Role of the C-Terminal Cytoplasmic Domain of FlhA in Bacterial Flagellar Type III Protein Export

For construction of the bacterial flagellum, many of the flagellar proteins are exported into the central channel of the flagellar structure by the flagellar type III protein export apparatus. FlhA and FlhB, which are integral membrane proteins of the export apparatus, form a docking platform for the soluble components of the export apparatus, FliH, FliI, and FliJ. The C-terminal cytoplasmic domain of FlhA (FlhA_C) is required for protein export, but it is not clear how it works. Here, we analyzed a temperature-sensitive Salmonella enterica mutant, the flhA(G368C) mutant, which has a mutation in the sequence encoding FlhA_C. The G368C mutation did not eliminate the interactions with FliH, FliI, FliJ, and the C-terminal cytoplasmic domain of FlhB, suggesting that the mutation blocks the export process after the FliH-FliI-FliJ-export substrate complex binds to the FlhA-FlhB platform. Limited proteolysis showed that FlhA_C consists of at least three subdomains, a flexible linker, FlhA_CN, and FlhA_CC, and that FlhA_CN becomes sensitive to proteolysis by the G368C mutation. Intragenic suppressor mutations were identified in these subdomains and restored flagellar protein export to a considerable degree. However, none of these suppressor mutations suppressed the protease sensitivity. We suggest that FlhA_C not only forms part of the docking platform for the FliH-FliI-FliJ-export substrate complex but also is directly involved in the translocation of the export substrate into the central channel of the growing flagellar structure.The bacterial flagellum, which is responsible for motility, is a supramolecular complex of about 30 different proteins, and it consists of at least three substructures: the basal body, the hook, and the filament. Flagellar assembly begins with the basal body, followed by the hook and finally the filament. Many of the flagellar component proteins are translocated into the central channel of the growing flagellar structure and then to the distal end of the structure for self-assembly by the flagellar type III protein export apparatus (11, 16, 22). This export apparatus consists of six integral membrane proteins, FlhA, FlhB, FliO, FliP, FliQ, and FliR, and three soluble proteins, FliH, FliI, and FliJ (18, 21). These protein components show significant sequence and functional similarities to those of the type III secretion systems of pathogenic bacteria, which directly inject virulence factors into their host cells (11, 16).FliI is an ATPase (4) and forms an FliH₂-FliI complex with its regulator, FliH, in the cytoplasm (20). FliI self-assembles into a homo-hexamer and hence exhibits full ATPase activity (1, 8, 17). FliH and FliI, together with FliJ and the export substrate, bind to the export core complex, which is composed of the six integral membrane proteins, to recruit export substrates from the cytoplasm to the core complex (14) and facilitate the initial entry of export substrates into the export gate (23). FliJ not only prevents premature aggregation of export substrates in the cytoplasm (13) but also plays an important role in the escort mechanism for cycling export chaperones during flagellar assembly (3). The export core complex is believed to be located in the central pore of the basal body MS ring (11, 16, 22). In fact, it has been found that FlhA, FliP, and FliR are associated with the MS ring (5, 9). The FliR-FlhB fusion protein is partially functional, suggesting that FliR and FlhB interact with each other within the MS ring (29). The export core complex utilizes a proton motive force across the cytoplasmic membrane as the energy source to drive the successive unfolding of export substrates and their translocation into the central channel of the growing flagellum (23, 27). Here we refer to the export core complex as the “export gate,” as we have previously (8, 16, 23, 24).FlhA is a 692-amino-acid protein consisting of two regions: a hydrophobic N-terminal transmembrane region with eight predicted α-helical transmembrane spans (FlhA_TM) and a hydrophilic C-terminal cytoplasmic region (FlhA_C) (12, 15). FlhA_TM is responsible for the association with the MS ring (9). FlhA_C interacts with FliH, FliI, FliJ, and the C-terminal cytoplasmic domain of FlhB (6, 12, 21, 24) and plays a role in the initial export process with these proteins (28). It has been shown that the V404M mutation in FlhA_C increases not only the probability of FliI binding to the export gate in the absence of FliH (14) but also the efficiency of substrate translocation through the export gate in the absence of FliH and FliI (23). Recently, it has been shown that FlhA_C is also required for substrate recognition (7). These observations suggest that an interaction between FlhA_C and FliI is coupled with substrate entry, although it is not clear how.In order to understand the mechanism of substrate entry into the export gate, we characterized a temperature-sensitive Salmonella enterica mutant, the flhA(G368C) mutant, whose mutation blocks the flagellar protein export process at 42°C (28). We show here that this mutation severely inhibits translocation of flagellar proteins through the export gate after the FliH-FliI-FliJ complex binds to the FlhA-FlhB platform of the gate and that the impaired ability of the flhA(G368C) mutant to export flagellar proteins is restored almost to wild-type levels by intragenic second-site mutations that may alter the interactions between subdomains of FlhA_C for possible rearrangement for the export function.     

