jejuni Cia proteins are secreted from the flagellar export apparatus.     

Structural properties of FliH,an ATPase regulatory component of the Salmonella type III flagellar export apparatus

FliH is a regulatory component for FliI, the ATPase that is responsible for driving flagellar protein export in Salmonella. FliH consists of 235 amino acid residues, has a quite elongated shape, exists as a homodimer and together with FliI forms a heterotrimer. Here, we have investigated the structural properties of the FliH homodimer in further detail. Like intact His-tagged FliH homodimer, fragment His-FliH(N2) (consisting of the first 102 amino acid residues of FliH), exhibited anomalous elution behavior in gel filtration chromatography; the same was true of His-FliH(C1) (consisting of amino acid residues 119-235), but to a much lesser degree. Thus the elongated shape of FliH appears to derive primarily from its N-terminal region. A deletion version of N-His-FliH, lacking amino acid residues 101-140, does not dimerize and so we were able to establish the gel filtration properties of an almost full-size monomeric form; it also exhibited anomalous elution behavior. We performed trypsin proteolysis of the FliH homodimer and subjected the cleavage products to gel filtration chromatography. FliH was degraded by trypsin and a contaminating protease into two stable fragments: FliH(Prt1) (missing both the first ten and the last 12 amino acid residues), and FliH(Prt2) (missing both the first ten and the last 63 amino acid residues); however, substantial amounts remained undigested even after 24 hours. Under native conditions, both FliH(Prt1) and FliH(Prt2) co-eluted with undigested His-FliH from the gel filtration column, indicating that the fragments exist as a hybrid dimer with intact FliH. These results suggest that the two subunits within the dimer differ in their proteolytic susceptibility. No heterotrimer was observed by gel filtration chromatography when His-FliI was mixed with either His-FliH/FliH(Prt1) or His-FliH/FliH(Prt2) hybrid dimers. A hybrid dimer of FliH and His-FliHDelta1 (lacking the first ten amino acid residues) retained the ability to form a complex with His-FliI. In contrast, hybrid dimers consisting of FliH and either His-FliH(W223ochre) or His-FliH(V172ochre) failed to complex to His-FliI, demonstrating that the C-terminal region of both FliH monomers within the FliH dimer are required for heterotrimer formation.     

Role of FliJ in flagellar protein export in Salmonella

We isolated and characterized spontaneous mutants with defects in the 147-amino-acid Salmonella protein FliJ, which is a cytoplasmic component of the type III flagellar export apparatus. These mutants, including ones with null mutations, have the ability to form swarms on motility agar plates after prolonged incubation at 30 degrees C; i.e., they display a leaky motile phenotype. One mutant, SJW277, which formed significantly bigger swarms than the others, encoded only the N-terminal 73 amino acids of FliJ, one-half of the protein. At 30 degrees C, overproduction of this mutant protein improved, to wild-type levels, both motility and the ability to export both rod/hook-type (FlgD; hook capping protein) and filament-type (FliC; flagellin) substrates. At 42 degrees C, however, export was inhibited, indicating that the mutant FliJ protein was temperature sensitive. Taking advantage of this, we performed temperature upshift experiments, which demonstrated that FliJ is directly required for the export of FliC. Co-overproduction of FliJ and either of two export substrates, FliE or FlgG, hindered their aggregation in the cytoplasm. We conclude that FliJ is a general component of the flagellar export apparatus and has a chaperone-like activity for both rod/hook-type and filament-type substrates.     

Characterization in vitro of the defect in a temperature-sensitive mutant of the protein subunit of RNase P from Escherichia coli.

We have studied the assembly of Escherichia coli RNase P from its catalytic RNA subunit (M1 RNA) and its protein subunit (C5 protein). A mutant form of the protein subunit, C5A49, has been purified to apparent homogeneity from a strain of E. coli carrying a thermosensitive mutation in the rnpA gene. The heat inactivation kinetics of both wild-type and mutant holoenzymes are similar, an indication of equivalent thermal stability. However, when the catalytic efficiencies of the holoenzymes were compared, we found that the holoenzyme containing the mutant protein had a lower efficiency of cleavage than the wild-type holoenzyme at 33, 37, and 44 degrees C. We then explored the interaction of M1 RNA and C5 protein during the assembly of the holoenzyme. The yield of active holoenzyme obtained by reconstitution with wild-type M1 RNA and C5A49 protein in vitro can be considerably enhanced by the addition of excess M1 RNA, just as it can be in vivo. We concluded that the Arg-46----His-46 mutation in the C5A49 protein affects the ability of the protein to participate with M1 RNA in the normal assembly process of RNase P.     

Application of temperature-sensitive mutants for single-cell protein production

Cell-division-cycle, temperature-sensitive mutants of Saccharomyces cerevisiae were investigated as a means of altering the morphological characteristics and subsequent physical properties of single-cell protein (SCP). Strain 4471, harboring mutation cdc 4, formed a visible complex mass at the nonpermissive temperature, after being grown at 30°C and then transferred to 37°C for 8 hr. Microscopic observation showed that the mother cell was unable to complete the budding process at the nonpermissive temperature, which caused the cells to enlarge. Viscosity measurements were used to establish and characterize optimum morphological changes in the yeast. The Maximum increase in viscosity occurred when cells were incubated at 30°C and then shifted to 37°C for 8 hr. Strain 4471 exhibited yield stress, whereas A364A did not. Maximum change in yield stress occurred when cells were shifted from 30 to 37°C for 8 hr. No significant loss of protein or RNA occurred in strain 4471, as compared to strain A364A, when incubated at the nonpermissive temperature.     

Functional changes in temperature-sensitive mutants of the adenovirus single-stranded DNA-binding protein are accompanied by structural alterations.

Adenovirus requires the virus-encoded single-stranded DNA-binding protein (DBP) to replicate its DNA. We have previously shown (M. Tsuji, P. C. van der Vliet, and G. R. Kitchingman, J. Biol. Chem. 266:16178-16187, 1991) that the inability of three temperature-sensitive (ts) mutant DBPs (Ad2+ ND1ts23, Ad2ts111A, and Ad5ts125) to support DNA replication at the nonpermissive temperature was associated with impaired ability to bind to DNA. In this study, we examined these mutant proteins for structural alterations that might be linked to the functional changes. All three ts mutants, but not the wild-type protein, showed different proteolytic cleavage patterns before and after heating at 40 degrees C (the nonpermissive temperature), suggesting a possible conformational change during heating. The Ad2+ND1ts23 and Ad2ts111A DBPs have single amino acid changes located in a putative zinc finger subdomain (positions 282 and 280). In the presence of zinc ions, these ts mutants showed significantly increased resistance to inactivation at 40 degrees C. Surprisingly, however, the stabilizing effect of zinc was also observed with the Ad5ts125DBP, which contains a mutation located more than 100 amino acids from the zinc finger. Other related metal ions, such as cobalt, cadmium, and mercury, did not protect the ts DBPs from inactivation at 40 degrees C. These results indicate that functional changes of the ts DBPs in DNA replication and DNA binding are accompanied by structural alterations in the protein and that zinc and the metal-binding subdomain may play an important role in the structure and/or function of the DBP.