Bertha González-Pedrajo

FLIK, THE PROTEIN RESPONSIBLE FOR FLAGELLAR HOOK LENGTH CONTROL IN SALMONELLA, IS EXPORTED DURING HOOK ASSEMBLY

In wild‐type Salmonella, the length of the flagellar hook, a structure consisting of subunits of the hook protein FlgE, is fairly tightly controlled at ≈ 55 nm. Because fliK mutants produce abnormally elongated hook structures that lack the filament structure, FliK appears to be involved in both the termination of hook elongation and the initiation of filament formation. FliK, a soluble protein, is believed to function together with a membrane protein, FlhB, of the export apparatus to mediate the switching of export substrate specificity (from hook protein to flagellin) upon completion of hook assembly. We have examined the location of FliK during flagellar morphogenesis. FliK was found in the culture supernatants from the wild‐type strain and from flgD (hook capping protein), flgE (hook protein) and flgK (hook‐filament junction protein) mutants, but not in that from a flgB (rod protein) mutant. The amount of FliK in the culture supernatant from the flgE mutant was much higher than in that from the flgK mutant, indicating that FliK is most efficiently exported prior to the completion of hook assembly. Export was impaired by deletions within the N‐terminal region of FliK, but not by C‐terminal truncations. A decrease in the level of exported FliK resulted in elongated hook structures, sometimes with filaments attached. Our results suggest that the export of FliK during hook assembly is important for hook‐length control and the switching of export substrate specificity.

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.

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.

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.

Role of Sex Steroid Hormones in Bacterial-Host Interactions

Sex steroid hormones play important physiological roles in reproductive and nonreproductive tissues, including immune cells. These hormones exert their functions by binding to either specific intracellular receptors that act as ligand-dependent transcription factors or membrane receptors that stimulate several signal transduction pathways. The elevated susceptibility of males to bacterial infections can be related to the usually lower immune responses presented in males as compared to females. This dimorphic sex difference is mainly due to the differential modulation of the immune system by sex steroid hormones through the control of proinflammatory and anti-inflammatory cytokines expression, as well as Toll-like receptors (TLRs) expression and antibody production. Besides, sex hormones can also affect the metabolism, growth, or virulence of pathogenic bacteria. In turn, pathogenic, microbiota, and environmental bacteria are able to metabolize and degrade steroid hormones and their related compounds. All these data suggest that sex steroid hormones play a key role in the modulation of bacterial-host interactions.

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.

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.

The muramidase EtgA from enteropathogenic Escherichia coli is required for efficient type III secretion

Enteropathogenic Escherichia coli (EPEC) is an important cause of infectious diarrhoea. It colonizes human intestinal epithelial cells by delivering effector proteins into the host cell cytoplasm via a type III secretion system (T3SS) encoded within the chromosomal locus of enterocyte effacement (LEE). The LEE pathogenicity island also encodes a lytic transglycosylase (LT) homologue named EtgA. In the present work we investigated the significance of EtgA function in type III secretion (T3S). Purified recombinant EtgA was found to have peptidoglycan lytic activity in vitro. Consistent with this function, signal peptide processing and bacterial cell fractionation revealed that EtgA is a periplasmic protein. EtgA possesses the conserved glutamate characteristic of the LT family, and we show here that it is essential for enzymic activity. Overproduction of EtgA in EPEC inhibits bacterial growth and induces cell lysis unless the predicted catalytic glutamate is mutated. An etgA mutant is attenuated for T3S, red blood cell haemolysis and EspA filamentation. BfpH, a plasmid-encoded putative LT, was not able to functionally replace EtgA. Overall, our results indicate that the muramidase activity of EtgA is not critical but makes a significant contribution to the efficiency of the T3S process.

Role of EscP (Orf16) in injectisome biogenesis and regulation of type III protein secretion in enteropathogenic Escherichia coli

Enteropathogenic Escherichia coli employs a type III secretion system (T3SS) to translocate virulence effector proteins directly into enterocyte host cells, leading to diarrheal disease. The T3SS is encoded within the chromosomal locus of enterocyte effacement (LEE). The function of some of the LEE-encoded proteins remains unknown. Here we investigated the role of the Orf16 protein in T3SS biogenesis and function. An orf16 deletion mutant showed translocator and effector protein secretion profiles different from those of wild-type cells. The orf16 null strain produced T3S structures with abnormally long needles and filaments that caused weak hemolysis of red blood cells. Furthermore, the number of fully assembled T3SSs was also reduced in the orf16 mutant, indicating that Orf16, though not essential, is required for efficient T3SS assembly. Analysis of protein secretion revealed that Orf16 is a T3SS-secreted substrate and regulates the secretion of the inner rod component EscI. Both pulldown and yeast two-hybrid assays showed that Orf16 interacts with the C-terminal domain of an inner membrane component of the secretion apparatus, EscU; the inner rod protein EscI; the needle protein EscF; and the multieffector chaperone CesT. These results suggest that Orf16 regulates needle length and, along with EscU, participates in a substrate specificity switch from early substrates to translocators. Taken together, our results suggest that Orf16 acts as a molecular measuring device in a way similar to that of members of the Yersinia YscP and flagellar FliK protein family. Therefore, we propose that this protein be renamed EscP.

Type Three Secretion System in Attaching and Effacing Pathogens

Enteropathogenic Escherichia coli and enterohemorrhagic E. coli are diarrheagenic bacterial human pathogens that cause severe gastroenteritis. These enteric pathotypes, together with the mouse pathogen Citrobacter rodentium, belong to the family of attaching and effacing pathogens that form a distinctive histological lesion in the intestinal epithelium. The virulence of these bacteria depends on a type III secretion system (T3SS), which mediates the translocation of effector proteins from the bacterial cytosol into the infected cells. The core architecture of the T3SS consists of a multi-ring basal body embedded in the bacterial membranes, a periplasmic inner rod, a transmembrane export apparatus in the inner membrane, and cytosolic components including an ATPase complex and the C-ring. In addition, two distinct hollow appendages are assembled on the extracellular face of the basal body creating a channel for protein secretion: an approximately 23 nm needle, and a filament that extends up to 600 nm. This filamentous structure allows these pathogens to get through the host cells mucus barrier. Upon contact with the target cell, a translocation pore is assembled in the host membrane through which the effector proteins are injected. Assembly of the T3SS is strictly regulated to ensure proper timing of substrate secretion. The different type III substrates coexist in the bacterial cytoplasm, and their hierarchical secretion is determined by specialized chaperones in coordination with two molecular switches and the so-called sorting platform. In this review, we present recent advances in the understanding of the T3SS in attaching and effacing pathogens.