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.

Structure and composition of the Shigella flexneri "needle complex", a part of its type III secreton.

Type III secretion systems (TTSSs or secretons), essential virulence determinants of many Gram-negative bacteria, serve to translocate proteins directly from the bacteria into the host cytoplasm. Electron microscopy (EM) indicates that the TTSSs of Shigella flexneri are composed of: (1) an external needle; (2) a transmembrane domain; and (3) a cytoplasmic bulb. EM analysis of purified and negatively stained parts 1, 2 and a portion of 3 of the TTSS, together termed the "needle complex" (NC), produced an average image at 17 A resolution in which a base, an outer ring and a needle, inserted through the ring into the base, could be discerned. This analysis and cryoEM images of NCs indicated that the needle and base contain a central 2-3 nm canal. Five major NC components, MxiD, MxiG, MxiJ, MxiH and MxiI, were identified by N-terminal sequencing. MxiG and MxiJ are predicted to be inner membrane proteins and presumably form the base. MxiD is predicted to be an outer membrane protein and to form the outer ring. MxiH and MxiI are small hydrophilic proteins. Mutants lacking either of these proteins formed needleless secretons and were unable to secrete Ipa proteins. As MxiH was present in NCs in large molar excess, we propose that it is the major needle component. MxiI may cap at the external needle tip.

Secretion of predicted Inc proteins of Chlamydia pneumoniae by a heterologous type III machinery.

Chlamydia spp. are strictly intracellular pathogens that grow inside a vacuole, called an inclusion. They possess genes encoding proteins homologous to components of type III secretion machineries, which, in other bacterial pathogens, are involved in delivery of bacterial proteins within or through the membrane of eukaryotic host cells. Inc proteins are chlamydial proteins that are associated with the inclusion membrane and are characterized by the presence of a large hydrophobic domain in their amino acid sequence. To investigate whether Inc proteins and other proteins exhibiting a similar hydropathic profile might be secreted by a type III system, we used a heterologous secretion system. Chimeras were constructed by fusing the N-terminal part of these proteins with a reporter, the Cya protein of Bordetella pertussis, and these were expressed in various strains of Shigella flexneri. We demonstrate that these hybrid proteins are secreted by the type III secretion system of S. flexneri, thereby providing evidence that IncA, IncB and IncC are secreted by a type III mechanism in chlamydiae. Moreover, we show that three other proteins from Chlamydia pneumoniae, all of which have in common the presence of a large hydrophobic domain, are also secreted by S. flexneri type III secretion machinery.

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.

IpgD, a protein secreted by the type III secretion machinery of Shigella flexneri, is chaperoned by IpgE and implicated in entry focus formation.

Invasion of epithelial cells by Shigella flexneri involves entry and intercellular dissemination. Entry of bacteria into non-phagocytic cells requires the IpaA-D proteins that are secreted by the Mxi-Spa type III secretion machinery. Type III secretion systems are found in several Gram-negative pathogens and serve to inject bacterial effector proteins directly into the cytoplasm of host cells. In this study, we have analysed the IpgD protein of S. flexneri, the gene of which is located on the virulence plasmid at the 5' end of the mxi-spa locus. We have shown that IpgD (i) is stored in the bacterial cytoplasm in association with a specific chaperone, IpgE; (ii) is secreted by the Mxi-Spa type III secretion system in amounts similar to those of the IpaA-D proteins; (iii) is associated with IpaA in the extracellular medium; and (iv) is involved in the modulation of the host cell response after contact of the bacterium with epithelial cells. This suggests that IpgD is an effector that might be injected into host cells to manipulate cellular processes during infection.

Characterization of the interaction of IpaB and IpaD, proteins required for entry of Shigella flexneri into epithelial cells, with a lipid membrane.

Entry of Shigella flexneri into epithelial cells and lysis of the phagosome involve the IpaB, IpaC, and IpaD proteins, which are secreted by type III secretion machinery. We report here the purification of IpaB and IpaD and the characterization of their lipid-binding properties as a function of pH. The interaction of IpaB with the membrane was quite independent of the pH whereas that of IpaD took place only at low pH. To support the data obtained with the purified proteins, we designed a system in which protein secretion by live bacteria was induced in the presence of liposomes, thereby allowing interaction of proteins with lipids directly after secretion and bypassing any purification step. In these conditions, both IpaB and IpaC, as well as minor amounts of IpaA and IpgD, were associated with the membrane and the ratio of IpaB to IpaC was modulated by the pH. The relevance of these results with respect to the dual roles of IpaB, IpaC and IpaD in induction of membrane ruffles and lysis of the endosomal membrane is discussed.

The development of a FACS-based strategy for the isolation of Shigella flexneri mutants that are deficient in intercellular spread.

