Stress fiber-based movement of Shigella flexneri within cells.

icsA (virG), a gene located on pWR100, the virulence plasmid of Shigella flexneri serotype 5 (M90T), encodes a 120-kDa outer membrane protein. This protein promotes a random intracellular movement of the bacteria and leads to the infection of adjacent cells by the formation of protrusions. This movement, which involves the nucleation, polymerization, and subsequent polarization of actin, is referred to as the Ics phenotype (intra/intercellular spread). Here we present evidence that a second, distinct form of locomotion is also elaborated by S. flexneri in chicken embryo fibroblasts in which the Ics phenotype is not expressed. Using a combination of phase-contrast microcinematography and confocal microscopy, we have demonstrated that bacteria adopt parallel orientations by interacting with stress fibers. This interaction subsequently results in bacterial movement along the stress fibers themselves. This phenomenon occurs independently of the presence of a phagocytic vacuole which is lysed shortly after entry of the bacteria into the cell. It is expressed by M90T and SC560, its icsA mutant. This movement has been termed organelle-like movement (Olm phenotype) and is thought to account for the early accumulation of bacteria seen near the nucleus.     

Regulation of surface presentation of IcsA, a Shigella protein essential to intracellular movement and spread, is growth phase dependent.

After lysing the phagocytic vacuole, Shigella spp. accumulate filaments of polymerized actin on their surface at one pole, leading to the formation of actin tails that enable them to move through the cytoplasm. We have recently demonstrated that the Shigella protein IcsA is located at the pole that is adjacent to the growing end of the actin tail (M. B. Goldberg, O. Barzu, C. Parsot, and P. J. Sansonetti, J. Bacteriol. 175:2189-2196, 1993). Not every bacterium that is observed within the cytoplasm has an actin tail. The factors that determine when a bacterium will form a tail are unknown. Here we demonstrate that at the moment of initiation of movement, Shigella spp. are frequently in the process of division. Furthermore, the expression of IcsA on the surface of the bacteria occurs in a growth phase-dependent fashion, suggesting that the surface expression of IcsA per se determines the observed association of bacterial division with movement.     

Establishment of Unipolar Localization of IcsA in Shigella flexneri 2a Is Not Dependent on Virulence Plasmid Determinants

Unipolar localization of IcsA on the surface of Shigella flexneri is required for efficient formation of actin tails and protrusions in infected eucaryotic cells. Lipopolysaccharide (LPS) mutations have been demonstrated to affect either the establishment or the maintenance of IcsA in a unipolar location, although the mechanism is unknown. In order to analyze the contribution of virulence plasmid determinants on the unipolar localization of IcsA, we examined the localization of IcsA expressed from a cloned plasmid copy in two different genetic backgrounds. The localization of IcsA was first examined in a virulence plasmid-cured derivative of the wild-type S. flexneri 2a isolate 2457T. This approach examined the contribution of virulence plasmid-borne factors, including the previously identified virulence plasmid-borne protease that is responsible for cleaving IcsA in the outer membrane and releasing the 95-kDa secreted form from the cell surface. IcsA localization in a related but nonpathogenic Escherichia coli strain expressing LPS of the O8 serotype was also examined. IcsA surface presentation in both of these genetic backgrounds continued to be unipolar, demonstrating that virulence plasmid-borne determinants are not responsible for unipolar localization of IcsA. The unipolar localization of IcsA in the E. coli background suggests that a common pathway that allows IcsA to be spatially restricted to one pole on the bacterial cell surface exists in Shigella and E. coli.     

