Proteolytic cleavage of the FlhB homologue YscU of Yersinia pseudotuberculosis is essential for bacterial survival but not for type III secretion

Pathogenic Yersinia species employ a type III secretion system (TTSS) to target antihost factors, Yop proteins, into eukaryotic cells. The secretion machinery is constituted of ca. 20 Ysc proteins, nine of which show significant homology to components of the flagellar TTSS. A key event in flagellar assembly is the switch from secreting-assembling hook substrates to filament substrates, a switch regulated by FlhB and FliK. The focus of this study is the FlhB homologue YscU, a bacterial inner membrane protein with a large cytoplasmic C-terminal domain. Our results demonstrate that low levels of YscU were required for functional Yop secretion, whereas higher levels of YscU lowered both Yop secretion and expression. Like FlhB, YscU was cleaved into a 30-kDa N-terminal and a 10-kDa C-terminal part. Expression of the latter in a wild-type strain resulted in elevated Yop secretion. The site of cleavage was at a proline residue, within the strictly conserved amino acid sequence NPTH. A YscU protein with an in-frame deletion of NPTH was cleaved at a different position and was nonfunctional with respect to Yop secretion. Variants of YscU with single substitutions in the conserved NPTH sequence--i.e., N263A, P264A, or T265A--were not cleaved but retained function in Yop secretion. Elevated expression of these YscU variants did, however, result in severe growth inhibition. From this we conclude that YscU cleavage is not a prerequisite for Yop secretion but is rather required to maintain a nontoxic fold.     

Atomic resolution structure of the cytoplasmic domain of Yersinia pestis YscU,a regulatory switch involved in type III secretion

Crystal structures of cleaved and uncleaved forms of the YscU cytoplasmic domain, an essential component of the type III secretion system (T3SS) in Yersinia pestis, have been solved by single‐wavelength anomolous dispersion and refined with X‐ray diffraction data extending up to atomic resolution (1.13 Å). These crystallographic studies provide structural insights into the conformational changes induced upon auto‐cleavage of the cytoplasmic domain of YscU. The structures indicate that the cleaved fragments remain bound to each other. The conserved NPTH sequence that contains the site of the N263‐P264 peptide bond cleavage is found on a β‐turn which, upon cleavage, undergoes a major reorientation of the loop away from the catalytic N263, resulting in altered electrostatic surface features at the site of cleavage. Additionally, a significant conformational change was observed in the N‐terminal linker regions of the cleaved and noncleaved forms of YscU which may correspond to the molecular switch that influences substrate specificity. The YscU structures determined here also are in good agreement with the auto‐cleavage mechanism described for the flagellar homolog FlhB and E. coli EscU.     

Structure of the type III secretion recognition protein YscU from Yersinia enterocolitica

The inner-membrane protein YscU has an important role during the assembly of the Yersinia enterocolitica type III secretion injectisome. Its cytoplasmic domain (YscU^C) recognizes translocators as individual substrates in the export hierarchy. Activation of YscU entails autocleavage at a conserved NPTH motif. Modification of this motif markedly changes the properties of YscU, including translocator export cessation and production of longer injectisome needles. We determined the crystal structures of the uncleaved variants N263A and N263D of YscU^C at 2.05 Å and 1.55 Å resolution, respectively. The globular domain is found to consist of a central, mixed β-sheet surrounded by α-helices. The NPTH motif forms a type II β-turn connecting two β-strands. NMR analysis of cleaved and uncleaved YscU^C indicates that the global structure of the protein is retained in cleaved YscU^C. The structure of YscU^C variant N263D reveals that wild type YscU^C is poised for cleavage due to an optimal reaction geometry for nucleophilic attack of the scissile bond by the side chain of Asn263. In vivo analysis of N263Q and H266A/R314A YscU variants showed a phenotype that combines the absence of translocator secretion with normal needle-length control. Comparing the structure of YscU to those of related proteins reveals that the linker domain between the N-terminal transmembrane domain and the autocleavage domain can switch from an extended to a largely α-helical conformation, allowing for optimal positioning of the autocleavage domain during injectisome assembly.     

Characterization of soluble complexes of the Shigella flexneri type III secretion system ATPase

The conserved ATPase of type III secretion systems is critical to the export of substrates through the apparatus. We present a characterization of the native T3SS ATPase, Spa47, from the cytoplasm of Shigella flexneri, demonstrating it to be in two distinct high-molecular-weight complexes with Spa33: MxiN and MxiK.     