Structure of the cytoplasmic domain of FlhA and implication for flagellar type III protein export

FlhA is the largest integral membrane component of the flagellar type III protein export apparatus of Salmonella and is composed of an N‐terminal transmembrane domain (FlhA_TM) and a C‐terminal cytoplasmic domain (FlhA_C). FlhA_C is thought to form a platform of the export gate for the soluble components to bind to for efficient delivery of export substrates to the gate. Here, we report a structure of FlhA_C at 2.8 Å resolution. FlhA_C consists of four subdomains (A_CD1, A_CD2, A_CD3 and A_CD4) and a linker connecting FlhA_C to FlhA_TM. The sites of temperature‐sensitive (ts) mutations that impair protein export are distributed to all four domains, with half of them at subdomain interfaces. Analyses of the ts mutations and four suppressor mutations to the G368C ts mutation suggested that FlhA_C changes its conformation for its function. Molecular dynamics simulation demonstrated an open‐close motion with a 5–10 ns oscillation in the distance between A_CD2 and A_CD4. These results along with further mutation analyses suggest that a dynamic domain motion of FlhA_C is essential for protein export.     

Interactions among components of the Salmonella flagellar export apparatus and its substrates

We have examined the cytoplasmic components (FliH, FliI and FliJ) of the type III flagellar protein export apparatus, plus the cytoplasmic domains (FlhAC and FlhBC) of two of its six membrane components. FliH, FlhAC and FliJ, when overproduced, caused inhibition of motility of wild-type cells and inhibition of the export of substrates such as the hook protein FlgE. Co-overproduction of FliH and FliI substantially relieved the inhibition caused by FliH, suggesting that it is excess free FliH that is inhibitory and that FliH and FliI form a complex. We purified His-FLAG-tagged versions of: (i) export components FliH, FliI, FliJ, FlhAC and FlhBC; (ii) rod/hook-type export substrates FlgB (rod protein), FlgE (hook protein), FlgD (hook capping protein) and FliE (basal body protein); and (iii) filament-type export substrates FlgK and FlgL (hook-filament junction proteins) and FliC (flagellin). We tested for protein-protein interactions by affinity blotting. In many cases, a given protein interacted with more than one other component, indicating that there are likely to be multiple dynamic interactions or interactions that involve more than two components. Interactions of FlhBC with rod/hook-type substrates were strong, whereas those with filament-type substrates were very weak; this may reflect the role of FlhB in substrate specificity switching. We propose a model for the flagellar export apparatus in which FlhA and FlhB and the other four integral membrane proteins of the apparatus form a complex at the base of the flagellar motor. A soluble complex of at least three proteins (FliH, FliI and FliJ) bind the protein to be exported and then interact with the complex at the motor to deliver the protein, which is then exported in an ATP-dependent process mediated by FliI.     

Interaction between FliJ and FlhA,Components of the Bacterial Flagellar Type III Export Apparatus

