The chaperone IpgC copurifies with the virulence regulator MxiE

The expression of a subset of Shigella flexneri virulence genes is dependent upon a cytoplasmic chaperone, IpgC, and an activator from the AraC/XylS family, MxiE. In this paper, we report that the chaperone forms a specific and stable heteromer with MxiE.     

The virulence plasmid pWR100 and the repertoire of proteins secreted by the type III secretion apparatus of Shigella flexneri

Bacteria of Shigella spp. are the causative agents of shigellosis. The virulence traits of these pathogens include their ability to enter into epithelial cells and induce apoptosis in macrophages. Expression of these functions requires the Mxi-Spa type III secretion apparatus and the secreted IpaA-D proteins, all of which are encoded by a virulence plasmid. In wild-type strains, the activity of the secretion apparatus is tightly regulated and induced upon contact of bacteria with epithelial cells. To investigate the repertoire of proteins secreted by Shigella flexneri in conditions of active secretion, we determined the N-terminal sequence of 14 proteins that are secreted by a mutant in which secretion was deregulated. Sequencing of the virulence plasmid pWR100 of the S. flexneri strain M90T (serotype 5) has allowed us to identify the genes encoding these secreted proteins and suggests that approximately 25 proteins are secreted by the type III secretion apparatus. Analysis of the G+C content and the relative positions of genes and open reading frames carried by the plasmid, together with information concerning the localization and function of encoded proteins, suggests that pWR100 contains blocks of genes of various origins, some of which were initially carried by four different plasmids.     

Shigella chromosomal IpaH proteins are secreted via the type III secretion system and act as effectors

Shigella possess 220 kb plasmid, and the major virulence determinants, called effectors, and the type III secretion system (TTSS) are exclusively encoded by the plasmid. The genome sequences of S. flexneri strains indicate that several ipaH family genes are located on both the plasmid and the chromosome, but whether their chromosomal IpaH cognates can be secreted from Shigella remains unknown. Here we report that S. flexneri strain, YSH6000 encodes seven ipaH cognate genes on the chromosome and that the IpaH proteins are secreted via the TTSS. The secretion kinetics of IpaH proteins by bacteria, however, showed delay compared with those of IpaB, IpaC and IpaD. Expression of the each mRNA of ipaH in Shigella was increased after bacterial entry into epithelial cells, and the IpaH proteins were secreted by intracellular bacteria. Although individual chromosomal ipaH deletion mutants showed no appreciable changes in the pathogenesis in a mouse pulmonary infection model, the DeltaipaH-null mutant, whose chromosome lacks all ipaH genes, was attenuated to mice lethality. Indeed, the histological examination for mouse lungs infected with the DeltaipaH-null showed a greater inflammatory response than induced by wild-type Shigella, suggesting that the chromosomal IpaH proteins act synergistically as effectors to modulate the host inflammatory responses.     

Characterization of the interaction partners of secreted proteins and chaperones of Shigella flexneri

The type III secretion (TTS) system of Gram-negative pathogenic bacteria is composed of proteins that assemble into the TTS machinery, proteins that are secreted by this machinery and specific chaperones that are required for storage and sometimes secretion of these proteins. Many sequential protein interactions are involved in the TTS pathway to deliver effector proteins to host cells. We used the yeast two-hybrid system to investigate the interaction partners of the Shigella flexneri effectors and chaperones. Libraries of preys containing random fusions with fragments of the TTS proteins were screened using effectors and chaperones as baits. Interactions between the effectors IpaB and IpaC and their chaperone IpgC were detected by this method, and interaction domains were identified. Using a His-tagged IpgC protein to co-purify truncated IpaB and IpaC proteins, we showed that the chaperone-binding domain was unique and located in the N-terminus of these proteins. This domain was not required for the secretion of recombinant proteins but was involved in the stability of IpaC and instability of IpaB. Homotypic interactions were identified with the baits IpaA, IpaB and IpaC. Interactions between effectors and components of the TTS machinery were also selected that might give insights into regulation of the TTS process.     

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.     

Functional conservation of the secretion and translocation machinery for virulence proteins of yersiniae, salmonellae and shigellae.

Virulent bacteria of the genera Yersinia, Shigella and Salmonella secrete a number of virulence determinants, Yops, Ipas and Sips respectively, by a type III secretion pathway. The IpaB protein of Shigella flexneri was expressed in Yersinia pseudotuberculosis and found to be secreted under the same conditions required for Yop secretion. Likewise, YopE was secreted by the wild-type strain LT2 of Salmonella typhimurium, but YopE was not secreted by the isogenic invA mutant. Secretion of both IpaB and YopE required their respective chaperones, IpgC and YerA. In addition, yopE-containing S. typhimurium expressed a YopE-mediated cytotoxicity on cultured HeLa cells. YopE was detected in the cytosol of the infected HeLa cells and the amount of translocated YopE correlated with the degree of cytotoxicity. Both translocation and cytotoxicity were prevented by the addition of gentamicin. Treatment of HeLa cells with cytochalasin D prior to infection prevented internalization of bacteria, but translocation of YopE was still observed. These results favour the hypothesis that YopE is translocated through the plasma membrane by surface-located bacteria. We propose that virulent Salmonella and Shigella deliver virulence effector molecules into the target cell through the utilization of a functionally conserved secretion/translocation machinery similar to that shown for Yersinia.     

Deoxycholate interacts with IpaD of Shigella flexneri in inducing the recruitment of IpaB to the type III secretion apparatus needle tip

Type III secretion (TTS) is an essential virulence function for Shigella flexneri that delivers effector proteins that are responsible for bacterial invasion of intestinal epithelial cells. The Shigella TTS apparatus (TTSA) consists of a basal body that spans the bacterial inner and outer membranes and a needle exposed at the pathogen surface. At the distal end of the needle is a "tip complex" composed of invasion plasmid antigen D (IpaD). IpaD not only regulates TTS, but is required for the recruitment and stable association of the translocator protein IpaB at the TTSA needle tip in the presence of deoxycholate or other bile salts. This phenomenon is not accompanied by induction of TTS or the recruitment of IpaC to the Shigella surface. We now show that IpaD specifically binds fluorescein-labeled deoxycholate and, based on energy transfer measurements and docking simulations, this interaction appears to occur where the N-terminal domain of IpaD meets its central coiled-coil, a region that may also be involved in needle-tip interactions. TTS is initiated as a series of distinct steps and that small molecules present in the bacterial milieu are capable of inducing the first step of TSS through interactions with the needle tip protein IpaD. Furthermore, the amino acids proposed to be important for deoxycholate binding by IpaD appear to have significant roles in regulating tip complex composition and pathogen entry into host cells.