Plaque formation by virulent Shigella flexneri.

An in vitro tissue culture plaque assay was developed to investigate the intracellular replication and intercellular spread of virulent shigellae. Shigella plaques were formed in HeLa cell monolayers in the presence of an agarose overlay containing tissue culture medium and gentamicin, which eliminated extracellular bacterial growth. Microscopically, the plaques were characterized by a central area of dead host cells surrounded by cells infected with shigellae. Cells further away from the plaque center were uninfected. Inclusion of chloramphenicol or nalidixic acid in the overlay completely abolished plaque formation. Plaque formation was completely inhibited when infected monolayers were shifted from 37 to 30 degrees C. Shifting infected monolayers from 30 degrees C, where plaques do not form, to 37 degrees C resulted in the formation of plaques. Cultures of Shigella boydii, Shigella sonnei (form I), and all six serotypes of Shigella flexneri produced plaques. Shigellae isolated from plaques were Sereny test positive, contained a 140-megadalton plasmid, and were gentamicin sensitive. Noninvasive shigellae did not form plaques.     

Identification of regions on a 230-kilobase plasmid from enteroinvasive Escherichia coli that are required for entry into HEp-2 cells.

Certain strains of Escherichia coli can cause an invasive diarrheal disease in humans which clinically resembles shigellosis. These strains share with Shigella species the ability to enter and replicate within colonic epithelial cells and the ability to bind Congo red dye in vitro when grown at 37 degrees C. Like shigellae, they contain a large plasmid essential for virulence. A 230-kilobase (kb) plasmid from enteroinvasive E. coli was genetically marked with a transposon and mobilized into an E. coli K-12 background. This plasmid conferred upon E. coli K-12 the ability to enter and multiply within cultured epithelial cells, as well as the ability to bind Congo red. Expression of these phenotypes required growth at 37 degrees C. Transposon mutagenesis was used to identify regions on the 230-kb plasmid required for virulence. All transposon insertions which resulted in loss of the ability to enter epithelial cells, as well as the ability to bind Congo red dye, were mapped to a single 25-kb BamHI fragment. Subclones from this 25-kb region were tested for the ability to complement invasion in noninvasive derivatives. A subclone containing about 8 kb of the left end of the 25-kb BamHI fragment was capable of complementing noninvasive mutants with Tn5 insertions in this region and restored to these noninvasive mutants the ability to enter epithelial cells.     

Identification of Shigella invasion genes by isolation of temperature-regulated inv::lacZ operon fusions.

Penetration and multiplication within cells of the human colonic epithelium are hallmarks of Shigella spp. pathogenicity. Shigella spp. virulence is regulated by growth temperature. Strains phenotypically virulent when grown at 37 degrees C are phenotypically avirulent when grown at 30 degrees C. The number of genes involved in Shigella spp. pathogenicity and how many virulence genes are temperature regulated are unknown. To facilitate the study of temperature-regulated virulence in Shigella spp., we employed lacZ operon fusion technology to identify temperature-regulated invasion (inv) genes. Four inv::lacZ fusion mutants were identified and found to be unable to invade HeLa cells. The fusions were located in a region of the 220-kilobase invasion plasmid defined as the minimal amount of DNA required for invasion, and they were controlled by virR, the temperature-dependent virulence gene regulator. Western blot (immunoblot) and Southern hybridization analyses indicated that one of the fusions was located in a known inv gene, ipaB, which encodes one of the major immunogenic peptides of Shigella spp. This ipaB::lacZ operon fusion mutant synthesized a truncated IpaB protein recognized by IpaB-specific monoclonal antibodies. Three of the fusions were within novel genes mapping to regions previously identified as essential for a positive virulence phenotype. Analysis of bacterial surface proteins suggested that the genes marked by these fusions may play a role in the correct surface expression of the ipaB and ipaC gene products.     