Secretion of early and late substrates of the type III secretion system from Xanthomonas is controlled by HpaC and the C-terminal domain of HrcU

The plant pathogenic bacterium Xanthomonas campestris pv. vesicatoria utilizes a type III secretion (T3S) system to inject effector proteins into eukaryotic cells. T3S substrate specificity is controlled by HpaC, which promotes secretion of translocon and effector proteins but prevents efficient secretion of the early substrate HrpB2. HpaC and HrpB2 interact with the C-terminal domain (HrcU(C) ) of the FlhB/YscU homologue HrcU. Here, we provide experimental evidence that HrcU is proteolytically cleaved at the conserved NPTH motif, which is required for binding of both HpaC and HrpB2 to HrcU(C) . The results of mutant studies showed that cleavage of HrcU contributes to pathogenicity and secretion of late substrates but is dispensable for secretion of HrpB2, which is presumably secreted prior to HrcU cleavage. The introduction of a point mutation (Y318D) into HrcU(C) activated secretion of late substrates in the absence of HpaC and suppressed the hpaC mutant phenotype. However, secretion of HrpB2 was unaffected by HrcU(Y318D) , suggesting that the export of early and late substrates is controlled by independent mechanisms that can be uncoupled. As HrcU(Y318D) did not interact with HrpB2 and HpaC, we propose that the substrate specificity switch leads to the release of HrcU(C) -bound HrpB2 and HpaC.     

MxiK and MxiN interact with the Spa47 ATPase and are required for transit of the needle components MxiH and MxiI,but not of Ipa proteins,through the type III secretion apparatus of Shigella flexneri

The type III secretion (TTS) pathway is used by numerous Gram-negative pathogens to inject virulence factors into eukaryotic cells. The Shigella flexneri TTS apparatus (TTSA) spans the bacterial envelope and its assembly requires the products of approximately 20 mxi and spa genes. We present a functional analysis of the mxiK, mxiN and mxiL genes. Inactivation of mxiK and mxiN, but not mxiL, resulted in the assembly of a non-functional TTSA that lacked the outer needle. The amounts of needle components MxiH and MxiI were drastically reduced in mxiK and mxiN mutants and in the secretion defective spa47 mutant, indicating that MxiH and MxiI are degraded if they do not transit through the TTSA. Remarkably, expression of MxiH-His in the mxiN mutant and MxiI-His in the mxiK mutant restored assembly of a functional TTSA, as shown by the ability of these strains to enter into epithelial cells and to secrete Ipa proteins in response to activation by Congo red. Using a two-hybrid screen in yeast and immunoprecipitation assays from S. flexneri extracts, we identified interactions between MxiK and Spa33 and Spa47 and between MxiN and Spa33 and Spa47. These results suggest that transit of the needle components MxiH and MxiI through the TTSA involves the concerted action of the cytoplasmic proteins Spa47, Spa33, MxiK and MxiN. They also show that neither MxiK nor MxiN are absolutely required for secretion of Ipa proteins, provided that the TTSA is correctly assembled.     

Spa15 of Shigella flexneri, a third type of chaperone in the type III secretion pathway

The type III secretion (TTS) pathway is used by numerous Gram-negative pathogens to inject virulence factors into eukaryotic cells. In addition to a functional TTS apparatus, secretion of effector proteins depends upon specific chaperones. Using a two-hybrid screen in yeast and a co-purification assay in Shigella flexneri, we demonstrated that Spa15, which is encoded by an operon for components of the TTS apparatus, is associated in the cytoplasm with three proteins that are secreted by the TTS pathway, IpaA, IpgB1 and OspC3. Spa15 was found to be necessary for stability of IpgB1 but not IpaA, and for secretion of IpaA molecules that were stored in the cytoplasm but not those that were synthesized while the secretion apparatus was active. The ability of Spa15 to associate with several non-homologous secreted proteins, the presence of Spa15 homologues in other TTS systems and the location of the corresponding genes within operons for components of the TTS apparatus suggest that Spa15 belongs to a new class of TTS chaperones.     