A soluble protein, FliJ, along with a membrane protein, FlhA, plays a role in the energy coupling mechanism for bacterial flagellar protein export. The water-soluble FliH_X-FliI₆ ATPase ring complex allows FliJ to efficiently interact with FlhA. However, the FlhA binding site of FliJ remains unknown. Here, we carried out genetic analysis of a region formed by well-conserved residues—Gln38, Leu42, Tyr45, Tyr49, Phe72, Leu76, Ala79, and His83—of FliJ. A structural model of the FliI₆-FliJ ring complex suggests that they extend out of the FliI₆ ring. Glutathione S-transferase (GST)-FliJ inhibited the motility of and flagellar protein export by both wild-type cells and a fliH-fliI flhB(P28T) bypass mutant. Pulldown assays revealed that the reduced export activity of the export apparatus results from the binding of GST-FliJ to FlhA. The F72A and L76A mutations of FliJ significantly reduced the binding affinity of FliJ for FlhA, thereby suppressing the inhibitory effect of GST-FliJ on the protein export. The F72A and L76A mutations were tolerated in the presence of FliH and FliI but considerably reduced motility in their absence. These two mutations affected neither the interaction with FliI nor the FliI ATPase activity. These results suggest that FliJ(F72A) and FliJ(L76A) require the support of FliH and FliI to exert their export function. Therefore, we propose that the well-conserved surface of FliJ is involved in the interaction with FlhA.     

Roles of the extreme N‐terminal region of FliH for efficient localization of the FliH–FliI complex to the bacterial flagellar type III export apparatus

Most bacterial flagellar proteins are exported by the flagellar type III protein export apparatus for their self‐assembly. FliI ATPase forms a complex with its regulator FliH and facilitates initial entry of export substrates to the export gate composed of six integral membrane proteins. The FliH–FliI complex also binds to the C ring of the basal body through a FliH–FliN interaction for efficient export. However, it remains unclear how these reactions proceed within the cell. Here, we analysed subcellular localization of FliI–YFP by fluorescence microscopy. FliI–YFP was localized to the flagellar base, and its localization required both FliH and the C ring. The ATPase activity of FliI was not required for its localization. FliI–YFP formed a complex with FliHΔ1 (missing residues 2–10) but the complex did not show any localization. FliHΔ1 did not interact with FliN, and alanine‐scanning mutagenesis revealed that only Trp‐7 and Trp‐10 of FliH are essential for the interaction with FliN. Overproduction of the FliH–FliI complex improved the export activity of the fliN mutant whereas neither of the FliH(W7A)‐FliI nor FliH(W10A)‐FliI complexes did, suggesting that Trp‐7 and Trp‐10 of FliH are also required for efficient localization of the FliH–FliI complex to the export gate.     

Molecular dissection of Salmonella FliH,a regulator of the ATPase FliI and the type III flagellar protein export pathway

FliH is a soluble component of the flagellar export apparatus that binds to the ATPase FliI, and negatively regulates its activity. The 235-amino-acid FliH dimerizes and interacts with FliI to form a hetero-trimeric (FliH)2FliI complex. In the present work, the importance of different regions of FliH was examined. A set of 24 scanning deletions of 10 amino acids was constructed over the entire FliH sequence, along with several combined deletions of 40 amino acids and truncations of both N- and C-termini. The mutant proteins were examined with respect to (i) complementation; (ii) dominance and multicopy effects; (iii) interaction with wild-type FliH; (iv) interaction with FliI; (v) inhibition of the ATPase activity of FliI; and (vi) interaction with the putative general chaperone FliJ. Analysis of the deletion mutants revealed a clear functional demarcation between the FliH N- and C-terminal regions. The 10-amino-acid deletions throughout most of the N-terminal half of the sequence complemented and were not dominant, whereas those throughout most of the C-terminal half did not complement and were dominant. FliI binding was disrupted by C-terminal deletions from residue 101 onwards, indicating that the C-terminal domain of FliH is essential for interaction with FliI. FliH dimerization was abolished by deletion of residues 101-140 in the centre of the sequence, as were complementation, dominance and interaction with FliI and FliJ. The importance of this region was confirmed by the fact that fragment FliHC2 (residues 99-235) interacted with FliH and FliI, whereas fragment FliHC1 (residues 119-235) did not. FliHC2 formed a relatively unstable complex with FliI and showed biphasic regulation of ATPase activity, suggesting that the FliH N-terminus stabilizes the (FliH)2FliI complex. Several of the N-terminal deletions tested permitted close to normal ATPase activity of FliI. Deletion of the last five residues of FliH caused a fivefold activation of ATPase activity, suggesting that this region of FliH governs a switch between repression and activation of FliI. Deletion of the first 10 residues of FliH abolished complementation, severely reduced its interaction with FliJ and uncoupled its role as a FliI repressor from its other export functions. Based on these data, a model is presented for the domain construction and function of FliH in complex with FliI and FliJ.     