Lack of correlation between haemagglutination and adherence to epithelial cells in Yersinia pseudotuberculosis

Yersinia pseudotuberculosis was examined for its haemagglutinating activity and adherence to cultured epithelial cells (HEp-2) in relation to possession of a virulence (VW) plasmid and to growth conditions. VW-lacking (VW-) bacteria were isolated from ten VW+ strains of each serovar which, after they were grown on CFA plates at 37 degrees C, agglutinated the erythrocytes from five different species. In contrast to the bacteria possessing the plasmid (VW+) half of the VW- bacteria, grown on CFA plates at 37 degrees C, did not agglutinate any of the erythrocytes used and the other half agglutinated only human erythrocytes. Furthermore, when grown on CFA plates at 25 degrees C, neither VW+ nor VW- bacteria showed a haemagglutinating activity. When the bacteria were grown in CFA broth, only two strains grown at 25 degrees C did not agglutinate any of the erythrocytes tested. The VW+ and VW- bacteria of the remaining strains, grown either at 25 degrees C or 37 degrees C, showed relatively high haemagglutinating activity. Adherence to HEp-2 cells did not correlate with haemagglutinating activity in Y. pseudotuberculosis; the VW+ bacteria grown at 37 degrees C adhered to HEp-2 cells more efficiently than either the VW- derivatives or the VW+ bacteria grown at 25 degrees C, regardless of the growth medium. These results indicate that some of the haemagglutinins detected on Y. pseudotuberculosis are not involved in the adherence to HEp-2 cells.     

Plasmid-mediated and temperature-regulated surface properties of Yersinia enterocolitica.

Enteropathogenic strains of Yersinia enterocolitica harbor a virulence plasmid which codes for a series of novel outer membrane proteins. The expression of these proteins on the outer membrane is temperature regulated: when cells are grown at 25 degrees C, these proteins are not exposed on the outer membrane, whereas they occur in high copy number when cells are grown at 37 degrees C. The majority of these proteins are externally exposed on the cell surface as evidenced by their susceptibility to proteolysis by exogenously added proteases. The expression of the plasmid-mediated proteins on the outer membrane does not favor adherence of the bacteria to intestinal epithelial cells in vitro. Cultures grown at 25 degrees C adhered to Henle cell monolayers, whereas those grown at 37 degrees C did so much less effectively. The presence of the proteins on the bacterial surface appears to be involved in rendering the cells resistant to the bactericidal effects of serum, i.e., 37 degrees C-grown cells were resistant to serum killing, and removal of the outer membrane proteins with pronase rendered them sensitive. Evidence is presented which strongly suggests that the plasmid-mediated proteins are synthesized and expressed on the cell surface either during or after transit of the ingested bacteria to the lamina propria. Some properties afforded to the cells by the outer membrane proteins are described.     

Surface properties of Yersinia species and epithelial cell interactions in vitro by a method measuring total associated, attached and intracellular bacteria

A procedure was developed for enumeration of total associated, attached and intracellular bacteria after interaction of Yersinia spp. with epithelial cells in vitro. Isogenic cultures of Y. enterocolitica grown at 25 degrees C had greater affinity for epithelial cells (Henle, HeLa and Vero) than for polystyrene, and they invaded the cells. Y. kristenseni and Y. intermedia showed less attachment to either surface and were non-invasive. The degree of attachment to cells and invasion by Y. enterocolitica was related to number of bacteria added and interaction time, whereas attachment to polystyrene occurred rapidly and did not change. Y. enterocolitica was more hydrophobic when grown at 35 degrees C than at 25 degrees C according to partitioning in a biphasic dextran-polyethylene glycol system, and attached strongly to both polystyrene and epithelial-cell monolayers. Y. kristenseni grown at 25 degrees C was also hydrophobic but did not have the same attachment properties. Y. kristenseni and Y. intermedia showed slightly reduced electrostatic interactions with the anion exchangers DEAE-Sepharose and DEAE-Trisacryl. Attachment of Y. enterocolitica to epithelial cells probably involves non-specific surface properties that are not entirely explicable by hydrophobic and electrostatic interactions, whereas invasion of epithelial cells appears to resemble "receptor-mediated endocytosis".     

HeLa cell invasiveness and O antigen of Shigella flexneri as separate and prerequisite attributes of virulence to evoke keratoconjunctivitis in guinea pigs.