The actin-based motility defect of a Shigella flexneri rmlD rough LPS mutant is not due to loss of IcsA polarity

Shigella flexneri requires the outer membrane protein IcsA(VirG) and lipopolysaccharide (LPS) for efficient actin-based motility (ABM) within mammalian cells which is essential for virulence. Wild type strains of S. flexneri 2a such as 2457T have smooth LPS whose O antigen (Oag) chains have two modal lengths and IcsA predominantly located at one pole on their cell surface. In contrast, rough LPS mutants lack Oag chains, have IcsA on lateral and polar regions of the cell surface, and are defective for ABM. In this study we directly compared the phenotype of a S. flexneri producing non-IcsP/SopA cleavable IcsA (IcsA*) with that of a rough LPS mutant. IcsA* was located on lateral and polar regions of smooth LPS bacteria, and was fully functional in ABM assays (HeLa cell monolayer plaque and F-actin comet tail formation) which contrasts with the R-LPS phenotype. This indicates that loss of polar IcsA localisation in R-LPS mutants is unrelated to their ABM defect, and suggests that Oag may directly contribute to IcsA-mediated ABM.     

Lack of serologically defined arthritogenic Shigella flexneri cell envelope antigens in post-dysenteric arthritis

Post-dysenteric or reactive arthritis (ReA) is closely associated with HLA-B27. This histocompatibility antigen is heterogeneous and consists of 2 serologically defined variants: B27M1+M2+ and B27M1+M2-. This paper gives a qualitative evaluation of the antibodies present in the sera of 62 patients with dysentery due to Shigella flexneri 2a, a known arthritogenic bacterium. The patients were classified in 4 groups: B27M1+M2+ReA+ (n = 5), B27M1+M2+ReA- (n = 7); B27M1+M2-ReA- (n = 1); B27-ReA- (n = 49). The isolated infectant possessed cell envelope antigens with B27M2-like epitopes (Mr 20,000). Analysis of the spectrum of antibodies directed against the separated cell envelope antigens of S. flexneri in the sera of these patients revealed 7 main patterns of reactivity. The detectable immunogens encompassed protein stainable antigens (Mr 98, 78, 68, 54, 50, 44, 41, 35, 14 and 13 kDa), lipopolysaccharides and peptidoglycan. None of the sera possessed detectable antibodies to the B27M2-like antigen. Consequently, this antigen is unlikely to be associated with ReA, and this applies equally to other antigens or patterns of antigens. The arthritogenicity of S. flexneri may therefore not be determined by the presence or absence of detectable antibody titers to certain cell envelope antigens. We hypothesize that other properties of these antigens could be of significance.     

Intracellular spread of Shigella flexneri associated with the kcpA locus and a 140-kilodalton protein.

Escherichia coli K-12 hybrids carrying both the 220-kilobase plasmid and the purE-linked kcpA locus from Shigella flexneri expressed a 140-kilodalton (kDa) protein which was recognized by convalescent sera from monkeys infected with S. flexneri. These hybrids were tested for the ability to produce plaques in HeLa cell monolayers. Hybrid strains which carried both the 220-kilobase plasmid and the kcpA locus had a plaque-forming efficiency of at least 10(-4) PFU/CFU, whereas the plaque-forming efficiency of hybrids that carried only the shigella invasion plasmid ranged from undetectable to 10(-6). Variants were purified from the rare plaques formed by E. coli hybrids that carried only the shigella invasion plasmid. These plaque-purified strains also expressed the 140-kDa protein, and they had a plaque-forming efficiency of at least 10(-4). Transduction of the purE locus from a plaque-purified hybrid into a non-plaque-forming E. coli K-12 strain did not alter the phenotype of the recipient, but conjugation of the shigella invasion plasmid into this transductant reconstituted both expression of the 140-kDa protein and the plaque-forming phenotype. Invasive E. coli K-12 hybrids carrying only the shigella invasion plasmid remained localized within discrete areas of the HeLa cell cytoplasm, whereas hybrids that also carried the S. flexneri kcpA locus grew in a dispersed pattern throughout the host cell cytoplasm. The dispersal of these organisms was inhibited by cytochalasin D, which suggested that host cell microfilaments may play a role in the intracellular spread of enteroinvasive pathogens.     

Plasmid-associated adherence of Shigella flexneri in a HeLa cell model.