Interactions between C ring proteins and export apparatus components: a possible mechanism for facilitating type III protein export

The flagellar switch proteins of Salmonella, FliG, FliM and FliN, participate in the switching of motor rotation, torque generation and flagellar assembly/export. FliN has been implicated in the flagellar export process. To address this possibility, we constructed 10-amino-acid scanning deletions and larger truncations over the C-terminal domain of FliN. Except for the last deletion variant, all other variants were unable to complement a fliN null strain or to restore the export of flagellar proteins. Most of the deletions showed strong negative dominance effects on wild-type cells. FliN was found to associate with FliH, a flagellar export component that regulates the ATPase activity of FliI. The binding of FliM to FliN does not interfere with this FliN-FliH interaction. Furthermore, a five-protein complex consisting of FliG, His-tagged FliM, FliN, FliH and FliI was purified by nickel-affinity chromatography. FliJ, a putative general chaperone, is bound to FliM even in the absence of FliH. The importance of the C ring as a possible docking site for export substrates, chaperones and FliI through FliH for their efficient delivery to membrane components of the export apparatus is discussed.     

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.     

Weak Interactions between Salmonella enterica FlhB and Other Flagellar Export Apparatus Proteins Govern Type III Secretion Dynamics

The bacterial flagellum contains its own type III secretion apparatus that coordinates protein export with assembly at the distal end. While many interactions among export apparatus proteins have been reported, few have been examined with respect to the differential affinities and dynamic relationships that must govern the mechanism of export. FlhB, an integral membrane protein, plays critical roles in both export and the substrate specificity switching that occurs upon hook completion. Reported herein is the quantitative characterization of interactions between the cytoplasmic domain of FlhB (FlhB_C) and other export apparatus proteins including FliK, FlhA_C and FliI. FliK and FlhA_C bound with micromolar affinity. K_D for FliI binding in the absence of ATP was 84 nM. ATP-induced oligomerization of FliI induced kinetic changes, stimulating fast-on, fast-off binding and lowering affinity. Full length FlhB purified under solubilizing, nondenaturing conditions formed a stable dimer via its transmembrane domain and stably bound FliH. Together, the present results support the previously hypothesized central role of FlhB and elucidate the dynamics of protein-protein interactions in type III secretion.     

The FliN-FliH interaction mediates localization of flagellar export ATPase FliI to the C ring complex

FliH regulates the flagellar export ATPase FliI, preventing nonproductive ATP hydrolysis. FliH has been shown to stably associate with the C ring protein FliN. Analysis of this complex reveals that FliH is required for FliI localization to the C ring, and thus FliH not only inhibits FliI ATPase activity but also may act to target FliI to the basal body. Quantitative binding studies revealed a KD of 110 nM for FliH binding to FliN. The KD for FliH binding of a FliN variant from a temperature-sensitive nonflagellate fliN point mutant was determined to be 270 nM, suggesting a molecular explanation for its phenotype. Another variant FliN from a temperature-sensitive mutant with a different phenotype displayed binding with an intermediate affinity. Weak export activity in a fliN null mutant was greatly increased by overproduction of FliI, mimicking a previously observed FliH bypass effect and supporting the conclusion that FliN-FliH binding is important for localization of FliI to the C ring and thus the membrane-embedded export apparatus beyond. A model incorporating the present findings is presented.     

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.     

Interaction of a bacterial flagellar chaperone FlgN with FlhA is required for efficient export of its cognate substrates

FlgN chaperone acts as a bodyguard to protect its cognate substrates, FlgK and FlgL, from proteolysis in the cytoplasm. Docking of the FlgN-FlgK complex with the FliI ATPase of the flagellar type III export apparatus is key to the protein export process. However, a ΔfliH-fliI flhB(P28T) mutant forms some flagella even in the absence of FliH and FliI, raising the question of how FlgN promotes the export of its cognate substrates. Here, we report that the interaction of FlgN with an integral membrane export protein, FlhA, is directly involved in efficient protein export. A ΔfliH-fliI flhB(P28T) ΔflgN mutant caused extragenic suppressor mutations in the C-terminal domain of FlhA (FlhA(C) ). Pull-down assays using GST affinity chromatography showed an interaction between FlgN and FlhA(C) . The FlgN-FlgK complex bound to FlhA(C) and FliJ to form the FlgN-FlgK-FliJ-FlhA(C) complex. The FlgN-FlhA(C) interaction was enhanced by FlgK but not by FliJ. FlgN120 missing the last 20 residues still bound to FlgK and FliJ but not to FlhA(C) . A highly conserved Tyr-122 residue was required for the interaction with FlhA(C) . These results suggest that FlgN efficiently transfers FlgK/L subunits to FlhA(C) to promote their export.     