In the disease course of bacillary dysentery, pathogenic Shigella flexneri invade colonic epithelial cells and spread both within and between host cells. The ability to spread intercellularly allows the organism to infect an entire epithelial layer without significant contact with the extracellular milieu. Using fluorescence activated cell sorter (FACS)-based technology, we developed a rapid and powerful selection strategy for the isolation of S. flexneri mutants that are unable to spread from cell to cell. The majority of mutants identified using this strategy harbour mutations that affect the structure of their lipopolysaccharide or the ability of the bacteria to move intracellularly via actin-based motility; both factors have previously been shown to be essential for cell-to-cell spread. However, using a modified strategy that eliminated both of these types of mutants, we identified several mutants that provide us with evidence that bacterial proteins of the type III secretion system, which are essential for bacterial entry into host cells, also play a role in cell-to-cell spread.

The tripartite type III secreton of Shigella flexneri inserts IpaB and IpaC into host membranes.

Bacterial type III secretion systems serve to translocate proteins into eukaryotic cells, requiring a secreton and a translocator for proteins to pass the bacterial and host membranes. We used the contact hemolytic activity of Shigella flexneri to investigate its putative translocator. Hemolysis was caused by formation of a 25-A pore within the red blood cell (RBC) membrane. Of the five proteins secreted by Shigella upon activation of its type III secretion system, only the hydrophobic IpaB and IpaC were tightly associated with RBC membranes isolated after hemolysis. Ipa protein secretion and hemolysis were kinetically coupled processes. However, Ipa protein secretion in the immediate vicinity of RBCs was not sufficient to cause hemolysis in the absence of centrifugation. Centrifugation reduced the distance between bacterial and RBC membranes beyond a critical threshold. Electron microscopy analysis indicated that secretons were constitutively assembled at 37 degrees C before any host contact. They were composed of three parts: (a) an external needle, (b) a neck domain, and (c) a large proximal bulb. Secreton morphology did not change upon activation of secretion. In mutants of some genes encoding the secretion machinery the organelle was absent, whereas ipaB and ipaC mutants displayed normal secretons.

The secreted IpaB and IpaC invasins and their cytoplasmic chaperone IpgC are required for intercellular dissemination of Shigella flexneri.

Invasion of epithelial cells by Shigella flexneri involves entry and dissemination. The main effectors of entry, IpaB and IpaC, are also required for contact haemolytic activity and escape from the phagosome in infected macrophages. These proteins are stored in the cytoplasm in association with the chaperone IpgC, before their secretion by a type III secretion apparatus is activated by host cells. We used a His-tagged IpgC protein to purify IpgC-containing complexes and showed that only IpaB and IpaC are associated with IpgC. Plasmids expressing His6-IpgC either alone or together with IpaB or IpaC under the control of an IPTG-inducible lac promoter were introduced into ipgC, ipaB or ipaC mutants. Induction of expression of the recombinant plasmid-encoded proteins by IPTG allowed bacteria to enter epithelial cells, and the role of these proteins in dissemination was investigated by incubating infected cells in either the absence or the presence of IPTG. The size of plaques produced by recombinant strains on cell monolayers was regulated by IPTG, indicating that IpgC, IpaB and IpaC were each required for efficient dissemination. Electron microscopy analysis of infected cells indicated that these proteins were necessary for lysis of the membrane of the protrusions during cell-to-cell spread.

Induction of type III secretion in Shigella flexneri is associated with differential control of transcription of genes encoding secreted proteins.

Shigella, the etiological agent of human bacillary dysentery, invades the colonic epithelium where it induces an intense inflammatory response. Entry of Shigella into epithelial cells involves a type III secretion machinery, encoded by the mxi and spa operons, and the IpaA-D secreted proteins. In this study, we have identified secreted proteins of 46 and 60 kDa as the products of virA and ipaH9.8, respectively, the latter being a member of the ipaH multigene family. Inactivation of virA did not affect entry into epithelial cells. Using lacZ transcriptional fusions, we found that transcription of virA and four ipaH genes, but not that of the ipaBCDA and mxi operons, was markedly increased during growth in the presence of Congo red and in an ipaD mutant, two conditions in which secretion through the Mxi-Spa machinery is enhanced. Transcription of the virA and ipaH genes was also transiently activated upon entry into epithelial cells. These results suggest that transcription of the virA and ipaH genes is regulated by the type III secretion machinery and that a regulatory cascade differentially controls transcription of genes encoding secreted proteins, some of which, like virA, are not required for entry.

Secretion of Ipa proteins by Shigella flexneri: inducer molecules and kinetics of activation.

