Myosin-cross-reactive epitope of Shigella flexneri invasion plasmid antigen B.

IpaB, invasion plasmid antigen B, of Shigella flexneri is a 62-kDa protein required for invasion of intestinal epithelial cells. IpaB is also one of several major protein antigens recognized by the humoral immune systems of most humans and monkeys after infection with shigellae. Computer analysis of the deduced IpaB amino acid sequence indicates that an alpha-helical structure is likely through much of the molecule. Homology searches with protein data banks show that one alpha-helical domain between amino acid residues 95 and 181 has a moderate level of identity with myosin and streptococcal M protein. By using a monoclonal antibody (2F1) which recognizes an epitope in the amino-terminal third of the IpaB protein, it was possible to demonstrate a cross-reactive epitope(s) on skeletal muscle myosin. Epitope mapping localized the 2F1 epitope to three noncontiguous regions of the IpaB protein within the alpha-helical domain that contains homology with myosin. Antibodies produced in rabbits immunized with synthetic peptides from one of the 2F1 epitope regions (residues 99 to 110) of IpaB were capable of reacting with IpaB as well as myosin. Furthermore, sera from several monkeys previously infected with S. flexneri 2a contained antibodies to IpaB pep 101-116 (IpaB peptide 101-116) and also myosin. Sera from animals with antibodies against other IpaB peptides did not contain antibodies against myosin.     

Shigella flexneri invasion plasmid antigens B and C: epitope location and characterization with monoclonal antibodies.

Invasion plasmid antigens B (IpaB) and C (IpaC) are associated with the ability of shigellae to invade cultured mammalian cells. Monoclonal antibodies against IpaB and IpaC polypeptides were produced and used in a whole-cell enzyme-linked immunosorbent assay to show that both IpaB and IpaC polypeptides were exposed on the surface of virulent shigellae. Moreover, these surface epitopes were shown to be highly conserved among different serotypes of Shigella spp. and enteroinvasive Escherichia coli. Cross-reactive epitopes were not found on noninvasive Shigella strains or on other enteric bacteria including Salmonella, Yersinia, Campylobacter, Vibrio, and Aeromonas spp. and various pathogenic strains of E. coli. The monoclonal antibodies were used in competitive binding assays to define three unique epitopes of the IpaB polypeptide and four unique epitopes of the IpaC polypeptide. Epitope locations and their corresponding DNA-encoding regions were defined by examining the IpaB and IpaC products expressed by lambda gt11 recombinants and by constructing a genetic map of the insert DNAs of these recombinants. Three IpaB epitopes (2F1, 1H4, 4C8) were found to be encoded on three contiguous DNA regions comprising a 700-base-pair (bp) segment that corresponded to the amino-terminal end of the IpaB polypeptide. Similarly, a 640-bp DNA segment that corresponded to the amino-terminal end of the IpaC polypeptide was found to encode three clustered IpaC epitopes (5H1, 9B6, 5B1). Approximately 50 bp downstream from this region a fourth IpaC epitope-encoding region (2G2) was found. The effect of the monoclonal antibodies on plaque formation by virulent Shigella flexneri on a monolayer of cultured mammalian cells (a sensitive measure of invasiveness) was determined. Only the IpaB-specific monoclonal antibody 2F1 was able to reduce the plaque-forming capacity by greater than 50%, suggesting that this epitope of the IpaB polypeptide is involved in the invasion process.     

Loss of pigmentation in Shigella flexneri 2a is correlated with loss of virulence and virulence-associated plasmid.

In this study, we examined the relationship between the virulence of Shigella flexneri 2a and the ability of strains of S. flexneri 2a to absorb Congo red. Spontaneous nonpigmented (i.e., unable to bind Congo red [Pcr-]) derivatives of a virulent, pigmented (Pcr+) strain of S. flexneri 2a were isolated and assayed for virulence as determined by their ability to invade epithelial cells. All Pcr- mutants examined lost the ability to invade epithelial cells and were thus avirulent. Agarose gel electrophoresis of plasmid DNA from these avirulent, Pcr- mutants showed that the majority of these strains had lost a plasmid band corresponding to a virulence-associated plasmid, pSf2a140. In many of the mutants, concomitant loss of pigmentation, virulence, and pSf2a140 was accompanied by the appearance of a new plasmid, smaller than pSf2a140. We believe these new plasmids to be deletion derivatives of pSf2a140 and that loss of pigmentation and loss of virulence are associated with deletions in pSf2a140. We transduced Pcr- mutants to Pcr+ and isolated transductants which suppressed the Pcr- phenotype. None of the Pcr+ transductants regained the ability to invade epithelial cells. Several suppressors of the Pcr- phenotype were identified as mutations in cell wall biosynthesis. These results support our belief that although pigmentation is usually associated with virulence, genetic determinants unrelated to virulence can also affect the ability of the cell to bind Congo red. Therefore, the ability of S. flexneri 2a to bind Congo red does not necessarily imply the ability to invade epithelial cells. However, loss of ability to bind Congo red is accompanied by loss of virulence.     

