Identification of an essential virulence region on Salmonella plasmids

The ADP-Ribosylating Toxins of Salmonella

A number of pathogenic bacteria utilize toxins to mediate disease in a susceptible host. The foodborne pathogen Salmonella is one of the most important and well-studied bacterial pathogens. Recently, whole genome sequence characterizations revealed the presence of multiple novel ADP-ribosylating toxins encoded by a variety of Salmonella serovars. In this review, we discuss both the classical (SpvB) and novel (typhoid toxin, ArtAB, and SboC/SeoC) ADP-ribosylating toxins of Salmonella, including the structure and function of these toxins and our current understanding of their contributions to virulence.

A subset of Actinobacillus pleuropneumoniae in vivo induced promoters respond to branched-chain amino acid limitation

Actinobacillus pleuropneumoniae is the causative agent of a necrotizing hemorrhagic pleuropneumonia in swine. In this study, we investigate the possibility that the limitation of branched-chain amino acids is a stimulus that A. pleuropneumoniae will encounter during infection and will respond to by up-regulation of genes involved in branched-chain amino acid biosynthesis and virulence. Actinobacillus pleuropneumoniae genetic loci that are specifically induced during infection were screened in vitro for expression in response to limitation of branched-chain amino acids. Of 32 in vivo induced promoter clones screened in vitro, eight were induced on chemically defined medium without isoleucine, leucine and valine as compared to complete chemically defined medium. We identify the genomic context of each clone and discuss its relevance to branched-chain amino acid limitation and virulence. We conclude that limitation of branched-chain amino acids is a cue for expression of a subset in vivo induced genes, including not only genes involved in the biosynthesis of branched-chain amino acids, but also other genes that are induced during infection of the natural host. These results suggest that limitation of branched-chain amino acids may be one of an array of environmental cues responsible for the induction of virulence-associated genes in A. pleuropneumoniae.

Differences in the carriage and the ability to utilize the serotype associated virulence plasmid in strains of Salmonella enterica serotype Typhimurium investigated by use of a self-transferable virulence plasmid, pOG669

Most strains of Salmonella enterica subspecies enterica serotype typhimurium (S. typhimurium) naturally harbour a virulence plasmid which carries the salmonella plasmid virulence (spv) genes. However, isolates belonging to certain phage types are generally found without the plasmid. We have utilized a self-transferable virulence plasmid, pOG669 to investigate the effect of introduction of spv genes into strains of such phage types. The use of the co-integrate plasmid, pOG669, was validated on a diverse collection of strains. pOG669 was transferred into strains of serotypes that are normally associated with the possession of virulence plasmids. All strains maintained the wild type level of virulence in a mouse model, except that introduction of pOG669 restored normal virulence levels in an avirulent, plasmid free strain of S. dublin and resulted in a decrease in virulence in a strain of S. dublin from clonal line Du3. S. gallinarum did not become virulent in mice, but pOG669 was functionally interchangeable with the wild type plasmid when strains were tested in a chicken model. Strains of serotypes not normally associated with the carriage of a virulence plasmid did not increase in virulence upon the introduction of pOG669. An IncX plasmid pOG670 that was included as control was incompatible with the virulence plasmid in a strain of S. dublin, demonstrating that the common virulence plasmid of this serotype is of a different incompatibility group than other virulence plasmids. Strains of S. typhimurium from phage types that do not normally carry a virulence plasmid responded differently to attempts to introduce pOG669. No transconjugants were observed with the strains of DT5 and DT21. The introduction of pOG669 did not alter the virulence of JEO3942(DT10), DT35 and JEO3949(DT66) significantly, while DT1 and DT27 became more virulent. DT27 became as virulent as wild type C5, while logVC(10) of DT1 only increased from 4.1 to 5.7. The ability to express spv-genes was measured by use of an spvRAB'-cat fusion. Expression in S. enteritidis was found to be higher than in other serotypes tested. Only serotypes that naturally carry a virulence plasmid expressed spv-genes. The strain of DT1 expressed spv at a very low level, while expression in the strains of DT10 and DT35 was approximately 2-fold lower than in a control strain of S. typhimurium, while the level in the DT66 strain corresponded to the control strain. The plasmid pSTF9, which carried the fusion gene could not be introduced into the strains of DT5, DT21 and DT27. The RpoS level in the strains was measured indirectly by use of a katE-lacZ fusion. In the DT5 strain the level of expression was low, while the strains JEO3942(DT10), DT21, DT27 and DT35 expressed 4-5 fold the level in this strain. An internal fragment of the rpoS gene was sequenced in three strains. These all showed an identical sequence to a published S. typhimurium rpoS gene.

55 kb plasmid and virulence-associated genes are positively correlated with Salmonella enteritidis pathogenicity in mice and chickens

Twenty-four strains of Salmonella enteritidis, isolated from several outbreaks of salmonellosis from different poultry farms in India, were checked for the plasmid profile and detection of virulence gene(s) by PCR. Most of the strains contained only a single plasmid of 55 kb. Additional plasmids of 23.2 kb and 8.7 kb were seen in one of the strains, and another strain carried only two plasmids of 23.2 kb and 8.7 kb. Four strains did not carry any plasmid. PCR amplification showed the presence of virulence-associated genes in all the isolates harbouring the 55 kb plasmid. Intraperitoneal inoculation of mice, with most of the strains carrying the 55 kb plasmid, caused 100% mortality. Most strains lacking the 55 kb plasmid were avirulent. In chickens, oral inoculation of the S. enteritidis strains carrying the 55 kb plasmid produced 40-100% mortality, with characteristic signs of salmonellosis. Oral inoculation of strains lacking the 55 kb plasmid did not cause any mortality. Hence, it appears that the large plasmid of S. enteritidis probably contributes towards virulence in mice and chickens.

Intracellular expression of the Salmonella plasmid virulence protein, SpvB, causes apoptotic cell death in eukaryotic cells

The spv genes carried on the Salmonella virulence plasmid are commonly associated with severe systemic infection in experimental animals. The SpvB virulence-associated protein has been shown to ADP-ribosylate actin, and this enzymatic activity is essential for virulence in mice. Here, we present evidence that intracellular expression of SpvB protein induces not only disruption of actin filaments but also apoptotic cell death in eukaryotic cells.

Characterization of a pore-forming cytotoxin expressed by Salmonella enterica serovars typhi and paratyphi A

Cytolysin A (ClyA) is a pore-forming cytotoxic protein encoded by the clyA gene that has been characterized so far only in Escherichia coli. Using DNA sequence analysis and PCR, we established that clyA is conserved in the human-specific typhoid Salmonella enterica serovars Typhi and Paratyphi A and that the entire clyA gene locus is absent in many other S. enterica serovars, including Typhimurium. The gene products, designated ClyA(STy) and ClyA(SPa), show >/=90% amino acid identity to E. coli cytolysin A, ClyA(EC), and they are immunogenically related. The Salmonella proteins showed a pore-forming activity and are hence functional homologues to ClyA(EC). The chromosomal clyA(STy) gene locus was expressed at detectable levels in the serovar Typhi strains S2369/96 and S1112/97. Furthermore, in the serovar Typhi vaccine strain Ty21a, expression of clyA(STy) reached phenotypic levels, as detected on blood agar plates. The hemolytic phenotype was abolished by the introduction of an in-frame deletion in the clyA(STy) chromosomal locus of Ty21a. Transcomplementation of the mutant with a cloned clyA(STy) gene restored the hemolytic phenotype. To our knowledge, Ty21a is the first reported phenotypically hemolytic Salmonella strain in which the genetic determinant has been identified.