The type III Mxi-Spa secretion machinery of Shigella flexneri is responsible for secretion of Ipa proteins, which are involved in the entry of bacteria into epithelial cells. Ipa proteins accumulate within bacteria growing in laboratory media, and their secretion is activated upon contact of bacteria with eukaryotic cells. In this study, we have identified a group of chemical compounds, including Congo red, Evans blue, and direct orange, which are able to induce secretion of Ipa proteins by bacteria suspended in phosphate-buffered saline. Parameters of kinetics of activation of Ipa secretion by Congo red were determined by measuring by enzyme-linked immunosorbent assay the amount of IpaC secreted and by investigating the increase in susceptibility of Ipa proteins to proteinase K degradation. Ipa secretion occurred at 37 degrees C, was obtained with 5 to 10 microM Congo red, and was complete within 30 min. In addition, activation of Ipa secretion by Congo red was observed with bacteria harvested throughout the exponential phase of growth but not with bacteria in the stationary phase. The interactions of Congo red and Congo red-related compounds with the Mxi-Spa secretion apparatus might be specific hydrophobic interactions similar to those involved in binding of Congo red to amyloid proteins.

Functional analysis of the Shigella flexneri IpaC invasin by insertional mutagenesis.

The ability of Shigella to enter epithelial cells, to escape from the phagocytic vacuole, and to induce apoptosis in macrophages requires the IpaB, IpaC, and IpaD proteins. An extracellular complex containing IpaB and IpaC can promote the uptake of inert particles by epithelial cells. To determine whether the function of IpaC is to act as an extracellular chaperone for IpaB in the Ipa complex or as an effector of entry involved in a direct interaction with the cell surface, we have constructed eight IpaC recombinant proteins by inserting the coding sequence for a 12- to 14-amino-acid fragment into restriction sites scattered within the ipaC gene. We have investigated the ability of recombinant proteins to bind IpgC in the bacterial cytoplasm and IpaB in the extracellular medium and to complement an ipaC null mutant for entry into HeLa cells, lysis of erythrocytes, and escape from the phagocytic vacuole in infected macrophages. Most recombinant proteins were produced and secreted at a level similar to that of wild-type IpaC and did not exhibit altered susceptibility to proteolysis by trypsin, and all were able to bind IpgC and IpaB. Some recombinant proteins did not complement the ipaC mutant for entry into HeLa cells, lysis of erythrocytes, or escape from the phagocytic vacuole, which indicates that IpaC plays an active role in these processes and does not act solely as a chaperone for IpaB. In addition, some insertions which were located outside of the hydrophobic region of IpaC differentially affected the abilities of Shigella to enter epithelial cells and to lyse cell membranes.

SopA, the outer membrane protease responsible for polar localization of IcsA in Shigella flexneri.

The spreading ability of Shigella flexneri, a facultative intracellular Gram-negative bacterium, within the host-cell cytoplasm is the result of directional assembly and accumulation of actin filaments at one pole of the bacterium. IcsA/VirG, the 120 kDa outer membrane protein that is required for intracellular motility, is located at the pole of the bacterium where actin polymerization occurs. Bacteria growing in laboratory media and within infected cells release a certain proportion of the surface-exposed IcsA after proteolytic cleavage. In this study, we report the characterization of the sopA gene which is located on the virulence plasmid and encodes the protein responsible for the cleavage of IcsA. The deduced amino acid sequence of SopA exhibits 60% identity with those of the OmpT and OmpP outer membrane proteases of Escherichia coli. The construction and phenotypic characterization of a sopA mutant demonstrated that SopA is required for exclusive polar localization of IcsA on the bacterial surface and proper expression of the motility phenotype in infected cells.

Purification of IpaC, a protein involved in entry of Shigella flexneri into epithelial cells and characterization of its interaction with lipid membranes.

Entry of Shigella flexneri into epithelial cells and lysis of the phagosome involve the secreted IpaA-D proteins. A complex containing IpaC and IpaB is able to promote uptake of inert particles by epithelial cells. This suggested that Ipa proteins, either individually or as a complex, might interact with the cell membrane. We have purified IpaC and demonstrated its interaction with lipid vesicles. This interaction is modulated by the pH, which might be relevant to the dual role of Ipa proteins, in induction of membrane ruffles upon entry and lysis of the endosome membrane thereafter.

Functional conservation of the Salmonella and Shigella effectors of entry into epithelial cells.

A Salmonella typhi chromosomal locus composed of five adjacent genes, designated sipEBCDA, was identified by transposon mutagenesis as being essential for cell invasion. Products of the sip genes exhibit extensive sequence similarities to the effectors of Shigella entry into epithelial cells encoded by the virulence plasmid-borne ipa operon. Expression of sipE and sipB in a Shigella non-invasive ipaB mutant restored the ability to invade epithelial cells. The structural and functional conservation of the Sip and Ipa proteins suggests that Salmonella and Shigella entry processes are promoted by similar effectors.