Studies on virulence of Shigella flexneri.

The antigenic structure and some biological properties were compared in virulent S. flexneri strains of differences in: 1) antigenic composition; 2) biochemical activity; 3) sensitivity to a set of Shigella phages and 4) susceptibility to phagocytosis. The only difference found concerned the LD50 for mice; it was 10 to 100 times larger for avirulent than for virulent strains of S. flexneri. The toxic products of the strains were also compared. The lipopolisaccharide and free endotoxin purified from virulent and avirulent variants behaved similarly when tested for: LD50, pyrogenicity and the local Shwartzman reaction. A striking difference was demonstrated in the ultrastructure of lipopolisaccharide and free endotoxin isolated from virulent and avirulent variant of S. flexneri 3a.     

Complete DNA sequence and analysis of the large virulence plasmid of Shigella flexneri

The complete sequence analysis of the 210-kb Shigella flexneri 5a virulence plasmid was determined. Shigella spp. cause dysentery and diarrhea by invasion and spread through the colonic mucosa. Most of the known Shigella virulence determinants are encoded on a large plasmid that is unique to virulent strains of Shigella and enteroinvasive Escherichia coli; these known genes account for approximately 30 to 35% of the virulence plasmid. In the complete sequence of the virulence plasmid, 286 open reading frames (ORFs) were identified. An astonishing 153 (53%) of these were related to known and putative insertion sequence (IS) elements; no known bacterial plasmid has previously been described with such a high proportion of IS elements. Four new IS elements were identified. Fifty putative proteins show no significant homology to proteins of known function; of these, 18 have a G+C content of less than 40%, typical of known virulence genes on the plasmid. These 18 constitute potentially unknown virulence genes. Two alleles of shet2 and five alleles of ipaH were also identified on the plasmid. Thus, the plasmid sequence suggests a remarkable history of IS-mediated acquisition of DNA across bacterial species. The complete sequence will permit targeted characterization of potential new Shigella virulence determinants.     

Role of heat labile antigens of Shigella flexneri in HeLa cell invasion

In studies of the role of surface antigens of Shigella flexneri in HeLa cell invasion, three antisera were employed to block the invasion. Antisera against live (ALS) and boiled (ABS) S. flexneri blocked invasion very effectively. Reduction in the numbers of intracellular shigellae was always accompanied by reduction in the number adherent to the cells, indicating the importance of adhesion in the invasive process. Anti-live absorbed antiserum (ALAS) prepared by exhaustive absorption of ALS with boiled S. flexneri blocked adhesion and invasion at dilutions of 20 or 50; the efficiency of the absorption was indicated by absence of agglutinating and anti-lipopolysaccharide (LPS) antibodies. S. flexneri LPS did not block adhesion and invasion even at a concentration of 1.0 mg/ml. Hence it was concluded that heat-labile surface antigens are important in adhesion and invasion of HeLa cells by S. flexneri. Antiserum against heat stable antigen (ABS) probably blocks adhesion by steric hindrance.     

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.     

Phage conversion of Shigella flexneri group antigens.

A temperate phage, designated Sf6, has been isolated from Shigella flexneri 3a. Characterization of Sf6 revealed that it possesses the capacity for converting the S. flexneri 3,4 group antigen complex to group factor 6. Serological studies and chemical analysis of lipopolysaccharide from converted strains suggest that group factor 6 is a reflection of an acetylation of the preexisting 3,4 antigen complex. Evidence is provided that the 3,4 group antigen complex functions, at least in part, as a cell surface receptor site for Sf6 adsorption.     