Effect of constitutively expressed phoP gene on the localization of Salmonella typhimurium within Mac-1 positive phagocytes

Intracellular localization of the wild-type (Spv+), the phoP-constitutively expressed strain (PhoPc), and the spv-deleted strain (Spv-) of Salmonella typhimurium was examined by the use of confocal laser scanning microscopy analysis of immunostained sections of mouse spleens after oral or subcutaneous inoculation. Only 40% of salmonellae of both the PhoPc and the Spv- strains were detected intracellularly within Mac-1 positive cells at day five after oral or day four after subcutaneous inoculation. In contrast, over 85% of salmonellae of the Spv+ strain were detected inside Mac-1 positive cells. In both inoculation trials, the splenic colony-forming unit values for the PhoPc and Spv- strains were significantly lower than the corresponding value for the Spv+ strain. These findings suggest that the constitutively expressed phoP gene of S. typhimurium attenuated virulence by limiting intracellular proliferation within mouse spleen phagocytes, and that the lack of spv genes had the same effect.

Virulence plasmid-borne spvB and spvC genes can replace the 90-kilobase plasmid in conferring virulence to Salmonella enterica serovar Typhimurium in subcutaneously inoculated mice

In a mouse model of systemic infection, the spv genes carried on the Salmonella enterica serovar Typhimurium virulence plasmid increase the replication rate of salmonellae in host cells of the reticuloendothelial system, most likely within macrophages. A nonpolar deletion in the spvB gene greatly decreased virulence but could not be complemented by spvB alone. However, a low-copy-number plasmid expressing spvBC from a constitutive lacUV5 promoter did complement the spvB deletion. By examining a series of spv mutations and cloned spv sequences, we deduced that spvB and spvC could be sufficient to confer plasmid-mediated virulence to S. enterica serovar Typhimurium. The spvBC-bearing plasmid was capable of replacing all of the spv genes, as well as the entire virulence plasmid, of serovar Typhimurium for causing systemic infection in BALB/c mice after subcutaneous, but not oral, inoculation. A point mutation in the spvBC plasmid preventing translation but not transcription of spvC eliminated the ability of the plasmid to confer virulence. Therefore, it appears that both spvB and spvC encode the principal effector factors for Spv- and plasmid-mediated virulence of serovar Typhimurium.

Constitutively expressed phoP inhibits mouse-virulence of Salmonella typhimurium in an Spv-dependent manner

In Salmonella typhimurium, the transcription of several virulence genes including spvB is regulated by the PhoP/PhoQ regulatory system. To further examine the relationship between the PhoP/PhoQ and Spv systems for virulence in mice, we examined a non-polar phoP mutation combined with different virulence plasmid genotypes for effects on virulence of S. typhimurium in the mouse model. PhoP-/Spv+ and PhoP-/Spv- mutants were not detectably recovered from the spleens of subcutaneously or orally inoculated mice. The phoP gene constitutively expressed from the lacZ promoter of a low copy number vector (phoP(C)) only partially complemented the non-polar phoP mutation for mouse-virulence in both the Spv+ and Spv- backgrounds; both PhoP(C) strains exhibited virulence equal only to a PhoP+/Spv- strain. Interestingly, in a PhoP+ background, the phoP(C) gene reduced splenic infection of the Spv+ but not Spv- salmonellae after subcutaneous or oral inoculation compared with the PhoP+ parents. Additionally, the phoP(C) gene in an Spv+ background reduced the net growth of salmonellae in macrophages in vitro; phoP(C) in an Spv- background was without effect. These data suggest that the constitutive expression of the phoP gene attenuates the virulence of S. typhimurium in mice in an Spv-dependent manner.

Actin is ADP-ribosylated by the Salmonella enterica virulence-associated protein SpvB

The Salmonella enterica virulence-associated protein SpvB was recently shown to contain a carboxy-terminal mono(ADP-ribosyl)transferase domain. We demonstrate here that the catalytic domain of SpvB as well bacterial extracts containing full-length SpvB modifies a 43 kDa protein from macrophage-like J774-A.1 and epithelial MDCK cells as shown by label transfer from [32P]-nicotinamide adenine dinucleotide (NAD) to the 43 kDa protein. When analysed by two-dimensional gel electrophoresis, the same protein was modified in cells infected with S. enterica serovariant Dublin strain SH9325, whereas infection with an isogenic spvB mutant strain did not result in modification. Immunoprecipitation and immunoblotting experiments using SH9325-infected cells identified the modified protein as actin. The isolated catalytic domain of SpvB mediated transfer of 32P from [32P]-NAD to actins from various sources in vitro, whereas isolated eukaryotic control proteins or bacterial proteins were not modified. In an in vitro actin polymerization assay, the isolated catalytic SpvB domain prevented the conversion of G actin into F actin. Microscopic examination of MDCK cells infected with SH9325 revealed morphological changes and loss of filamentous actin content, whereas cells infected with the spvB mutant remained virtually unaffected. We conclude that actin is a target for an SpvB-mediated modification, most probably ADP-ribosylation, and that the modification of G actin interferes with actin polymerization.

The spvB gene-product of the Salmonella enterica virulence plasmid is a mono(ADP-ribosyl)transferase

A number of well-known bacterial toxins ADP-ribosylate and thereby inactivate target proteins in their animal hosts. Recently, several vertebrate ecto-enzymes (ART1-ART7) with activities similar to bacterial toxins have also been cloned. We show here that PSIBLAST, a position-specific-iterative database search program, faithfully connects all known vertebrate ecto-mono(ADP-ribosyl)transferases (mADPRTs) with most of the known bacterial mADPRTs. Intriguingly, no matches were found in the available public genome sequences of archaeabacteria, the yeast Saccharomyces cerevisiae or the nematode Caenorhabditis elegans. Significant new matches detected by PSIBLAST from the public sequence data bases included only one open reading frame (ORF) of previously unknown function: the spvB gene contained in the virulence plasmids of Salmonella enterica. Structure predictions of SpvB indicated that it is composed of a C-terminal ADP-ribosyltransferase domain fused via a poly proline stretch to a N-domain resembling the N-domain of the secretory toxin TcaC from nematode-infecting enterobacteria. We produced the predicted catalytic domain of SpvB as a recombinant fusion protein and demonstrate that it, indeed, acts as an ADP-ribosyltransferase. Our findings underscore the power of the PSIBLAST program for the discovery of new family members in genome databases. Moreover, they open a new avenue of investigation regarding salmonella pathogenesis.