The inner rod of virulence‐associated type III secretion systems constitutes a needle adapter of one helical turn that is deeply integrated into the system's export apparatus

Type III secretion injectisomes are essential virulence factors for many pathogenic bacteria by mediating the transport of effector proteins into eukaryotic host cells. The secretion conduit of injectisomes is formed by a helical assembly of three hydrophobic proteins (SctR, SctS and SctT), an inner rod (SctI) and a needle filament (SctF). SctI is thought to play a role in switching between the secretion of different substrate classes and assembly of the inner rod has been implicated in regulating the length of the needle filament. While high‐resolution structures of the hydrophobic components and of the needle filament have been solved, little is known about the structure and the assembly of the inner rod, which impedes the deeper assessment of its function. Here we show by exhaustive in vivo photocrosslinking that SctI engages in extensive interactions with SctR and SctT throughout its entire length. Our data imply that the inner rod serves as an adapter between the export apparatus and the needle filament by forming one helical turn. We show that assembly of the inner rod does not play a role in needle length control nor in substrate specificity switching. Instead, our findings imply that inner rod assembly must precede assembly of the needle filament.     

Structure-function analysis of the HrpB2-HrcU interaction in the Xanthomonas citri type III secretion system

Bacterial type III secretion systems deliver protein virulence factors to host cells. Here we characterize the interaction between HrpB2, a small protein secreted by the Xanthomonas citri subsp. citri type III secretion system, and the cytosolic domain of the inner membrane protein HrcU, a paralog of the flagellar protein FlhB. We show that a recombinant fragment corresponding to the C-terminal cytosolic domain of HrcU produced in E. coli suffers cleavage within a conserved Asn264-Pro265-Thr266-His267 (NPTH) sequence. A recombinant HrcU cytosolic domain with N264A, P265A, T266A mutations at the cleavage site (HrcU(AAAH)) was not cleaved and interacted with HrpB2. Furthermore, a polypeptide corresponding to the sequence following the NPTH cleavage site also interacted with HrpB2 indicating that the site for interaction is located after the NPTH site. Non-polar deletion mutants of the hrcU and hrpB2 genes resulted in a total loss of pathogenicity in susceptible citrus plants and disease symptoms could be recovered by expression of HrpB2 and HrcU from extrachromossomal plasmids. Complementation of the ΔhrcU mutant with HrcU(AAAH) produced canker lesions similar to those observed when complemented with wild-type HrcU. HrpB2 secretion however, was significantly reduced in the ΔhrcU mutant complemented with HrcU(AAAH,) suggesting that an intact and cleavable NPTH site in HrcU is necessary for total functionally of T3SS in X. citri subsp. citri. Complementation of the ΔhrpB2 X. citri subsp. citri strain with a series of hrpB2 gene mutants revealed that the highly conserved HrpB2 C-terminus is essential for T3SS-dependent development of citrus canker symptoms in planta.     

Two parts of the T3S4 domain of the hook-length control protein FliK are essential for the substrate specificity switching of the flagellar type III export apparatus

The switch in export specificity of the type III flagellar protein export apparatus from rod/hook type to filament type is believed to occur upon completion of hook assembly by way of an interaction of the type III secretion substrate specificity switch (T3S4) domain of the hook-length control protein FliK, with the integral membrane export apparatus component FlhB. The T3S4 domain of FliK (FliKT3S4) consisting of amino acid residues 265-405 has an unstable and flexible conformation in its last 35 residues (FliKCT). To investigate the role of FliKT3S4 in substrate specificity switching, we studied the effect of deletions and point mutations within this domain and characterized suppressor mutations. Deletions of ten amino acid residues within the region of residues 301-350 and five amino acids of residues 401-405 abolished switching of export specificity. Site directed mutagenesis showed that highly conserved residues, Val302, Ile304, Leu335, Val401 and Ala405, are essential, and that the five C terminal residues (401-405) are restricted in conformation for the switching process. Suppressor mutant analysis of the fliK(S319Y) mutant, which produces extended hooks with filaments attached due to delayed switching, suggested that FliKT3S4 interacts with the C terminal half of the cytoplasmic domain of FlhB (FlhBC). We propose a two step binding model of FliKT3S4 and FlhBC, in which residues 301-350 of FliK bind to FlhBC upon hook assembly completion at about 55 nm, and then unfolded FliKCT binds to FlhBC to trigger the switch in substrate specificity.     