MxiG, a membrane protein required for secretion of Shigella spp. Ipa invasins: involvement in entry into epithelial cells and in intercellular dissemination.

Entry of Shigella flexneri into epithelial cells involves secretory proteins, the Ipa proteins, and their dedicated secretion apparatus, the Mxi-Spa translocon, which is encoded by the mxi and spa operons. We have characterized the mxiG gene that is located at the proximal part of the mxi operon. Inactivation of mxiG abolished lpa secretion, which indicates that MxiG is an essential component of the Mxi-Spa translocon. Immunoblotting analysis of membrane fractions suggests that the 42 kDa MxiG protein is associated with both the inner and outer membranes. Taking advantage of the complementation of the mxiG mutant by a plasmid carrying a wild-type copy of mxiG (which restored Ipa secretion, entry into HeLa cells, and cell-to-cell spread) we mutagenized the mxiG gene carried by the complementing plasmid to replace the RGD motif of MxiG by RAD. This mutation (mxiG*), which had no effect on the stability of the protein, did not affect Ipa secretion in vitro or entry into HeLa cells, but impaired intercellular dissemination. Therefore, MxiG and possibly proteins secreted by the Mxi-Spa translocation are involved not only in entry but also in spread of Shigella between epithelial cells.

SepA, the major extracellular protein of Shigella flexneri: autonomous secretion and involvement in tissue invasion.

In addition to Ipa proteins and IcsA, which are involved in entry into epithelial cells and intercellular spread, respectively, Shigella secretes a 110 kDa protein, designated SepA. We report the identification, cloning, and nucleotide sequence determination of the sepA gene, analysis of SepA secretion, and construction and characterization of a sepA mutant. The sepA gene is carried by the virulence plasmid and codes for a 150 kDa precursor. Upon secretion, which does not involve accessory proteins encoded by the virulence plasmid, the precursor is converted to a mature protein of 110 kDa by two cleavages removing an N-terminal signal sequence and a C-terminal fragment. Extensive similarities were detected between the sequence of the first 500 residues of mature SepA and the N-terminal region of IgA1 proteases from Neisseria gonorrhoeae and Haemophilus influenzae, the Tsh haemagglutinin of an avian pathogenic Escherichia coli, and the Hap protein involved in adhesion and penetration of H. influenzae. The C-terminal domain of the SepA precursor, which is not present in the secreted protein, exhibits sequence similarity with pertactin of Bordetella pertussis and the ring-forming protein of Helicobacter mustelae. Construction and phenotypic characterization of a sepA mutant indicated that SepA is required neither for entry into cultured epithelial cells nor for intercellular dissemination. However, in the rabbit ligated ileal loop model, the sepA mutant exhibited an attenuated virulence, which suggests that SepA might play a role in tissue invasion.

Enhanced secretion through the Shigella flexneri Mxi-Spa translocon leads to assembly of extracellular proteins into macromolecular structures.

Genes required for entry of Shigella flexneri into epithelial cells in vitro are clustered in two adjacent loci, one of which encodes secretory proteins, the IpaA-D proteins, and the other their dedicated secretion apparatus, the Mxi-Spa translocon. Ipa secretion, which is induced upon contact of bacteria with epithelial cells, is prevented during growth in vitro. Here, we show that ipaB and ipaD mutations lead to enhanced secretion of a set of about 15 proteins. These extracellular proteins and some Ipas associate in organized structures consisting of extended sheets. Growth of the wild-type strain in the presence of Congo red is shown to induce protein secretion through the Mxi-Spa translocon. Cultures grown to stationary phase in the presence of Congo red contain extracellular filaments whose composition and morphology are similar to those produced by the hypersecreting ipaB and ipaD mutants.

The secretion of the Shigella flexneri Ipa invasins is activated by epithelial cells and controlled by IpaB and IpaD.

Shigella species are enteropathogens that invade epithelial cells of the human colon. Entry into epithelial cells is triggered by the IpaB, IpaC and IpaD proteins which are translocated into the medium through the specific Mxi-Spa machinery. In vitro, Shigella cells secrete only a small fraction of the Ipa proteins, the majority of which remains in the cytoplasm. We show here that upon interaction with cultured epithelial cells or in the presence of fetal bovine serum, S.flexneri release pre-synthesized Ipa molecules from the cytoplasm into the environment. Evidence is presented that IpaB and IpaD are essential for both blocking secretion through the Mxi-Spa translocon in the absence of a secretion-inducing signal and controlling secretion of the Ipa proteins in the presence of a signal. Subcellular localization and analysis of the molecular interactions of the Ipa proteins indicate that IpaB and IpaD associate transiently in the bacterial envelope. We propose that IpaB and IpaD, by interacting in the secretion apparatus, modulate secretion.