Inhibition of Salmonella typhimurium invasion by host cell expression of secreted bacterial invasion proteins

Pathogenic Salmonella species initiate infection of a host by inducing their own uptake into intestinal epithelial cells. An invasive phenotype is conferred to this pathogen by a number of proteins that are components of a type III secretion system. During the invasion process, the bacteria utilize this secretion system to release proteins that enter the host cell and apparently interact with unknown host cell components that induce alterations in the actin cytoskeleton. To investigate the role of secreted proteins as direct modulators of invasion, we have evaluated the ability of Salmonella typhimurium to enter mammalian cells that express portions of the Salmonella invasion proteins SipB and SipC. Plasma membrane localization of SipB and SipC was achieved by fusing carboxyl- and amino-terminal portions of each invasion protein to the intracellular carboxyl-terminal tail of a membrane-bound eukaryotic receptor. Expression of receptor chimeras possessing the carboxyl terminus of SipB or the amino terminus of SipC blocked Salmonella invasion, whereas expression of their chimeric counterparts had no effect on invasion. The effect on invasion was specific for Salmonella since the perturbation of uptake was not extended to other invasive bacterial species. These results suggest that Salmonella invasion can be competitively inhibited by preventing the intracellular effects of SipB or SipC. In addition, these experiments provide a model for examining interactions between bacterial invasion proteins and their host cell targets.

Identification of a pathogenicity island required for Salmonella enteropathogenicity

Salmonella spp. interact with ileal mucosa and disrupt normal intestinal function, which results in an acute inflammatory cell influx, fluid secretion and enteritis. We have recently characterized SopB, a novel secreted effector protein of Salmonella dublin, and presented evidence that SopB is translocated into eukaryotic cells via a sip-dependent pathway to promote fluid secretion and inflammatory responses. Here, we show that sopB is located on a large DNA fragment unique to the Salmonella chromosome. This locus is conserved in Salmonella and maps at approximately 20 centisome of the S. typhimurium chromosome. Sequence analysis revealed that this Salmonella-specific DNA fragment is flanked by DNA sequences with significant sequence similarity to the Escherichia coli K-12 genes, tRNA1ser (serT) on one side and copS/copR on the other. Thus, this Salmonella-specific DNA fragment has features characteristic of 'pathogenicity islands' and, therefore, it was denoted SPI-5 (Salmonella pathogenicity island-5). SPI-5 was sequenced and was found to contain five novel genes, pipA, pipB, pipC, pipD (pathogenicity island-encoded proteins) and orf, in addition to sopB. The effect of mutations in pipA, pipB and pipD on the induction of fluid secretion and an acute inflammatory cell influx was assessed in bovine ligated ileal loops. The effect of mutations in SPI-5-encoded genes on systemic salmonellosis was assessed in mice. The results of these experiments suggest that SPI-5-encoded genes contribute to enteric but not to systemic salmonellosis.

Study of the role of the htrB gene in Salmonella typhimurium virulence

We have undertaken a study to investigate the contribution of the htrB gene to the virulence of pathogenic Salmonella typhimurium. An htrB::mini-Tn10 mutation from Escherichia coli was transferred by transduction to the mouse-virulent strain S. typhimurium SL1344 to create an htrB mutant. The S. typhimurium htrB mutant was inoculated into mice and found to be severely limited in its ability to colonize organs of the lymphatic system and to cause systemic disease in mice. A variety of experiments were performed to determine the possible reasons for this loss of virulence. Serum killing assays revealed that the S. typhimurium htrB mutant was as resistant to killing by complement as the wild-type strain. However, macrophage survival assays revealed that the S. typhimurium htrB mutant was more sensitive to the intracellular environment of murine macrophages than the wild-type strain. In addition, the bioactivity of the lipopolysaccharide (LPS) of the htrB mutant was reduced compared to that of the LPS from the parent strain as measured by both a Limulus amoebocyte lysate endotoxin quantitation assay and a tumor necrosis factor alpha bioassay. These results indicate that the htrB gene plays a role in the virulence of S. typhimurium.

Role of sigma factor RpoS in initial stages of Salmonella typhimurium infection

The sigma factor RpoS mediates the stationary-phase expression of a large group of genes, including those involved in resistance to a variety of environmental stresses, such as starvation, oxidation, and low pH. In addition, RpoS has been shown to regulate Salmonella virulence. In Salmonella typhimurium, RpoS controls the expression of the Salmonella plasmid virulence (spv) genes, which are required for systemic infection. However, the mechanism by which RpoS affects the pathogenicity of Salmonella remains incompletely defined. In this study, we focused on the ability of rpoS to affect the early stages of the infection process of S. typhimurium. An rpoS mutant of S. typhimurium exhibited wild-type abilities to attach to and invade Int-407 cells and J774 macrophage-like cells. In addition, rpoS did not affect the intracellular survival of S. typhimurium in either J774 macrophage-like cells or rat bone marrow-derived macrophages. However, the rpoS mutant demonstrated a decreased ability to colonize murine Peyer's patches after oral inoculation than its wild-type virulent parent strain showed. In addition, virulence plasmid-cured derivatives of the rpoS mutant were recovered in lower numbers from murine Peyer's patches than were plasmid-cured derivatives of the isogenic wild-type S. typhimurium. This indicates that RpoS regulation of chromosomally encoded genes is important for colonization of the gut-associated lymphoid tissue (GALT) by S. typhimurium. Microscopic analysis of histological sections taken from Peyer's patches after peroral infection of mice showed that, unlike its wild-type virulent parent strain, the isogenic rpoS mutant did not destroy the follicle-associated epithelium of the GALT. Furthermore, the rpoS mutant demonstrated a decreased ability to adhere to histological sections of murine Peyer's patches than its wild-type parent showed. Our data provide evidence for a role of RpoS in the interaction of Salmonella with cells of the GALT, specifically the Peyer's patches. This implicates the involvement of rpoS in the initial stages of systemic infection by Salmonella as opposed to infection leading to gastroenteritis.

An altered rpoS allele contributes to the avirulence of Salmonella typhimurium LT2

Virulent Salmonella typhimurium strains differ from the attenuated laboratory strain LT2 at the rpoS locus. It was previously shown that the rpoS gene in strain LT2 contains a rare UUG start codon (I. S. Lee, J. Lin, H. K. Hall, B. Bearson, and J. W. Foster, Mol. Microbiol. 17:155-167, 1995). This difference is responsible for the inability of LT2 to display a sustained log-phase acid tolerance response. We show that the altered rpoS allele (rpoS(LT2)) also affects the stationary-phase acid tolerance response in Salmonella. By transducing the rpoS(LT2) allele into virulent strain backgrounds and crossing wild-type rpoS allele into strain LT2, we demonstrate that the rpoS(LT2) allele contributes to the attenuation of strain LT2. We examined the effect of the rpoS allele on invasion and found that the rpoS status of the cell had no effect on the ability of the strains to invade intestinal epithelial cells in tissue culture. Enumeration of bacteria from tissues of infected mice indicated that the presence of the rpoS(LT2) allele affected the ability of S. typhimurium to reach the liver and spleen and to persist in several tissues at 6 days postinfection. This is likely due, at least in part, to a decrease in spv gene expression in these mutants. We demonstrate that strains containing the rpoS(LT2) allele are not only sensitive to pH 3.0 (acid stress) but are also sensitive to the DNA-damaging agent methyl methanesulfonate. However, these strains appear to survive stationary-phase and oxidative stresses as well as strains containing a wild-type rpoS allele. Despite an increased sensitivity to acid stress and DNA damage, strains containing either an rpoS-null mutation or the rpoS(LT2) allele survived in J774 cells and bone marrow-derived macrophages as well as did otherwise isogenic strains with a wild-type rpoS allele.