The NMR structure of FliK, the trigger for the switch of substrate specificity in the flagellar type III secretion apparatus

The flagellar cytoplasmic protein FliK controls hook elongation by two successive events: by determining hook length and by stopping the supply of hook protein. These two distinct roles are assigned to different parts of FliK: the N-terminal half (FliK_N) determines length and the C-terminal half (FliK_C) switches secretion from the hook protein to the filament protein. The interaction of FliK_C with FlhB, the switchable secretion gate, triggers the switch. By NMR spectroscopy, we demonstrated that FliK is largely unstructured and determined the structure of a compact domain in FliK_C. The compact domain, denoted the FliK_C core domain, consists of two α-helices, a β-sheet with two parallel and two antiparallel strands, and several exposed loops. Based on the functional data obtained by a series of deletion mutants of the FliK_C core domain, we constructed a model of the complex between the FliK_C core domain and FlhB_C. The model suggested that one of the FliK_C loops has a high probability of interacting with the C-terminal domain of FlhB (FlhB_C) as the FliK molecule enters the secretion gate. We suggest that the autocleaved NPTH sequence in FlhB contacts loop 2 of FliK_C to trigger the switching event. This contact is sterically prevented when NPTH is not cleaved. Thus, the structure of FliK provides insight into the mechanism by which this bifunctional protein triggers a switch in the export of substrates.     

Role of the Plasmodium Export Element in Trafficking Parasite Proteins to the Infected Erythrocyte

The intracellular survival of Plasmodium falciparum within human erythrocytes is dependent on export of parasite proteins that remodel the host cell. Most exported proteins require a conserved motif (RxLxE/Q/D), termed the Plasmodium export element (PEXEL) or vacuolar targeting sequence (VTS), for targeting beyond the parasitophorous vacuole membrane and into the host cell; however, the precise role of this motif in export is poorly defined. We used transgenic P. falciparum expressing chimeric proteins to investigate the function of the PEXEL motif for export. The PEXEL constitutes a bifunctional export motif comprising a protease recognition sequence that is cleaved, in the endoplasmic reticulum, from proteins destined for export, in a PEXEL arginine- and leucine-dependent manner. Following processing, the remaining conserved PEXEL residue is required to direct the mature protein to the host cell. Furthermore, we demonstrate that N acetylation of proteins following N-terminal processing is a PEXEL-independent process that is insufficient for correct export to the host cell. This work defines the role of each residue in the PEXEL for export into the P. falciparum -infected erythrocyte.     

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.     

YscU, a Yersinia enterocolitica inner membrane protein involved in Yop secretion.

Pathogenic yersiniae secrete antihost Yop proteins by a recently discovered secretion pathway which is also encountered in several animal and plant pathogens. The components of the export machinery are encoded by the virA (lcrA), virB (lcrB), and virC (lcrC) loci of the 70-kb pYV plasmid. In the present paper we describe yscU, the last gene of the virB locus. We determined the DNA sequence and mutated the gene on the pYV plasmid. After inactivation of yscU, the mutant strain was unable to secrete Yop proteins. The topology of YscU was investigated by the analysis of YscU-PhoA translational fusions generated by TnphoA transposition. This showed that the 40.3-kDa yscU product contains four transmembrane segments anchoring a large cytoplasmic carboxyl-terminal domain to the inner membrane. YscU is related to Spa40 from Shigella flexneri, to SpaS from Salmonella typhimurium, to FlhB from Bacillus subtilis, and to HrpN from Pseudomonas solanacearum.     

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.     

FlhB regulates ordered export of flagellar components via autocleavage mechanism

The bacterial flagellum is a predominantly cell-external super-macromolecular construction whose structural components are exported by a flagellum-specific export apparatus. One of the export apparatus proteins, FlhB, regulates the substrate specificity of the entire apparatus; i.e. it has a role in the ordered export of the two main groups of flagellar structural proteins such that the cell-proximal components (rod-/hook-type proteins) are exported before the cell-distal components (filament-type proteins). The controlled switch between these two export states is believed to be mediated by conformational changes in the structure of the C-terminal cytoplasmic domain of FlhB (FlhB(C)), which is consistently and specifically cleaved into two subdomains (FlhB(CN) and FlhB(CC)) that remain tightly associated with each other. The cleavage event has been shown to be physiologically significant for the switch. In this study, the mechanism of FlhB cleavage has been more directly analyzed. We demonstrate that cleavage occurs in a heterologous host, Saccharomyces cerevisiae, deficient in vacuolar proteinases A and B. In addition, we find that cleavage of a slow-cleaving variant, FlhB(C)(P270A), is stimulated in vitro at alkaline pH. We also show by analytical gel-filtration chromatography and analytical ultracentrifugation experiments that both FlhB(C) and FlhB(C)(P270A) are monomeric in solution, and therefore self-proteolysis is unlikely. Finally, we provide evidence via peptide analysis and FlhB cleavage variants that the tertiary structure of FlhB plays a significant role in cleavage. Based on these results, we propose that FlhB cleavage is an autocatalytic process.     