The initial interaction of Shigella flexneri with HeLa cells was studied at 4 degrees C, a temperature that inhibits parasite-directed endocytosis. It was found that invasive strains were 10-fold more adherent to HeLa cells than were isogenic, noninvasive strains which had lost a 140-megadalton plasmid. Adherent strains were also more hydrophobic than were nonadherent strains.     

Avirulence of rough mutants of Shigella flexneri: requirement of O antigen for correct unipolar localization of IcsA in the bacterial outer membrane.

Mutations in the lipopolysaccharide (LPS) of Shigella spp. result in attenuation of the bacteria in both in vitro and in vivo models of virulence, although the precise block in pathogenesis is not known. We isolated defined mutations in two genes, galU and rfe, which directly affect synthesis of the LPS of S. flexneri 2a, in order to determine more precisely the step in virulence at which LPS mutants are blocked. The galU and rfe mutants invaded HeLa cells but failed to generate the membrane protrusions (fireworks) characteristic of intracellular motility displayed by wild-type shigellae. Furthermore, the galU mutant was unable to form plaques on a confluent monolayer of eucaryotic cells and the rfe mutant generated only tiny plaques. These observations indicated that the mutants were blocked in their ability to spread from cell to cell. Western immunoblot analysis of expression of IcsA, the protein essential for intracellular motility and intercellular spread, demonstrated that both mutants synthesized IcsA, although they secreted less of the protein to the extracellular medium than did the wild-type parent. More strikingly, the LPS mutants showed aberrant surface localization of IcsA. Unlike the unipolar localization of IcsA seen in the wild-type parent, the galU mutant expressed the protein in a circumferential fashion. The rfe mutant had an intermediate phenotype in that it displayed some localization of IcsA at one pole while also showing diffuse localization around the bacterium. Given the known structures of the LPS of wild-type S. flexneri 2a, the rfe mutant, and the galU mutant, we hypothesize that the core and O-antigen components of LPS are critical elements in the correct unipolar localization of IcsA. These observations indicate a more precise role for LPS in Shigella pathogenesis.     

Involvement of a plasmid in the invasive ability of Shigella flexneri.

Representative Shigella flexneri strains were studied to determine whether plasmids are involved in their virulence. All invasive S. flexneri strains, irrespective of serotype, were found to harbor a large plasmid of approximately 140 megadaltons in size, although some strains carried additional plasmid species. Spontaneous variants of strains of serotypes 1, 2, and 5 had lost this 140-megadalton plasmid and had concomitantly become avirulent, i.e., could neither invade HeLa cell monolayers nor produced keratoconjunctivitis in guinea pigs. To monitor plasmid transfer, the 140-megadalton plasmid of strain M90T (serotype 5) was tagged with the kanamycin resistance transposon Tn5. This tagged plasmid, pWR110, was not self-transmissible, but was mobilized by one of several different conjugative plasmids into avirulent derivatives of the heterologous serotypes 1 and 2 which had lost the comparable large plasmid. Transconjugants of both serotypes which had received pWR110 regained virulence. These data directly demonstrate that this large S. flexneri plasmid encodes or regulates some function(s) required for epithelial cell penetration.     

Virulent Shigella flexneri causes damage to mitochondria and triggers necrosis in infected human monocyte-derived macrophages

Shigella flexneri is a gram-negative bacterium that causes bacillary dysentery in humans that is characterized by an acute inflammatory response of the colon. The fate of phagocytes that are infected in vitro with virulent Shigella has been the subject of some investigation and debate. In this study we found that virulent Shigella caused a rapid increase in the cell membrane permeability of infected human monocyte-derived macrophages (HMDM) but not in the cell membrane permeability of monocytes, as demonstrated by the uptake of fluorescent vital dyes. Within 2 h of infection, 59% +/- 6% of the HMDM and 相似文献   

Identification and characterization of B-cell epitopes of IpaC, an invasion-associated protein of Shigella flexneri.