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.     

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.     

Characterization of virulence plasmids and plasmid-associated outer membrane proteins in Shigella flexneri, Shigella sonnei, and Escherichia coli.

The 140-megadalton plasmids of Shigella flexneri serotypes 1, 3, and 5, in addition to the 120-megadalton plasmid of Shigella sonnei, are associated with virulence. The present study showed that a 140-megadalton plasmid is also associated with virulence in Escherichia coli. When these plasmids were cleaved with EcoRI or BamHI restriction endonucleases, considerable homology was evident in plasmids from S. sonnei strains, whereas only a few common fragments were observed among the S. flexneri and enteroinvasive E. coli plasmids. Nitrocellulose filter hybridization demonstrated that, despite variations in restriction sites, all these plasmids shared a considerable complement of homologous sequences. Minicell-producing strains were obtained by N-methyl-N'-nitro-N-nitrosoguanidine mutagenesis. Transmission electron microscopy of infected HeLa cells showed that minicells from invasive strains retained the invasive phenotype. Sixteen polypeptides were labeled when S. flexneri 5 minicells were incubated with [35S]methionine. Fourteen of these plasmid-coded polypeptides were associated with the outer membrane in invasive strains of S. flexneri 5, and nine polypeptides of similar molecular weight were labeled in the outer membrane of invasive strains of S. flexneri 3, S. sonnei, and E. coli. Seven of the S. flexneri 5 polypeptides were not labeled in a noninvasive strain which had sustained a large deletion in the virulence-associated plasmid, and none were labeled in minicells which no longer harbored this plasmid.     

Recognition of three epitopic regions on invasion plasmid antigen C by immune sera of rhesus monkeys infected with Shigella flexneri 2a.

The invasive ability of Shigella spp. is correlated with the expression of several plasmid-encoded proteins, including invasion plasmid antigen C (IpaC). By characterizing the antigenic structure of IpaC with monoclonal antibodies and convalescent-phase sera, it may be possible to determine the physical location of specific epitopes as well as the involvement of epitopes in a protective immune response or the host's susceptibility to disease. By using overlapping octameric synthetic peptides, which together represent the entire IpaC protein, the precise linear sequence of four surface-exposed epitopes was defined for four IpaC monoclonal antibodies. Furthermore, 17 unique peptide epitopes of IpaC were mapped by using 9-day-postinfection serum samples from 13 rhesus monkeys challenged with Shigella flexneri 2a. Each individual recognized a somewhat different array of IpaC peptide epitopes after infection with shigellae. However, the epitopes were clustered within three regions of the protein: region I (between amino acid residues 1 and 61), region II (between amino acid residues 177 and 258), and region III (between amino acid residues 298 and 307). Region II was recognized by 92% of S. flexneri-infected individuals and was considered to be a highly immunogenic region. Animals asymptomatic for shigellosis after challenge with S. flexneri recognized peptide epitopes within all three epitopic regions of IpaC, whereas symptomatic animals recognized peptides in only one or two of the epitopic regions. Antibody from monkeys challenged with S. sonnei recognized IpaC peptide epitopes which fell within and outside the three S. flexneri epitopic regions. While numerous potential epitopes exist on the IpaC protein, the identification of three regions in which epitopes are clustered suggests that these regions are significant with respect to the immune response and to subsequent pathogenesis postinfection.     

Molecular characterization of a trans-acting, positive effector (ipaR) of invasion plasmid antigen synthesis in Shigella flexneri serotype 5