Intrinsic membrane targeting of the flagellar export ATPase FliI: interaction with acidic phospholipids and FliH

The specialised ATPase FliI is central to export of flagellar axial protein subunits during flagellum assembly. We establish the normal cellular location of FliI and its regulatory accessory protein FliH in motile Salmonella typhimurium, and ascertain the regions involved in FliH(2)/FliI heterotrimerisation. Both FliI and FliH localised to the cytoplasmic membrane in the presence and in the absence of proteins making up the flagellar export machinery and basal body. Membrane association was tight, and FliI and FliH interacted with Escherichia coli phospholipids in vitro, both separately and as the preformed FliH(2)/FliI complex, in the presence or in the absence of ATP. Yeast two-hybrid analysis and pull-down assays revealed that the C-terminal half of FliH (H105-235) directs FliH homodimerisation, and interacts with the N-terminal region of FliI (I1-155), which in turn has an intra-molecular interaction with the remainder of the protein (I156-456) containing the ATPase domain. The FliH105-235 interaction with FliI was sufficient to exert the FliH-mediated down-regulation of ATPase activity. The basal ATPase activity of isolated FliI was stimulated tenfold by bacterial (acidic) phospholipids, such that activity was 100-fold higher than when bound by FliH in the absence of phospholipids. The results indicate similarities between FliI and the well-characterised SecA ATPase that energises general protein secretion. They suggest that FliI and FliH are intrinsically targeted to the inner membrane before contacting the flagellar secretion machinery, with both FliH105-235 and membrane phospholipids interacting with FliI to couple ATP hydrolysis to flagellum assembly.     

Interaction of the Extreme N-Terminal Region of FliH with FlhA Is Required for Efficient Bacterial Flagellar Protein Export

The flagellar type III protein export apparatus plays an essential role in the formation of the bacterial flagellum. FliH forms a complex along with FliI ATPase and is postulated to provide a link between FliI ring formation and flagellar protein export. Two tryptophan residues of FliH, Trp7 and Trp10, are required for the effective docking of the FliH-FliI complex to the export gate made of six membrane proteins. However, it remains unknown which export gate component interacts with these two tryptophan residues. Here, we performed targeted photo-cross-linking of the extreme N-terminal region of FliH (FliH(EN)) with its binding partners. We replaced Trp7 and Trp10 of FliH with p-benzoyl-phenylalanine (pBPA), a photo-cross-linkable unnatural amino acid, to produce FliH(W7pBPA) and FliH(W10pBPA). They were both functional and were photo-cross-linked with one of the export gate proteins, FlhA, but not with the other gate proteins, indicating that these two tryptophan residues are in close proximity to FlhA. Mutant FlhA proteins that are functional in the presence of FliH and FliI but not in their absence showed a significantly reduced function also by N-terminal FliH mutations even in the presence of FliI. We suggest that the interaction of FliH(EN) with FlhA is required for anchoring the FliI hexamer ring to the export gate for efficient flagellar protein export.     

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.     

Interactions of bacterial flagellar chaperone–substrate complexes with FlhA contribute to co‐ordinating assembly of the flagellar filament

Assembly of the bacterial flagellar filament is strictly sequential; the junction proteins, FlgK and FlgL, are assembled at the distal end of the hook prior to the FliD cap, which supports assembly of as many as 30 000 FliC molecules into the filament. Export of these proteins requires assistance of flagellar chaperones: FlgN for FlgK and FlgL, FliT for FliD and FliS for FliC. The C‐terminal cytoplasmic domain of FlhA (FlhA_C), a membrane component of the export apparatus, provides a binding‐site for these chaperone–substrate complexes but it remains unknown how it co‐ordinates flagellar protein export. Here, we report that the highly conserved hydrophobic dimple of FlhA_C is involved in the export of FlgK, FlgL, FliD and FliC but not in proteins responsible for the structure and assembly of the hook, and that the binding affinity of FlhA_C for the FlgN/FlgK complex is slightly higher than that for the FliT/FliD complex and about 14‐fold higher than that for the FliS/FliC complex, leading to the proposal that the different binding affinities of FlhA_C for these chaperone/substrate complexes may confer an advantage for the efficient formation of the junction and cap structures at the tip of the hook prior to filament formation.     