Invasion plasmid antigen C (IpaC) is a 43-kDa plasmid-encoded protein associated with the ability of shigellae to invade epithelial cells. This protein is consistently strongly recognized by sera from convalescent patients and monkeys experimentally infected with shigellae. The strong immunogenicity of IpaC in the course of natural infection makes it a good candidate as a potentially protective antigen. To map the B-cell epitopes of this protein, the gene encoding IpaC was cloned and expressed at a high level in Escherichia coli. The partially purified recombinant protein was used to raise rabbit polyclonal antisera and murine monoclonal antibodies. A lambda gt11 ipaC gene library was screened with the antisera and antibodies. Recombinant DNA clones producing specific antigenic determinants were isolated, and the sequence of their DNA inserts was determined. The amino acid sequence of each determinant was deduced from the minimal overlap of DNA inserts of multiple antibody-positive DNA clones. Two distinct epitopes, located between amino acid residues 25 and 33 and 90 and 97, were identified. Two additional B-cell epitopes which were located between residues 297 and 349, near the carboxy-terminal end of the protein, were characterized. Each of these epitopes was also recognized by sera from convalescent humans and monkeys. Therefore, it seems likely that these epitopes are relevant to the humoral response against IpaC during natural infection.     

Immunogenicity and efficacy of oral or intranasal Shigella flexneri 2a and Shigella sonnei proteosome-lipopolysaccharide vaccines in animal models.

Immunity against shigellosis has been shown to correlate with the presence of antibodies specific for Shigella lipopolysaccharide (LPS). We here propose a new candidate vaccine for shigellosis composed of purified Shigella flexneri 2a or Shigella sonnei LPS hydrophobically complexed with group C type 2b Neisseria meningitidis outer membrane protein proteosomes. Immunization of mice either orally or intranasally with this complex induced specific homologous anti-LPS antibodies in both intestinal and respiratory secretions as well as in sera. Strong anamnestic responses were found after two or three immunizations. LPS alone, alkaline-detoxified LPS, or alkaline-detoxified LPS complexed with proteosomes was not effective. Oral or intranasal immunization of guinea pigs with two or more doses of this proteosome-LPS vaccine elicited homologous protection against Shigella keratoconjunctivitis (Serény test). These data demonstrate that proteosomes can be used as an effective mucosal vaccine delivery system and that orally or intranasally administered acellular vaccines can protect against Shigella infections.     

Immunochemical characteristics of Shigella sonnei and serotype 6 Shigella flexneri lipopolysaccharides and enterobacterial common antigen.

Immunochemical studies on Shigella sonnei and serotype 6 Shigella flexneri 0 antigens (lipopolysaccharides) and enterobacterial common antigen (ECA) isolated from Shigella sonnei were carried out. Oligosaccharide structure of 0-specific chain of serotype 6 Shigella fiexneri lipopolysaccharide was defined and beta-L-rhamnosyl-1,3-N-acetyl-D-galactosamin as immunodeterminant of type VI specificity was recognized. The structures of core regions of lipopolysaccharides isolated from R mutants of both Shigella subgroups were established. On the base of the serological and structural results it has been suggested that these core regions are identical and very close to RI core structure of E. coli C. The effective method of isolation and purification of enterobacterial common antigen from Shigella sonnei was elaborated and its immunological properties as well as chemical character defined.     

Use of monoclonal antibodies to type Shigella flexneri in Bangladesh.

A panel of 10 mouse and rat monoclonal antibodies specific for different type- and group-specific O-antigenic determinants of Shigella flexneri lipopolysaccharide was used to serotype 240 isolates of S. flexneri from Bangladesh. Three immunoglobulin M antibodies were used in a direct slide agglutination test; seven immunoglobulin G antibodies were absorbed to Staphylococcus aureus and used in a coagglutination assay. All but 13 of the isolates could be serotyped by using the monclonal antibodies. The six most common serotypes were (in descending order) 2a, 2b, Y (E1037), 1a, 3a, and 1b and accounted for more than 80% of all isolates. Two of the nontypable strains were found to be of a new provisional serotype of S. flexneri (T. Wehler and N.I.A. Carlin, Eur. J. Biochem. 176:471-476, 1988). The 11 remaining strains were found to be rough and therefore nontypable. The serotyping scheme based on the panel of monoclonal antibodies is specific and holds the potential to be developed into a useful tool for epidemiological investigation. The study also demonstrates that the recently described E1037 antigen is commonly found among at least four serotypes (4a, 6, X, and Y) of S. flexneri.     