Virulence determinants invA and spvC in salmonellae isolated from poultry products, wastewater, and human sources

The presence of two virulence foci, invA and spvC, in Salmonella isolates obtained from poultry, wastewater, and human sources was determined. All isolates (n = 245) were positive for the invA gene sequence. Differences in degree of invasiveness were apparent with the Madin Darby canine kidney cell line, as only 79 of 159 randomly selected isolates (49.7%) tested were invasive at > 0.1% of the inoculum. 25% were invasive between 0.1 and 1.0% of the inoculum, and 24.5% were invasive at > 1.0% of the inoculum. There was a significant correlation between degree of invasion and source from which the isolate was recovered but no correlation between geographic origin of poultry isolates and degree of invasion. Only 37 of 245 isolates (15.1%) hybridized with the spvC DNA probe. All isolates that were recovered from a commercial egg production environment and chicken eggs and whose sequences exhibited homology with the spvC gene sequence were determined to be either Salmonella enteritidis PT 23 or PT 13. The sequences of few isolates from ceca and none from wastewater or humans demonstrated homology with the spvC gene.

The Salmonella virulence plasmid enhances Salmonella-induced lysis of macrophages and influences inflammatory responses

The Salmonella dublin virulence plasmid mediates systemic infection in mice and cattle. Here, we analyze the interaction between wild-type and plasmid-cured Salmonella strains with phagocytes in vitro and in vivo. The intracellular recovery of S. dublin from murine peritoneal and bovine alveolar macrophages cultured in the presence of gentamicin in vitro was not related to virulence plasmid carriage. However, the virulence plasmid increased the lytic activity of S. dublin, Salmonella typhimurium, and Salmonella choleraesuis for resident or activated mouse peritoneal macrophages. Lysis was not mediated by spv genes and was abolished by cytochalasin D treatment. Peritoneal and splenic macrophages were isolated from mice 4 days after intraperitoneal infection with wild-type or plasmid-cured S. dublin strains. The wild-type strain was recovered in significantly higher numbers than the plasmid-cured strain. However, the intracellular killing rates of such cells cultured in vitro for both S. dublin strains were not significantly different. Four days after infection, there was a lower increase of phagocyte numbers in the peritoneal cavities and spleens of mice infected with the wild-type strain compared with the plasmid-cured strain. The virulence plasmid influenced the survival of macrophages in vitro following infection in vivo as assessed by microscopy. Cells from mice infected with the plasmid-cured strain survived better than those from mice infected with the wild-type strain. This is the first report demonstrating an effect of the virulence plasmid on the interaction of Salmonella strains with macrophages. Plasmid-mediated macrophage dysfunction could influence the recruitment and/or the activation of phagocytic cells and consequently the net growth of Salmonella strains during infection.

Salmonellosis: host immune responses and bacterial virulence determinants

The lifestyle of bacterial pathogens requires them to establish infection in the face of host immunity. Upon entering a potential host, a variety of interactions are initiated, the outcome of which depends upon a myriad of attributes of each of the participants. In this review we discuss the interactions that occur between pathogenic Salmonella species and the host immune systems, but when appropriate to broaden perspective, we have provided a general overview of the interactions between bacterial pathogens and animal hosts. Pathogenic Salmonella species possess an array of invasion genes that produce proteins secreted by a specialized type III secretion apparatus. These proteins are used by the bacteria to penetrate the intestinal mucosa by invading and destroying specialized epithelial M cells of the Peyer's patches. This maneuver deposits the bacteria directly within the confines of the reticuloendothelial system. The host responds to these actions with nonspecific phagocytic cells and an inflammatory response as well as by activating specific cellular and humoral immune responses. Salmonella responds to this show of force directly. It appears that the bacteria invade and establish a niche within the very cells that have been sent to destroy them. Efforts are underway to characterize the factors that allow these intracellular bacteria to customize intracellular vacuoles for their own purposes. It is the constant play between these interactions that determines the outcome of the host infection, and clearly they will also shape the evolution of new survival strategies for both the bacterium and the host.

The Salmonella dublin virulence plasmid does not modulate early T-cell responses in mice

The virulence plasmid in Salmonella dublin mediates systemic infection in mice and cattle. The role of gamma delta T cells or hepatic extrathymic T cells has recently been reported to be important in the control of the early stage of Salmonella choleraesuis infections of mice. Here, we report on T-cell responses in conventional mice after challenge with a virulent strain of S. dublin carrying a virulence plasmid or with a strain cured of the plasmid. Over a period of 4 days postinfection, when both strains could be compared, similar changes in alpha beta and gamma delta T-cell subsets in peritoneal cavities, livers, and spleens were recorded, demonstrating no clear role of the virulence plasmid in modulation of early T-cell responses. To investigate further the role of the virulence plasmid in pathogenesis, the growth of the plasmid-cured strain was assessed in SCID, SCID bg, and irradiated mice. During the first 6 days after infection, there was no statistically difference in the net growth of Salmonella cells in the livers and spleens of SCID and SCID bg mice compared with conventional BALB/mice. This observation excludes a key role for a T- or B-cell-mediated immune response in controlling the initial growth of the plasmid-cured S. dublin strain. Thereafter, the immunocompromised mice were no longer able to control infection, although SCID mice were more efficient at controlling net bacterial multiplication than SCID bg mice, potentially implicating NK cells in the control of infection in SCID mice. The early control of net bacterial multiplication in the spleens and livers of BALB/c mice was ablated by whole-body X-irradiation. Both wild-type and plasmid-cured strains multiplied significantly more rapidly in irradiated than in conventional BALB/c mice. However, the numbers of wild-type bacterial still increased more rapidly than in the numbers of the cured strains. These results are consistent with a role of the S. dublin virulence plasmid in promoting in vivo growth of Salmonella cells.

Serum survival and plasmid possession by strains of Salmonella enteritidis, Salm. typhimurium and Salm. virchow

Strains of Salmonella enteritidis, Salm. typhimurium and Salm. virchow, carrying different numbers of plasmids, were examined for the ability to multiply in sera. Viable counts were performed to monitor the kinetics of growth of bacteria when in human, chicken and turkey sera. The presence of plasmids in Salm. enteritidis, Salm. typhimurium and Salm. virchow reduced considerably the ability of strains of these serotypes to multiply in serum. SDS-PAGE was used to show that growth of Salm. enteritidis in serum did not involve changes in outer membrane proteins or lipopolysaccharide. It was concluded that the carriage of plasmids may be disadvantageous for the survival in serum of certain common salmonella serotypes.