Many rough mutants selected from isogenic smooth virulent and avirulent strains of Shigella flexneri were examined for virulence, using tissue culture infection and Sereny tests. Many of the rough mutants isolated from a virulent smooth strain were capable of penetrating tissue culture cells but incapable of producing a positive Sereny test. In contrast, we could not obtain from smooth avirulent strains any rough mutants capable of penetrating HeLa cells. Chemical analysis of lipopolysaccharide of some representative rough strains showed several patterns of sugar composition with a range of from Ra to Re chemotypes. There was no correlation between HeLa cell invasiveness and chemotypes of lipopolysaccharides, thus indicating little significance of oligosaccharides of the rough core as well as O antigens in the ability of S. flexneri to penetrate HeLa cells. When these invasive rough strains were given O antigen genes from a smooth avirulent Shigella Hfr strain, most of the transconjugants that expressed O antigens regained the ability to evoke keratoconjunctivitis in guinea pigs. We also examined the chromosomal loci of HeLa cell invasion by transferring carbohydrate fermentation genes of Escherichia coli K-12 Hfr and found two chromosomal loci, the rha and lac-gal regions, which control the ability to penetrate HeLa cells. These results suggested that O antigens and ability to penetrate tissue culture cells are independent and prerequisite attributes of virulence in Shigella flexneri to evoke keratoconjunctivitis in guinea pigs.     

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.     

Quantitation of HeLa cell monolayer invasion by Shigella and Salmonella species.

A major determinant in the virulence of Salmonella and Shigella spp. is the ability of these organisms to invade epithelial cells of the gastrointestinal mucosa and multiply intracellularly. The invasion of cell culture monolayers is a convenient experimental system to evaluate eucaryotic cell penetration and is correlated with the potential of a strain to cause human disease. We have developed an agarose-L agar overlay technique which allows for the convenient quantitation of the number of infected tissue culture cells in a monolayer. Bacterial strains were introduced onto antibiotic-free HeLa cell monolayers. Infected monolayers were washed, and noninternalized bacteria were counterselected with kanamycin (50 micrograms/ml). The number of infected HeLa cells present was determined by overlaying the monolayer with distilled water-agarose (0.5 to 1.5%) followed by an equal volume of 2X L agar. Bacterial colonies formed over infected cells in 24 h at 37 degrees C, and wells were counted with a dissecting microscope under X2 power. Bacterial colonies were not observed with noninvasive variants of Shigella spp. To obtain countable wells (20 to 200 CFU) the multiplicity of infection or invasion times were adjusted. With a 90-min invasion time, the invasive potential of a strain was reflected by the multiplicity of infection needed to produce countable wells. The quantitation of bacterium-invaded cells by using standard bacteriological methods is a convenient and rapid method to evaluate the invasive potential of bacterial strains. Additionally, parameters essential for the invasive process can easily be investigated.     

Bacteriophage Mu d1(Apr lac) generates vir-lac operon fusions in Shigella flexneri 2a.

Previous studies have demonstrated that expression of virulence in Shigella spp. is controlled by growth temperature. To study the regulation of virulence (vir) genes, we set out to develop a rapid, easily-assayed phenotype with which to measure expression of virulence. This report described a procedure for isolating vir-lac operon fusions in S. flexneri 2a by using the specialized transducing bacteriophage Mu d1(Apr lac) of Casadaban and Cohen (M. Casadaban and S. N. Cohen, Proc. Natl. Acad. Sci. U.S.A. 76:4530-4533, 1976). Mu d1(Apr lac) lysogens were isolated and screened for loss of virulence and for temperature-dependent expression of the lactose genes on Mu d1(Apr lac). A recombinant plasmid carrying the Mu immunity gene was also introduced into lysogens of interest to stabilize the Mu d1(Apr lac) insertion and prevent possible thermal induction at 37 degrees C. The mutant which we isolated failed to penetrate tissue culture cells in the assay for virulence and produced almost 15-fold more beta-galactosidase when grown at 37 degrees C than when grown at 30 degrees C. The site of insertion of Mu d1(Apr lac) in this strain was shown to be in the 140-megadalton plasmid pSf2a140, which is known to be associated with virulence. P1L4-mediated transduction of the insertion into a virulent recipient demonstrated genetic linkage of Mu d1(Apr lac) with loss of virulence and temperature-dependent expression of beta-galactosidase. All of these features fulfill the phenotype expected for a Mu d1(Apr lac)-induced vir-lac operon fusion. This mutant provides us with a means of measuring expression of a gene function required for virulence by assaying for beta-galactosidase. The insertion will also serve as a starting point for mapping of genes on pSf2a140 which are necessary for expression of virulence.     