Adhesion of Shigella dysenteriae type 1 and Shigella flexneri to guinea-pig colonic epithelial cells in vitro.

Adhesion of bacteria to guinea-pig colonic epithelial cells in vitro was inhibited by fucose with all the four strains tested (two of Shigella dysenteriae type 1 and two of S. flexneri). N-acetyl neuraminic acid and N-acetyl mannosamine also caused inhibition, suggesting a multiplicity of receptors on the epithelial cell. Congo-red binding of the strains correlated with their adhesive ability, whereas haemagglutination of rabbit erythrocytes by the bacteria did not.     

Regulation of virulence gene expression in Shigella flexneri, a facultative intracellular pathogen.

Shigella flexneri and its close relatives are facultative intracellular pathogens of humans and are the etiological agents of bacillary dysentery. These bacteria secrete proteins that enable them to enter human epithelial cells via an elaborate and fascinating cell biology. This behaviour depends on a complicated regulon of virulence genes, whose expression is controlled in response to a multiplicity of environmental signals. This review describes and attempts to interpret these gene control mechanisms.     

A model of interaction between Entamoeba histolytica and Shigella flexneri.

The establishment of a relationship between Entamoeba histolytica and certain bacteria may contribute to the expression and/or enhancement of the pathogenicity of this parasite. Recent experiments have shown that bacteria expressing mannose-binding lectins on their surface could attach to mannose-containing molecules on the surface of amoebae. In this study, we established a model of interaction between. E. histolytica and Shigella flexneri. Using well-characterized mutants of S. flexneri, we studied the role of type I pili expression and the invasive phenotype of S. flexneri in the interaction between amoebae and the bacteria. Type I pili expression allowed attachment and subsequent internalization of S. flexneri by amoebae, these events were not observed in isogenic strains that did not express type I pili. Invasive as well as non-invasive variants of S. flexneri expressing type I pili were slowly digested by amoebae following internalization. Morphological studies showed that the specific features of the interaction depend on the dynamics of the distribution of mannose residues on the amoebic membrane during the interaction.     

Congo red-mediated regulation of levels of Shigella flexneri 2a membrane proteins.

The ability of Shigella spp. to bind Congo red from agar medium is generally correlated with their virulence properties. We used a metabolically active culture of Shigella flexneri 2a to determine the effect of Congo red on its membrane protein profiles. Virulent S. flexneri grown in the presence of Congo red at 37 degrees C showed increased levels of three proteins with Mrs of 43,000, 58,000, and 63,000 (43K, 58K, and 63K proteins) in the Sarkosyl-soluble membrane fractions. The observed phenomenon was temperature dependent. At 30 or 42 degrees C the protein levels remained unaffected by the presence of Congo red. Similar regulation of the levels of the 43K, 58K, and 63K membrane proteins was also observed with Shigella dysenteriae 1 and enteroinvasive Escherichia coli, but not with enteropathogenic E. coli. The cellular uptake of Congo red seemed to be essential, but not sufficient, for regulation. All three proteins reacted with human convalescent-phase sera in immunoblots of S. flexneri 2a Sarkosyl-soluble membrane fractions. Using the 43K-specific antiserum as the primary antibody, by indirect immunofluorescence studies, we detected an increase in the level of the 43K protein in S. flexneri which had invaded epithelial cells. These observations strongly indicate that the 43K, 58K, and 63K proteins are virulence associated. We propose that the observed regulatory effect of Congo red on membrane proteins of S. flexneri is mediated through induction. Since the same regulatory effect was also observed during the invasion of epithelial cells by S. flexneri, it is suggested that Congo red mimics some host tissue factor in vitro.