The Salmonella dublin virulence plasmid mediates systemic but not enteric phases of salmonellosis in cattle

Plasmid-bearing and plasmid-free isolates and a plasmid-cured strain of Salmonella dublin were compared for virulence in calves. The plasmid-bearing strains were highly virulent, causing severe enteric and systemic disease with high mortality. In contrast, the plasmid-free strains caused diarrhea but only low mortality. The infection kinetics of a wild-type and a derivative plasmid-cured strain were compared. Both strains were isolated in high numbers from intestinal sites at 3 and 6 days after oral challenge and were isolated at comparable frequencies from systemic sites at 3 days, but not at 6 days, when the wild-type strain was predominant. The strains were equally invasive in intestinal epithelia with and without Peyer's patch and elicited comparable secretory and inflammatory responses and intestinal pathology in ligated ileal loops. The effect of the virulence plasmid on growth kinetics and on the outer membrane protein profile was assessed in an in vivo growth chamber. The virulence plasmid did not influence either extracellular growth or the expression of major outer membrane proteins. These observations demonstrate that the virulence plasmid is not involved in either the enteric phase of infection or the systemic dissemination of S. dublin but probably mediates the persistence of S. dublin at systemic sites.

Current perspectives in salmonellosis

Salmonellosis remains an important human and animal problem worldwide and, despite extensive research effort, many of the details of its pathogenesis are not known. While there have been recent advances in some aspects of pathogenesis, other areas are not understood. The host adaptation shown by several serotypes and the recent dramatic changes in the predominance of particular serotypes are examples. Molecular techniques using in vitro model systems have identified several genes involved in adhesion and invasion, though their function and even their relevance to disease remain poorly defined. Similarly, several potential toxins have been identified and the genes cloned, although their significance is far from clear. Some of the essential genes on the large virulence plasmids have been defined, and these are known to be necessary for the establishment of systemic infection. Two of these genes are regulatory, but the function of the other genes is unknown. A general theme has been the identification of gene systems involved in regulation of virulence. New vaccines, based on 'rational attenuation' are being designed, and these have also been used to carry heterologous antigens; such vaccines are currently undergoing trials. The improved understanding of the pathogenesis of salmonellosis may also provide a model of wide applicability to a more general understanding of bacterial pathogenesis. New techniques, including the polymerase chain reaction, are being applied to diagnose salmonellosis.

Regulation of spvR gene expression of Salmonella virulence plasmid pKDSC50 in Salmonella choleraesuis serovar Choleraesuis

The expression regulation of spvR, a regulatory gene on the virulence plasmid (pKDSC50) of Salmonella choleraesuis serovar Choleraesuis, was investigated by spvR-lacZ translational fusion. The spvR gene was found to be positively regulated by its own product, the SpvR protein, and this unusual positive autoregulation was repressed by the products of spvA and spvB, virulence-associated genes present downstream from the spvR gene. Amino acid sequence analysis revealed that the amino-terminal region of SpvB had homology with the CatM repressor protein of Acinetobacter calcoaceticus, which belongs to the MetR/LysR protein family. On the other hand, the sigma factor RpoS was required for expression of the spvR gene in the stationary phase of bacterial growth. The SpvR protein was also necessary for self-activation, suggesting that an RNA polymerase holoenzyme containing RpoS requires SpvR protein in order to recognize the spvR promoter.

Regulation of spvR, the positive regulatory gene of Salmonella plasmid virulence genes

The regulation of the spvR promoter from the Salmonella dublin virulence plasmid was monitored using promoter-reporter gene fusion constructs. Activity was dependent upon the presence of the spv region and was affected by the number of copies of the spv region present within the cell. Activity remained constant throughout exponential growth, and increased rapidly with the onset of stationary phase, under both aerobic and anaerobic conditions. Additionally, the level of spvR expression was controlled by the availability of iron, activity being greatest under low iron conditions in stationary phase. The spvA gene product negatively regulated spvR expression in a dose-dependent manner, indicating that SpvA provides a negative feedback mechanism for this operon.

Expression of the Salmonella virulence plasmid gene spvB in cultured macrophages and nonphagocytic cells

Certain serotypes of salmonellae carry virulence plasmids that greatly enhance the pathogenicity of these bacteria in experimentally infected mice. This phenotype is largely attributable to the 8-kb spv regulon. However, spv genes are not expressed while bacteria grow in vitro. We now show that spvB, which is required for virulence, is expressed rapidly after Salmonella dublin is ingested by cultured J774 and murine peritoneal macrophages and that expression is not affected by the alkalinization of intracellular vesicles. The level of induction of spvB is reduced when macrophages are pretreated with gamma interferon. spvB is also expressed in human and canine epithelial cell lines and a human hepatoma cell line. In all cases, spvB expression is dependent on the spvR gene, just as it is in stationary-phase cultures in vitro. These data suggest that spv virulence genes are expressed by intracellular salmonellae in vivo in response to a signal that is common to the intracellular compartments of cells that are invaded by salmonellae.

Nucleotide sequence of a 13.9 kb segment of the 90 kb virulence plasmid of Salmonella typhimurium: the presence of fimbrial biosynthetic genes

The 90kb plasmid resident in Salmonella typhimurium confers increased virulence in mice by promoting the spread of infection after invasion of the intestinal epithelium. The nucleotide sequence of a 13.9kb segment of this plasmid known to encode an outer membrane protein related in sequence to components of fimbrial biosynthesis in enteric bacteria was determined. This cloned segment between the repB and repC replicon regions programmed expression of abundant surface fimbriae in Escherichia coli and S. typhimurium cells. A 7kb region contained seven open reading frames, the protein products of five of which were related in sequence to regulatory, structural, and assembly proteins of adherence fimbriae/pili, such as the P and K88 pili. These five genes and two adjacent ones which were not markedly related to proteins in the data bases comprise the pef (plasmid-encoded fimbriae) locus. Transposon TnphoA insertions in four genes in the pef locus (pefA, pefC, orf5 and orf6) resulted in active PhoA fusions and blocked or reduced the surface presentation of fimbriae, indicating that the proteins encoded by these four genes are translocated at least across the cytoplasmic membrane and contribute to formation of the fimbrial structure. The differences in genetic organization and protein sequence relatedness from other fimbrial gene clusters suggest that the pef locus might encode a novel type of fimbria. Between the pef and the repB loci, there were five open reading frames, one of which (orf8) gave rise to active PhoA fusions but was not necessary for fimbrial expression. Two of the other proteins were homologous to transcription regulatory proteins and a third was the rck gene, which encodes an outer membrane protein that confers complement resistance to serum-sensitive hosts.

Molecular analysis of spv virulence genes of the Salmonella virulence plasmids

Genes on an 8 kb region common to the virulence plasmids of several serovars of Salmonella are sufficient to replace the entire plasmid in enabling systemic infection in animal models. This virulence region encompasses five genes which previously have been designated with different names from each investigating laboratory. A common nomenclature has been devised for the five genes, i.e. spv for salmonella plasmid virulence. The first gene, spvR, encodes a positive activator for the following four genes, spvABCD. DNA sequence analysis of the spv genes from Salmonella typhimurium, Salmonella dublin, and Salmonella choleraesuis demonstrated extremely high conservation of the DNA and amino acid sequences. The spv genes are induced at stationary phase and in carbon-poor media, and optimal expression is dependent on the katF locus. The virulence functions of the spv genes are not known, but these genes may increase the growth rate of salmonellae in host cells and affect the interaction of salmonellae with the host immune system.