A trans-acting, positive effector of invasion plasmid antigen (Ipa) synthesis has been identified and mapped on the pWR100 invasion plasmid of Shigella flexneri serotype 5 (strain M90T-W). Recombinant plasmids carrying this regulatory gene, designated ipaR, were found to restore full virulence to a non-invasive ipaR::Tn5 insertion mutant [M90T-W(pHS1042)] that had lost the ability to synthesize four Ipa antigens (IpaA, 70 kDa; IpaB, 62 kDa; IpaC, 42 kDa; and IpaD, 37 kDa). Genetic mapping of the ipaR gene positioned the locus on a 2.6 kb PstI-AccI fragment contained within a larger 8.0 kb EcoRI molecule that also encoded IpaD, IpaA, and two small proteins (27 kDa and 28 kDa). The trans regulatory effect of the ipaR product on ipaB, ipaC, ipaD, and ipaA expression was demonstrated by transforming compatible ipaBC, ipaDA, ipaR and ipaDAR plasmid recombinants, in various combinations, into M90T-A3, an isogenic invasion plasmid mutant of M90T-W that contained a deletion of the pWR100 ipaBCDA and ipaR loci; such transformants produced wild type levels of the IpaB, IpaC, IpaD and IpaA antigens only in the presence of IpaR+ plasmids. DNA sequence analysis of the ipaR region established that the intiation codon for ipaR is 459 bp from the 3'-end of the ipaA gene and that ipaR encodes a 309 amino acid residue protein. An interesting feature of the IpaR polypeptide was its strong sequence homology with the bacteriophage P1 partition protein ParB, consisting of a 42.8% amino acid identity over a 278 residue section of the aligned proteins.     

Isolation, characterization, and mapping of Tn5 insertions into the 140-megadalton invasion plasmid defective in the mouse Sereny test in Shigella flexneri 2a

Using Shigella flexneri 2a YSH6000, we isolated 304 independent Tn5 insertion mutants in the 230-kilobase invasion plasmid, pMYSH6000. The site of each Tn5 insertion was assigned to 23 SalI fragments on the previously made SalI cleavage map of pMYSH6000. Among the 304 insertions, 150 were negative in expression of four phenotypes examined (mouse Sereny test [Ser], invasion into epithelial cells [Inv], Congo red binding [Pcr], and inhibition of bacterial growth [Igr] ): 12 were Ser- Inv+ Pcr+ Igr+, and 142 were positive in all four phenotypes. Tn5 insertions in the avirulent mutants were distributed in two separate SalI fragments, F and G, and in four contiguous SalI fragments, B, P, H, and D. Fragment G contains a novel class of determinant(s) which is required only for Ser+ but not for Inv+, Pcr+, and Igr+. Fragment F contains the previously characterized virF locus. B, P, H, and D each contained both virulent and avirulent Tn5 insertions. This indicates that more than two gene clusters exist within this region. Both are required for expression of all four virulence phenotypes.     

Molecular alteration of the 140-megadalton plasmid associated with loss of virulence and Congo red binding activity in Shigella flexneri.

A plasmid of about 140 megadaltons has been associated with the invasiveness of Shigella flexneri. Upon subculturing in liquid media of fully virulent isolates of Shigella flexneri 2a YSH6000, which contains only a 230-kilobase-pair (kbp) plasmid in addition to 3.3- and 4.2-kbp cryptic plasmids characteristic to all S. flexneri strains, loss of invasiveness, loss of Congo red binding activity (Pcr), and complete loss of, or a deletion, or even a single-site IS insertion in the plasmid occurred simultaneously. This was ascribed to the fact that, once a noninvasive Pcr- cell has emerged, it overgrows the wild type as a consequence of its selective advantage in artificial media. A deletion map of the 230-kbp plasmid was made by analyzing SalI digests of 39 deletion derivatives plus 1 formed by insertion of an IS1-like element in independently isolated, noninvasive Pcr- mutants. Of 39 deletion derivatives, 16 belonged to a single type, and 6 belonged to another, suggesting deletion hot spots. The deletion map was confirmed and extended by analyzing 359 SalI-generated partial digests of the wild-type plasmid cloned into pBR322. Three copies of IS1-like elements were found on three different SalI fragments by Southern hybridization. Segments required for the Pcr+ phenotype seemed to occur at several different locations in the plasmid. Each of 28 representative Pcr- mutants were negative by the Sereny test. Hence, many, or possibly all, Pcr determinants were required for full virulence.     

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.     

Secretory immunoglobulin A response following peroral priming and challenge with Shigella flexneri lacking the 140-megadalton virulence plasmid

This study evaluates the ability of noninvasive Shigella spp., lacking the 140-megadalton virulence plasmid, to elicit a mucosal immunoglobulin A immune response in the intestine. For these studies, we used Shigella flexneri M4243A1 (which lacks the plasmid and is Sereny test negative) to prime and challenge three groups of rabbits perorally. Both primary and immunoglobulin A memory responses were detectable in these secretions. These findings indicate that a mucosal memory response can be primed by nonpathogenic strains of Shigella which lack the virulence plasmid.