Expression of Campylobacter jejuni invasiveness in cell cultures coinfected with other bacteria.

Enteroinvasive Salmonella, Shigella, and Escherichia coli strains were found to exert an effect which rendered Campylobacter jejuni capable of intracellular localization in epithelial cells in vitro. When monolayers of HEp-2 or A-549 cells were challenged with pure cultures of C. jejuni or Campylobacter coli, none of the eight strains tested invaded the cells. In contrast, four of these strains were able to localize intracellularly when the cells were challenged with a mixture of campylobacters and enteroinvasive Salmonella typhimurium, Shigella flexneri, Shigella boydii, Shigella sonnei, or E. coli strains. Invasiveness of campylobacters was also induced by one nonenteroinvasive strain of E. coli O124. Coinfection with other nonenteroinvasive E. coli strains did not induce invasiveness in C. jejuni. The degree of internalization induced by S. typhimurium was significantly higher than that induced by Shigella or E. coli strains. The invasive capacity of C. jejuni was found to differ considerably between strains. No evidence of an invasive potential was demonstrable for two C. coli strains or for two enterotoxigenic isolates of C. jejuni examined. C. jejuni was only able to localize intracellularly in cell cultures when the interaction occurred in a microaerobic atmosphere. None of the strains tested evoked keratoconjunctivitis in guinea pig eyes (Sereny test), regardless of the presence of coinfectants. The results indicate that a synergistic interaction that exists between C. jejuni and other enteropathogens facilitates invasion by C. jejuni.     

Shigella Infection of Henle Intestinal Epithelial Cells: Role of the Host Cell

The process of Henle 407 embryonic intestinal epithelial cell infection by Shigella flexneri 2a M42-43 was studied in an in vitro model system. The role of the Henle cell was assessed. It was established that entry of S. flexneri into cells was suppressed by reagents which inhibit uptake of particles by phagocytic cells. The compounds tested included cytochalasin B, dibutyryl-cyclic adenosine monophosphate, choleragen (Vibrio cholera enterotoxin), iodoacetate, and dinitrophenol. Cytochalasin B inhibited infection at concentrations of 1.0 mug/ml or greater. Dibutyryl-cyclic adenosine monophosphate at concentrations of 1 mM and choleragen at 0.1 mug/ml caused significant suppression of infection. Iodoacetate or dinitrophenol, at 0.1 mM concentrations, inhibited internalization of virulent shigellae, and a combination of these compounds inhibited infection at 0.01 mM concentrations. Preincubation of Henle cell monolayers with the combination of iodoacetate and dinitrophenol (0.05 mM) also inhibited infection markedly. The data suggest that infection of epithelial cells by S. flexneri in vitro is accomplished by an endocytic process induced by virulent bacteria. The process appears to be similar to uptake of particles by phagocytic cells. Ultrastructural analysis by transmission electron microscopy provided corroborative evidence of phagocytosis of shigellae by Henle cells in that intracellular bacteria were often observed within membrane-limiting vacuoles resembling phagosomes.     

Use of Shigella flexneri ipaC and ipaH gene sequences for the general identification of Shigella spp. and enteroinvasive Escherichia coli.