Function of the conserved FHIPEP domain of the flagellar type III export apparatus,protein FlhA

The Type III flagellar protein export apparatus of bacteria consists of five or six membrane proteins, notably FlhA, which controls the export of other proteins and is homologous to the large family of FHIPEP export proteins. FHIPEP proteins contain a highly‐conserved cytoplasmic domain. We mutagenized the cloned Salmonella flhA gene for the 692 amino acid FlhA, changing a single, conserved amino acid in the 68‐amino acid FHIPEP region. Fifty‐two mutations at 30 positions mostly led to loss of motility and total disappearance of microscopically visible flagella, also Western blot protein/protein hybridization showed no detectable export of hook protein and flagellin. There were two exceptions: a D199A mutant strain, which produced short‐stubby flagella; and a V151L mutant strain, which did not produce flagella and excreted mainly un‐polymerized hook protein. The V151L mutant strain also exported a reduced amount of hook‐cap protein FlgD, but when grown with exogenous FlgD it produced polyhooks and polyhook‐filaments. A suppressor mutant in the cytoplasmic domain of the export apparatus membrane protein FlhB rescued export of hook‐length control protein FliK and facilitated growth of full‐length flagella. These results suggested that the FHIPEP region is part of the gate regulating substrate entry into the export apparatus pore.     

Mechanism of type‐III protein secretion: Regulation of FlhA conformation by a functionally critical charged‐residue cluster

The bacterial flagellum contains a specialized secretion apparatus in its base that pumps certain protein subunits through the growing structure to their sites of installation beyond the membrane. A related apparatus functions in the injectisomes of gram‐negative pathogens to export virulence factors into host cells. This mode of protein export is termed type‐III secretion (T3S). Details of the T3S mechanism are unclear. It is energized by the proton gradient; here, a mutational approach was used to identify proton‐binding groups that might function in transport. Conserved proton‐binding residues in all the membrane components were tested. The results identify residues R147, R154 and D158 of FlhA as most critical. These lie in a small, well‐conserved cytoplasmic domain of FlhA, located between transmembrane segments 4 and 5. Two‐hybrid experiments demonstrate self‐interaction of the domain, and targeted cross‐linking indicates that it forms a multimeric array. A mutation that mimics protonation of the key acidic residue (D158N) was shown to trigger a global conformational change that affects the other, larger cytoplasmic domain that interacts with the export cargo. The results are discussed in the framework of a transport model based on proton‐actuated movements in the cytoplasmic domains of FlhA.     

HrcQ Provides a Docking Site for Early and Late Type III Secretion Substrates from Xanthomonas

Pathogenicity of many Gram-negative bacteria depends on a type III secretion (T3S) system which translocates bacterial effector proteins into eukaryotic cells. The membrane-spanning secretion apparatus is associated with a cytoplasmic ATPase complex and a predicted cytoplasmic (C) ring structure which is proposed to provide a substrate docking platform for secreted proteins. In this study, we show that the putative C ring component HrcQ from the plant pathogenic bacterium Xanthomonas campestris pv. vesicatoria is essential for bacterial pathogenicity and T3S. Fractionation studies revealed that HrcQ localizes to the cytoplasm and associates with the bacterial membranes under T3S-permissive conditions. HrcQ binds to the cytoplasmic T3S-ATPase HrcN, its predicted regulator HrcL and the cytoplasmic domains of the inner membrane proteins HrcV and HrcU. Furthermore, we observed an interaction between HrcQ and secreted proteins including early and late T3S substrates. HrcQ might therefore act as a general substrate acceptor site of the T3S system and is presumably part of a larger protein complex. Interestingly, the N-terminal export signal of the T3S substrate AvrBs3 is dispensable for the interaction with HrcQ, suggesting that binding of AvrBs3 to HrcQ occurs after its initial targeting to the T3S system.     

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.