The Salmonella typhimurium virulence plasmid increases the growth rate of salmonellae in mice

The virulence plasmids of Salmonella typhimurium and other invasive Salmonella serovars have long been associated with the ability of these bacteria to cause systemic infection beyond the intestines in orally inoculated animals. Genetic analysis of virulence genes on the high-molecular-weight plasmids has revealed that no more than five genes spanning a 6.2-kb region are sufficient to replace the entire plasmid for conferring virulence. However, the exact virulence function(s) encoded by these genes has not been elucidated. In this report, we measured the possible effect of the virulence plasmid on the growth rate of S. typhimurium in mice by two complementary procedures. The first procedure used segregation of a temperature-sensitive plasmid in vivo to provide a measure of bacterial divisions and the number of recovered marker plasmid-containing salmonellae as a measure of killing. In the second procedure, aroA deletions were transduced into virulence plasmid-containing and plasmid-cured S. typhimurium. Since AroA- salmonellae are inhibited for growth in vivo, if the virulence plasmid affected only growth rate, no difference in the recoveries of the paired AroA- strains would be seen. Virulence plasmid-containing S. typhimurium segregated the marker plasmid more rapidly than did the virulence plasmid-cured strain, and AroA- derivatives of both strains were recovered equally from mice. Therefore, the S. typhimurium virulence plasmid increased growth rate but had no detectable effect on killing or bacterial movement into deep tissues. To examine whether the plasmid accomplished this function by affecting the intracellular/extracellular location of bacteria, orally infected mice were injected with gentamicin to kill the extracellular bacteria. Wild-type and plasmid-cured S. typhimurium strains were equally resistant to gentamicin in vivo and hence most likely located intracellularly to equal degrees. When wild-type and plasmid-cured S. typhimurium strains were sequestered within peritoneal chambers in mice, the resulting extracellular growth was equal. Therefore, the virulence plasmid increases the growth rate of S. typhimurium in mice, probably within mouse cells.

Characterization of translation termination mutations in the spv operon of the Salmonella virulence plasmid pSDL2

The spv region of the Salmonella virulence plasmids consists of five genes located on an 8-kb fragment previously shown to be essential for virulence in mice. Four structural genes, spvABCD, form an operon that is transcriptionally activated by the spvR gene product in the stationary phase of growth. The role of the individual spv genes in the virulence phenotype was tested by isolating translation termination linker insertions in each gene. Analysis of proteins synthesized in minicells identified each of the spvABCD gene products and confirmed the dependence of spv structural gene expression on the SpvR regulatory protein. The oligonucleotide insertions in spvA, -B, and -C were shown to be nonpolar. Virulence testing indicated that the SpvB protein, regulated by SpvR, is essential for Salmonella dublin to cause lethal disease in mice. Inserts in spvC and spvD were unstable in vivo for unknown reasons, but these mutants still killed mice at slightly higher inocula. Abolition of spvA had no effect on virulence in this system.

Regulation of plasmid virulence gene expression in Salmonella dublin involves an unusual operon structure

The 80-kb plasmid pSDL2 of Salmonella dublin Lane is essential for lethal systemic infection in experimental mice. A cluster of five plasmid genes, designated spvR, spvA, spvB, spvC, and spvD, is sufficient to express the plasmid-related virulent phenotype. The spvR gene product has recently been identified as a positive regulator of spvB expression in the stationary phase of bacterial growth (F. C. Fang, M. Krause, C. Roudier, J. Fierer, and D. G. Guiney, J. Bacteriol. 173:6783-6789, 1991). In this study, we evaluated the role of SpvR in the transcription of the downstream virulence genes spvABCD. Analysis of mRNA synthesis revealed that SpvR promotes transcription of the downstream spvABCD genes in the stationary growth phase. Transcript mapping of the spv region demonstrated an unusual operon structure involving messages for spvA, spvAB, spvABC, and spvABCD. Quantitative measurement of transcription and of gene expression by use of translational spv-lacZ fusions suggested that SpvA, SpvB, SpvC, and SpvD are produced in decreasing abundance. Primer extension assays identified two transcriptional start sites 70 and 98 bp upstream of the start codon of spvA, but none upstream of spvB, spvC, or spvD. Deletion of a 320-bp EcoRI-ApaI segment that contains both start sites abolished expression of the downstream spvB and spvC genes. Our results establish a central function of SpvR as a positive regulator of the downstream spvABCD genes in the stationary phase of bacterial growth and indicate that the primary mechanism of regulation is by activation of promoters upstream of spvA.

A Salmonella dublin virulence plasmid locus that affects bacterial growth under nutrient-limited conditions

This paper reports the characterization of a new locus, vagC/vagD, on the virulence plasmid of Salmonella dublin. Strain G19, harbouring a TnA insertion in vagC, exhibited reduced virulence although vagC was outside the 8 kb essential virulence region. G19 was also unable to grow on minimal-medium containing various sole carbon/energy sources, unlike the wild-type and plasmid-cured strains. Sequencing of the locus revealed the presence of two ORFs (vagC and vagD) which overlapped by one nucleotide. The VagC polypeptide (12 kDa) was observed using minicell expression. Results indicated that vagD was responsible for the phenotypic differences observed between the wild type and G19, and that vagC modulated the activity of vagD. Furthermore, microscopic analysis of G19 cells harvested from minimal-medium plates showed that a high proportion of cells were elongated, which suggested that vagC and vagD might be involved in coordination of plasmid replication with cell division. We propose that vagD, under certain environmental conditions, acts to prevent cell division until plasmid replication is complete, thus aiding plasmid maintenance. vagC and vagD are absent from the related virulence plasmid of Salmonella typhimurium.

Identification, genetic analysis and DNA sequence of a 7.8-kb virulence region of the Salmonella typhimurium virulence plasmid

The 90-kilobase (kb) virulence plasmid of Salmonella typhimurium is responsible for invasion from the intestines to mesenteric lymph nodes and spleens of orally inoculated mice. We used Tn5 and aminoglycoside phosphotransferase (aph) gene insertion mutagenesis and deletion mutagenesis of a previously identified 14-kb virulence region to reduce this virulence region to 7.8kb. The 7.8-kb virulence region subcloned into a low copy-number vector conferred a wild-type level of splenic infection to virulence plasmid-cured S. typhimurium and conferred essentially a wild-type oral LD50. Insertion mutagenesis identified five loci essential for virulence, and DNA sequence analysis of the virulence region identified six open reading frames. Expected protein products were identified from four of the six genes, with three of the proteins identified as doublet bands in Escherichia coli minicells. Three of the five mutated genes were able to be complemented by clones containing only the corresponding wild-type gene. Only one of the five deduced amino acid sequences, that of the positive regulatory element, SpvR, possessed significant homology to other proteins. The codon usage for the virulence genes showed no codon bias, which is consistent with the low levels of expression observed for the corresponding proteins. Consensus promoters for several different sigma factors were identified upstream of several of the genes, whereas only consensus Rho-dependent termination sequences were observed between certain of the genes. The operon structure of this virulence region therefore appears to be complex. The construction of the cloned 7.8-kb virulence region and the determination of the DNA sequence will aid in the further genetic analysis of the five plasmid-encoded virulence genes of S. typhimurium.