Interaction between FliI ATPase and a flagellar chaperone FliT during bacterial flagellar protein export

FliT is a flagellar type III export chaperone specific for the filament-capping protein FliD. The FliT/FliD complex binds to the FliI ATPase of the flagellar export apparatus. The C-terminal α4 helix of FliT controls its interaction with FliI but it remains unknown how it does so. Here, we analysed the FliI-FliT interaction by pull-down assays using GST affinity chromatography. FliT94, missing the C-terminal α4 helix, bound to the extreme N-terminal region of FliI (FliI(EN)) with high affinity and to the C-terminal ATPase domain (FliI(CAT)) with low affinity. The C-terminal α4 helix of FliT suppressed the interaction with FliI(EN). FliH and FliT94 bound to a common binding site on FliI(EN) and hence FliH induced the release of FliI from FliT94 in an ATP-independent manner. FliD increased the binding affinity of FliI(CAT) for FliT. These results raise a possible hypothesis that the FliH/FliI complex binds to the FliT/FliD complex through FliI(CAT) to escort it from the cytoplasm to the export gate made up of six integral membrane proteins and that, upon dissociation of FliD from FliT, FliT94 may bind to FliI(EN) and then FliI may transfer from FliT94 to FliH by the direct competition of FliT94 and FliH for FliI(EN).     

Protein export through the bacterial flagellar type III export pathway

For construction of the bacterial flagellum, which is responsible for bacterial motility, the flagellar type III export apparatus utilizes both ATP and proton motive force across the cytoplasmic membrane and exports flagellar proteins from the cytoplasm to the distal end of the nascent structure. The export apparatus consists of a membrane-embedded export gate made of FlhA, FlhB, FliO, FliP, FliQ, and FliR and a water-soluble ATPase ring complex consisting of FliH, FliI, and FliJ. FlgN, FliS, and FliT act as substrate-specific chaperones that do not only protect their cognate substrates from degradation and aggregation in the cytoplasm but also efficiently transfer the substrates to the export apparatus. The ATPase ring complex facilitates the initial entry of the substrates into the narrow pore of the export gate. The export gate by itself is a proton-protein antiporter that uses the two components of proton motive force, the electric potential difference and the proton concentration difference, for different steps of the export process. A specific interaction of FlhA with FliJ located in the center of the ATPase ring complex allows the export gate to efficiently use proton motive force to drive protein export. The ATPase ring complex couples ATP binding and hydrolysis to its assembly–disassembly cycle for rapid and efficient protein export cycle. This article is part of a Special Issue entitled: Protein trafficking and secretion in bacteria. Guest Editors: Anastassios Economou and Ross Dalbey.     

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.     

ATP-induced FliI hexamerization facilitates bacterial flagellar protein export

FliI ATPase forms a homo-hexamer to fully exert its ATPase activity, facilitating bacterial flagellar protein export. However, it remains unknown how FliI hexamerization is linked to protein export. Here, we analyzed the capability of ring formation by FliI and its catalytic mutant variants. Compared to ATP a non-hydrolysable ATP analog increased the probability of FliI hexamerization. In contrast, FliI(E221Q), which retained the affinity for ATP but has lost ATPase activity, efficiently formed the hexamer even in the presence of ATP. The mutations, which reduced the binding affinity for ATP, significantly abolished the ring formation. These results indicate that ATP-binding induces FliI hexamerization and that the release of ADP and Pi destabilizes the ring structure. FliI(E221Q) facilitated flagellar protein export in the absence of the FliH regulator of the export apparatus although not at the wild-type FliI level while the other did not. We propose that FliI couples ATP binding and hydrolysis to its assembly-disassembly cycle to efficiently initiate the flagellar protein export cycle.