The products of the ipaB, ipaC, and ipaD genes are involved in the expression of the invasive phenotype in all species of Shigella and enteroinvasive Escherichia coli (EIEC). DNA probes derived from these genes are accurate indicators of the invasive phenotype (M. Venkatesan, J. M. Buysse, E. V. Vandendries, and D. J. Kopecko, J. Clin. Microbiol. 26:261-266, 1988); however, spontaneous loss of the invasion plasmid or selective deletion of invasion-associated genes may restrict the usefulness of such probes as general diagnostic tools. In this study, we report that laboratory-passaged strains of Shigella spp. and EIEC that were invasion and Sereny test negative were unable to hybridize to the ipaC DNA probe. However, a second DNA probe, derived from the Shigella flexneri ipaH gene, a multiple-copy element found on the chromosome and invasion plasmid that encodes a 60-kilodalton antigen, was more sensitive in its ability to detect virulent as well as avirulent shigellae and EIEC. Analysis of colony blots and stool blots from pediatric patients with diarrhea indicated that the ipaH probe was more effective in detecting shigellae and EIEC than was either the ipaC or 17-kilobase EcoRI fragment probe.     

Determinants for thermoinducible cell binding and plasmid-encoded cellular penetration detected in the absence of the Yersinia pseudotuberculosis invasin protein.

Yersinia pseudotuberculosis inv mutants were analyzed for their ability to bind and penetrate mammalian cell lines. Strains defective for the production of invasin and cured of the Yersinia virulence plasmid pIB1 were extremely defective for entry into the HEp-2 cell line. inv strains harboring the virulence plasmid partially overcame this defect, indicating that the virulence plasmid mediates an invasin-independent pathway for low-level entry into cultured cells. Plasmid-cured inv mutants were able to attach efficiently to mammalian cells after bacterial culture at 37 degrees C but not after culture at a lower temperature. The enhanced cellular binding of inv mutants grown at 37 degrees C did not result in efficient cellular penetration, indicating that invasin-mediated entry is the primary chromosomally encoded pathway responsible for Y. pseudotuberculosis penetration into both HEp-2 and Chinese hamster ovary cells under the assay conditions described here.     

Influence of osmolarity on lipopolysaccharides and virulence of Aeromonas hydrophila serotype O:34 strains grown at 37 degrees C.

Growth of Aeromonas hydrophila serotype O:34 strains at 37 degrees C at low and high osmolarity resulted in changes in the lipopolysaccharide (LPS) and virulence of the strains tested. We previously described the effect of growth temperature on LPS and virulence of these strains (S. Merino et al., Infect. Immun. 60:4343-4349, 1992). The effect of osmolarity can be observed when the cells grow at 37 degrees C but not when they grow at 20 degrees C. Purified LPS from cells cultivated at 37 degrees C and high osmolarity was smooth, while the LPS extracted from the cells cultivated at low osmolarity was rough. Furthermore, the strains were more virulent for fish and mice when they were grown at high osmolarity than when they were grown at low osmolarity and also showed increased extracellular activities when they were grown at high osmolarity. Finally, cells grown at high osmolarity showed better adhesion to HEp-2 cells than the same cells grown at low osmolarity, and furthermore the cells grown at high osmolarity were resistant to the bactericidal activity of nonimmune serum, while the same cells grown at low osmolarity were sensitive.     

OmpC is involved in invasion of epithelial cells by Shigella flexneri.

Osmoregulation of the Shigella flexneri ompC gene and the role of OmpC in Shigella virulence have been investigated. OmpC was highly expressed when bacteria were grown in medium of either low or high osmolarity. This constitutive expression is in contrast with the regulation observed in Escherichia coli, in which the expression of OmpC is repressed at low osmolarity and induced at high osmolarity. In addition, the Shigella ompC gene was barely expressed by a delta ompB (delta ompR and delta envZ) mutant. We described in a previous report that such a mutant was severely impaired in virulence both in vitro and in vivo. Starting from this observation, and in order to assess which gene(s) regulated by ompR and envZ are involved in virulence, we constructed an S. flexneri delta ompC mutant. Three S. flexneri mutants, ompF'-lacZ, delta ompC, and delta ompB, were compared for virulence. The ompF'lacZ mutant behaved like the S. flexneri serotype 5 wild-type strain M90T in all in vitro and in vivo virulence tests. On the contrary, the delta ompB and delta ompC strains were considerably impaired in their virulence phenotypes. The ability of these two mutants to spread from cell to cell and to kill epithelial cells was severely affected. Consequently delta ompC, as previously described for delta ompB, was unable to elicit a positive Sereny test. The delta ompB mutant was restored to virulence by introducing a recombinant multicopy plasmid carrying the cloned E. coli ompC gene, indicating that a functional OmpC protein was necessary and sufficient to restore virulence to this mutant of S. flexneri.     