Heteroduplex analysis of Salmonella virulence plasmids and their prevalence in isolates of defined sources

Strains of the Salmonella serovars S. typhimurium, S. enteritidis, S. dublin, and S. choleraesuis harbour large plasmids which are required for extraintestinal colonization after oral infection of mice. Electron microscopic heteroduplex analysis showed that these virulence plasmids share large regions of homology. Nine hundred and eighty-six isolates of different origins were analysed for the presence of these plasmids by using a cloned fragment of a S. choleraesuis virulence plasmid as a gene probe. Virulence plasmids were detected in nearly 100% of strains isolated from animal organs or human blood. Frequencies of detection ranged from 48 to 87% in strains of faecal, food or environmental origin. These results suggest that Salmonella virulence plasmids are required for systemic infections in humans and livestock.

The Salmonella typhimurium virulence plasmid encodes a positive regulator of a plasmid-encoded virulence gene

The 90-kb virulence plasmid of Salmonella typhimurium is necessary for invasion beyond the Peyer's patches to the mesenteric lymph nodes and spleens of orally inoculated mice. Two Tn5 insertions located on the left side of a previously identified 14-kb virulence region (P. A. Gulig and R. Curtiss III, Infect. Immun. 58:3262-3271, 1988) and mapping 272 bp from each other exhibited opposite effects on splenic infection of mice after oral inoculation. spvR23::Tn5 decreased splenic infection by 1,000-fold, whereas a spv-14::Tn5 mutant outcompeted wild-type S. typhimurium for splenic infection by 27-fold in mice fed mixtures of mutated and wild-type S. typhimurium. spvR23::Tn5 was complemented by a virulence plasmid subclone with an insert sequence encoding only an 891-bp open reading frame specifying a 33,000-molecular-weight protein. The amino acid sequence of this open reading frame had significant homology to members of the LysR family of positive regulatory proteins; thus, the gene was named spvR (salmonella plasmid virulence). To examine the possible regulatory effects of spvR on other virulence genes, we constructed a lacZ operon fusion in a downstream virulence gene, spvB. When spvR subcloned behind the lac promoter was provided on a separate plasmid in trans to the spvB-lacZ operon fusion, transcription of spvB increased 15-fold. spv-14::Tn5, which conferred a competitive advantage to S. typhimurium, increased the expression of a spvR-lacZ operon fusion in cis. spvR is therefore a positive regulator of spvB and an essential virulence gene of S. typhimurium. As opposed to having spvR subcloned behind the lac promoter, the wild-type spvR gene present on the virulence plasmid did not function to positively regulate spvB-lacZ in trans when salmonellae were grown to the log phase in L broth, suggesting that this regulatory system is activated in vivo during infection.

The mkaC virulence gene of the Salmonella serovar typhimurium 96 kb plasmid encodes a transcriptional activator

The intracellular growth and virulence of Salmonella serovar Typhimurium for mice is dependent on a plasmid-borne gene cluster termed mka. We studied the regulatory interactions of the genes mkaA, mkaB, mkaC and mkaD using lacZ gene fusions. Complementation experiments with cloned DNA fragments encoding each of the four MKa proteins indicated that mkaC enhances the expression of beta-galactosidase from the mkaA-, mkaB- and mkaC-lacZ gene fusions in trans. An mkaD-lacZ fusion or mkaA-lacZ fusion that did not contain DNA proximal to mkaB was not inducible with MkaC, indicating that at least mkaB and mkaA are induced together as an operon. MkaC is thus the first virulence protein whose function has been resolved.

Positive regulator for the expression of Mba protein of the virulence plasmid, pKDSC50, of Salmonella choleraesuis

A positive regulator was identified within a 2.3 kb fragment of the 6.4 kb mouse bacteremia region (mba region) of the virulence pKDSC50 plasmid of Salmonella choleraesuis. Sodium dodecyl sulphate polyacrylamide gel electrophoresis showed that Escherichia coli K-12 carrying the recombinant plasmids of the 2.3 kb fragment produced Mba1 protein with a molecular mass of 32 kDa. The recombinant plasmids carrying a 4.1 kb fragment, the other part of 6.4 kb region, produced Mba2 (32 kDa), Mba3 (70 kDa) and Mba4 (29 kDa) proteins. All three proteins were expressed by using the lacZ promoter under isopropyl thiogalactoside induction. In contrast to this, Mba3 protein was overexpressed independently of the lacZ promoter when the 2.3 kb fragment coexisted either in cis or trans. These results suggest that Mba1 is a trans-acting positive regulator for the expression of the Mba3 protein of mba region of pKDSC50.

Molecular analysis of the virulence locus of the Salmonella dublin plasmid pSDL2

The virulence properties of various non-typhoid Salmonella serotypes depend on the presence of large plasmids 60-100 kb in size. We have shown previously that the virulence region on the 80 kb plasmid pSDL2 of Salmonella dublin Lane maps within a 14kb SalI fragment. In this report we show that an 8.2 kb region within this fragment is sufficient to express lethal disease in BALB/c mice. Sequence analysis of this segment revealed six sequential open reading frames designated vsdA-F, which encode putative proteins of 13-65kDa. Deletion analysis and location of Tn5-oriT inserts which abolish virulence suggest that vsdA, vsdC, vsdD and vsdE are essential for virulence expression. Downstream of vsdF we discovered a locus involved in stable plasmid maintenance. Deletion of that region resulted in plasmid multimerization and instability.

Pathogenicity of foodborne Salmonella

Salmonella remains a leading etiological agent in bacterial foodborne diseases. Although human salmonellosis generally presents as a self-limiting episode of enterocolitis, the disease can degenerate into chronic and debilitating conditions. Antibiotic treatment of uncomplicated salmonellosis is contra-indicated because it tends to prolong the carrier state. Clinical management of systemic infections with newer drugs such as third-generation cephalosporins and quinolones is most promising, particularly in light of the increasing resistance of Salmonella to the traditional ampicillin, chloramphenicol and trimethoprim sulfamethoxazole therapeutic agents. Research into the development of effective vaccines from avirulent auxotrophic or from virulence plasmid-cured strains may ultimately facilitate the control of salmonellosis in human populations and in various agricultural sectors. Human salmonellosis reflects the outcome of a confrontation between humoral and cellular immune responses of the host, and virulence determinants of the invasive pathogen. Following an adhesion-dependent attachment of salmonellae to lumenal epithelial cells, the invasive pathogen is internalized within an epithelial cell by a receptor-mediated endocytotic process. Cytotoxin localized in the bacterial cell wall suggestively may facilitate Salmonella entry into the epithelial layer. Cytoplasmic translocation of the infected endosome to the basal epithelial membrane culminates in the release of salmonellae in the lamina propria. During this invasive process, Salmonella secretes a heat-labile enterotoxin that precipitates a net efflux of water and electrolytes into the intestinal lumen. Although non-typhoid salmonellae generally precipitate a localized inflammatory response in deeper tissues via lymphatics and capillaries, and elicit a major immune response. Current research efforts have focused on the molecular characterization and role of virulence plasmids and chromosomal genes in Salmonella pathogenicity.