Distribution of the invA, -B, -C, and -D genes of Salmonella typhimurium among other Salmonella serovars: invA mutants of Salmonella typhi are deficient for entry into mammalian cells.

Invasion of intestinal epithelial cells is an essential virulence factor of salmonellae. A group of genes, invABC and invD, that allow Salmonella typhimurium to penetrate cultured epithelial cells have previously been characterized (J. E. Galán and R. Curtiss III, Proc. Natl. Acad. Sci. USA 86:6383-6387, 1989). The distribution of these genes among Salmonella isolates belonging to 37 different species or serovars was investigated by Southern and colony blot hybridization analyses. Regions of high sequence similarity to the invABC genes were present in all Salonella isolates examined, while regions of sequence similarity to the invD gene were present in all but one (S. arizonae) of the isolates tested, with little restriction fragment length polymorphism. Sequences similar to these genes were not detected in strains of Escherichia coli, Yersinia spp., or Shigella spp. invA mutants (unable to express the invABC genes) of several Salmonella species or serovars, including S. typhi, were constructed and examined for their ability to penetrate Henle-407 cells. All mutants were deficient for entry into cultured epithelial cells, indicating that the invABC genes were not only present in these strains but also functional.     

Cloning of plasmid DNA sequences involved in invasion of HeLa cells by Shigella flexneri.

A large plasmid is found in virulent isolates of Shigella sp. and encodes functions essential for invasion of mammalian cells. To identify plasmid sequences necessary for invasion, we isolated a series of Tn5 insertions in pWR100, the virulence plasmid of Shigella flexneri serotype 5. These insertions demonstrated that three separate EcoRI fragments of pWR100 were required for invasion of HeLa cells. However, the corresponding native EcoRI fragments, when cloned into pBR325, did not restore virulence to plasmidless strains. Construction of a lambda-sensitive, plasmidless Shigella recipient enabled us to shotgun clone plasmid DNA directly into S. flexneri by using the cosmid vector pJB8 and score for expression of invasive functions. In this fashion, we succeeded in isolating six independent recombinants which restored invasion of HeLa cells in plasmidless Shigella recipients. The cloned inserts all contained a common core of ca. 37 kilobases, thus defining a minimum sequence necessary for invasion of HeLa cells. Virulence-associated peptides produced by wild-type S. flexneri were also produced by the recombinants. Expression of these peptides and expression of invasiveness by the clones were regulated by growth temperature, as is expression of these traits in wild-type S. flexneri. A complete invasive phenotype was not expressed by the recombinants in that they failed to produce a positive Sereny test. Possible explanations for this behavior as it relates to the mechanism of bacterial invasion are discussed.     

Intercellular spread of Shigella flexneri through a monolayer mediated by membranous protrusions and associated with reorganization of the cytoskeletal protein vinculin.

The spread of Shigella flexneri in a monolayer of infected Henle and HeLa cells was studied by using immunofluorescence and electron microscopy. Infected cells produced numerous bacterium-containing membranous protrusions up to 18 microns in length that penetrated adjacent cells and were subsequently phagocytosed. Fluorescence staining of actin and vinculin in infected cells with phalloidin and monoclonal antibody to vinculin, respectively, demonstrated that the protrusions containing the bacteria consisted of these cytoskeletal proteins. Actin accumulated predominantly at the poles of bacteria distal to the tip of protrusions and appeared as trails extending back towards the host cell cytoplasm. Vinculin, however, was distributed uniformly around the bacteria and throughout the protrusion. A profound rearrangement of vinculin occurred in Henle and HeLa cells following infection with shigellae: whereas in uninfected cells it was distributed mainly around the cell periphery, in infected cells it concentrated mainly around clusters of bacteria in the cytoplasm. This suggests a possible involvement of the vinculin cytoskeletal protein in the intercellular spread of shigellae during an infection.