Conservation of Salmonella typhimurium virulence plasmid maintenance regions among Salmonella serovars as a basis for plasmid curing

The association of large plasmids with virulence in invasive Salmonella serovars has led to a number of studies designed to uncover the role of these plasmids in virulence. This study addresses two aspects of virulence-associated plasmids. The first is the distribution of the replication and maintenance regions among the plasmids of different Salmonella serovars, and the second is the use of the conserved virulence plasmid par region to provide a rapid method for eliminating the virulence plasmids specifically. Colony blots revealed that the par and repB regions of the S. typhimurium virulence plasmid hybridized with 80% of the isolates of S. choleraesuis, S. dublin, S. enteritidis, S. gallinarum, S. pullorum, and S. typhimurium, while the repC region was not detected in any of the isolates of S. dublin, S. gallinarum, or S. pullorum. None of these maintenance regions was found in any of the 30 additional serovars tested. The large plasmids of those serovars that hybridized with par were labeled with a Kmr insert within parA via P22HTint or P1L4 transduction, which destabilized the plasmids and allowed the rapid isolation of plasmid-free derivatives for all of the serovars, except for S. dublin, which exhibited weak homology with par.

Identification of proteins expressed by the essential virulence region of the Salmonella dublin plasmid

An 8 kilobase pair (kb) fragment from the Salmonella dublin 2229 plasmid is sufficient to restore virulence for mice to a cured strain of S. dublin. Deletion analysis of this virulence fragment identified at least one specific region required for virulence expression. Plasmid-directed protein synthesis in minicells has indicated the presence of at least four genes within the essential virulence region of the S. dublin plasmid, encoding proteins of 70, 33, 30 and 26 kDa. Analysis of the proteins expressed by the deletion derivatives suggested that expression of the 33 kDa polypeptide was linked to that of the 30 kDa polypeptide. The proteins expressed by the essential virulence region of the S. dublin plasmid appeared to be similar to the plasmid-encoded virulence proteins recently identified in S. typhimurium.

Correlation between the presence of sequences homologous to the vir region of Salmonella dublin plasmid pSDL2 and the virulence of twenty-two Salmonella serotypes in mice

Large plasmids encoding important virulence properties have been found in several Salmonella serotypes. We have studied the relationship between the presence of a highly conserved 4-kilobase (kb) EcoRI fragment from the plasmid virulence region and pathogenicity for mice of 53 isolates representing 22 serotypes of Salmonella. Only strains possessing the homologous 4-kb region were virulent for mice. In addition, we transferred the virulence plasmid from S. dublin into nine different serotypes, including S. typhi and S. paratyphi A, that lack a native virulence plasmid. Only S. heidelberg and S. newport were rendered mouse virulent by the introduction of the S. dublin plasmid. This study demonstrates that plasmid-mediated virulence sequences are required for Salmonella virulence in mice, but many strains, including the agents of human typhoid fever, also lack chromosomal genes necessary to produce lethal systemic disease in mice. Since all the major Salmonella strains that are host-adapted to animals carry virulence plasmids, it appears that these plasmids are important in mediating systemic infection in animals and may contribute to septicemic, nontyphoid salmonellosis in humans.

Salmonella-based vaccines

There continues to be considerable interest in the development of a safe, effective, live, oral vaccine to combat typhoid fever of humans. Such a vaccine may be a derivative of the causative agent of the disease, Salmonella typhi. The prototype of such a vaccine, Ty21a, is not ideal, but no replacement for Ty21a is yet obvious. The construction and trial of bivalent vaccines, in which an attenuated Salmonella strain expresses determinants from another pathogen, awaits the development of a suitably attenuated derivative. In parallel with vaccine development programmes, a variety of techniques have been designed to effect stable association between Salmonella carrier and introduced cloned DNA.

The identification, typing and fingerprinting of Salmonella: laboratory aspects and epidemiological applications

Since the 1930s, traditional methods of strain identification based on serotyping and phage typing have been the foundation of salmonella epidemiology. Although the incidence of diseases such as typhoid and paratyphoid has decreased in recent years, food-poisoning caused by non-typhoidal salmonella strains has now reached epidemic proportions in many countries, despite improvements in sanitation and hygiene. Precise strain identification is an essential prerequisite for epidemiological investigations aimed at combating the spread of these strains and eradicating the sources of infection. Modern methods of genotypic typing, particularly those based on physical characterization of the plasmid content of the organism have already proved invaluable for the identification and differentiation of strains in many outbreaks. These plasmid typing methods are now increasingly used with serotyping and phage typing for many epidemiological investigations. Other methods of genotypic typing, particularly those based on recognition of small differences in chromosome structure, are not yet practical for the examination of large numbers of strains. Nevertheless, improvements in small-scale methods for chromosomal DNA extraction coupled with the increasing use of non-isotopic labels for identification of restriction fragment length polymorphisms may provide a new dimension to Salmonella epidemiology.

Virulence plasmids of Salmonella typhimurium and other salmonellae

Related high molecular weight plasmids of several serotypes and species of Salmonella have been associated with virulence in a variety of animal models of infection. The primary virulence plasmid phenotype is in the ability of salmonellae to spread beyond the initial site of infection, the intestines. The mechanism of this plasmid-mediated invasive infection has not been identified, but may be a complex interaction in the host-pathogen relationship. A common region of the salmonella plasmids has been associated with virulence, and specific virulence genes and their products are now being identified; however, much is yet to be accomplished in this field. The combined analysis of pathogenesis and genetics associated with the salmonella virulence plasmids may identify new systems of bacterial virulence and the genetic basis for this virulence.

Molecular organization of genes constituting the virulence determinant on the Salmonella typhimurium 96 kilobase pair plasmid

The ability of intracellular growth is plasmid-dependent in Salmonella typhimurium. Only a small portion of this 96 kilobase pair plasmid appears essential for intracellular growth. The genetic organization of this region (the essential virulence determinant) was resolved. Fragments of the virulence determinant were cloned from the 96-kb plasmid pEX102 and transformed into minicell-producing E. coli. Plasmid-directed protein synthesis was investigated in metabolically labeled minicells. This analysis indicated the presence of at least four genes, mkaA, mkaB, mkaC and mkaD, within the virulence determinant encoding proteins of 70, 31, 30 and 29 kDa, respectively. The genes were positioned on the restriction map of the 96-kb virulence plasmid and the map locations confirmed by nucleotide sequence analysis of two new virulence genes (mkaB and mkaC).

Functional homology of virulence plasmids in Salmonella gallinarum, S. pullorum, and S. typhimurium

The virulence-associated plasmids of strains of Salmonella gallinarum and S. pullorum were transferred separately by mobilization with the F plasmid into virulence plasmid-cured derivatives of S. gallinarum, S. pullorum, and S. typhimurium and into a prototrophic Escherichia coli K-12 strain. The transconjugants were tested for virulence in chickens of different ages and in mice. The S. gallinarum and S. pullorum plasmids were able to restore full virulence in the three Salmonella strains, thus demonstrating functional homology in virulence plasmids from these Salmonella serotypes and biotypes. The virulence phenotypes of the transconjugants remained the same as that of the parent strain of the recipient. This, together with the fact that E. coli K-12 containing either of the virulence plasmids was avirulent for chickens, suggested that in addition to plasmid genes, chromosomal genes are important in determining virulence, particularly in determining the ability to survive and multiply in the cells of the reticuloendothelial system. The virulence plasmids were not self-transmissible and could not be transduced by temperate bacteriophages lysogenizing field strains of S. gallinarum. They were not in the same incompatibility group as F but were fi+.