Spontaneous and transient defence against bacteriophage by phase‐variable glucosylation of O‐antigen in Salmonella enterica serovar Typhimurium

As natural killers of bacteria, bacteriophages have forced bacteria to develop a variety of defence mechanisms. The alteration of host receptors is one of the most common bacterial defence strategies against phage infection, which completely blocks phage attachment but comes at a potential fitness cost to the bacteria. Here, we report the cost‐free, transient emergence of phage resistance in Salmonella enterica subspecies enterica serovar Typhimurium through a phase‐variable modification of the O‐antigen. Phage SPC35 typically requires BtuB as a host receptor but also uses the Salmonella O12‐antigen as an adsorption‐assisting apparatus for the successful infection of S. Typhimurium. The α‐1,4‐glucosylation of galactose residues in the O12‐antigen by phase variably expressed O‐antigen glucosylating genes, designated the ^{LT 2} gtrABC1 cluster, blocks the adsorption‐assisting function of the O12‐antigen. Consequently, it confers transient SPC35 resistance to Salmonella without any mutations to the btuB gene. This temporal switch‐off of phage adsorption through phase‐variable antigenic modification may be widespread among Gram‐negative bacteria‐phage systems.     

Horizontally Acquired Glycosyltransferase Operons Drive Salmonellae Lipopolysaccharide Diversity

The immunodominant lipopolysaccharide is a key antigenic factor for Gram-negative pathogens such as salmonellae where it plays key roles in host adaptation, virulence, immune evasion, and persistence. Variation in the lipopolysaccharide is also the major differentiating factor that is used to classify Salmonella into over 2600 serovars as part of the Kaufmann-White scheme. While lipopolysaccharide diversity is generally associated with sequence variation in the lipopolysaccharide biosynthesis operon, extraneous genetic factors such as those encoded by the glucosyltransferase (gtr) operons provide further structural heterogeneity by adding additional sugars onto the O-antigen component of the lipopolysaccharide. Here we identify and examine the O-antigen modifying glucosyltransferase genes from the genomes of Salmonella enterica and Salmonella bongori serovars. We show that Salmonella generally carries between 1 and 4 gtr operons that we have classified into 10 families on the basis of gtrC sequence with apparent O-antigen modification detected for five of these families. The gtr operons localize to bacteriophage-associated genomic regions and exhibit a dynamic evolutionary history driven by recombination and gene shuffling events leading to new gene combinations. Furthermore, evidence of Dam- and OxyR-dependent phase variation of gtr gene expression was identified within eight gtr families. Thus, as O-antigen modification generates significant intra- and inter-strain phenotypic diversity, gtr-mediated modification is fundamental in assessing Salmonella strain variability. This will inform appropriate vaccine and diagnostic approaches, in addition to contributing to our understanding of host-pathogen interactions.     

Immunogenicity of the Shigella flexneri Serotype Y (SFL124) Vaccine Strain Expressing Cloned Glucosyl Transferase Gene of Converting Bacteriophage SfX

The glucosyl transferase gene (gtr) from bacteriophage phage X (SfX) caused partial conversion of serotype Y (group antigen 3, 4) to X (group antigen 7, 8) when introduced into a candidate vaccine strain of Shigella flexneri serotype Y (SFL124). The gtr gene caused conversion of O-antigens but did not eliminate the adsorption of the corresponding phage SfX. The hybrid strain expressing both group antigens 7, 8 and 3, 4 showed 75% protection when immunized guinea pigs were challenged with a wild-type S. flexneri serotype X strain. No protection was observed against serotype Y challenge, although group antigen 3, 4 was detected in the LPS of the hybrid strain. This suggests the importance of O-antigen immunity in the host defense against shigellosis.     

Epigenetic Control of Salmonella enterica O-Antigen Chain Length: A Tradeoff between Virulence and Bacteriophage Resistance

The Salmonella enterica opvAB operon is a horizontally-acquired locus that undergoes phase variation under Dam methylation control. The OpvA and OpvB proteins form intertwining ribbons in the inner membrane. Synthesis of OpvA and OpvB alters lipopolysaccharide O-antigen chain length and confers resistance to bacteriophages 9NA (Siphoviridae), Det7 (Myoviridae), and P22 (Podoviridae). These phages use the O-antigen as receptor. Because opvAB undergoes phase variation, S. enterica cultures contain subpopulations of opvAB ^OFF and opvAB ^ON cells. In the presence of a bacteriophage that uses the O-antigen as receptor, the opvAB ^OFF subpopulation is killed and the opvAB ^ON subpopulation is selected. Acquisition of phage resistance by phase variation of O-antigen chain length requires a payoff: opvAB expression reduces Salmonella virulence. However, phase variation permits resuscitation of the opvAB ^OFF subpopulation as soon as phage challenge ceases. Phenotypic heterogeneity generated by opvAB phase variation thus preadapts Salmonella to survive phage challenge with a fitness cost that is transient only.     

Shigella flexneri type-specific antigen V: cloning,sequencing and characterization of the glucosyl transferase gene of temperate bacteriophage SfV

With lysogeny by bacteriophage SfV, Shigella flexneri serotype Y is converted to serotype 5a. The glucosyl transferase gene (gtr) from bacteriophage SfV of S. flexneri, involved in serotype-specific conversion, was cloned and characterized. The DNA sequence of a 3.7 kb EcoRI–BamHI fragment of bacteriophage SfV which includes the gtr gene was determined. This gene, encoding a polypeptide of 417 aa with 47.67 kDa molecular mass, caused partial serotype conversion of S. flexneri from serotype Y to type V antigen as demonstrated by Western blotting and the sensitivity of the hybrid strain to phage Sf6. The deduced protein of the partially sequenced open reading frame upstream of the gtr showed similarity to various glycosyl transferases of other bacteria. Orf3, separated from the gtr by a non-coding region and transcribed convergently, codes for a 167 aa (18.8 kDa) protein found to have homology with tail fibre genes of phage lambda and P2.     

Conflicting roles for a cell surface modification in Salmonella

Chemical modifications of components of the bacterial cell envelope can enhance resistance to antimicrobial agents. Why then are such modifications produced only under specific conditions? Here, we address this question by examining the role of regulated variations in O‐antigen length in the lipopolysaccharide (LPS), a glycolipid that forms most of the outer leaflet of the outer membrane in Gram‐negative bacteria. We determined that activation of the PmrA/PmrB two‐component system, which is the major regulator of LPS alterations in Salmonella enterica serovar Typhimurium, impaired growth of Salmonella in bile. This growth defect required the PmrA‐activated gene wzz_st, which encodes the protein that determines long O‐antigen chain length and confers resistance to complement‐mediated killing. By contrast, this growth defect did not require the wzz_fepE gene, which controls production of very long O‐antigen, or other PmrA‐activated genes that mediate modifications of lipid A or core regions of the LPS. Additionally, we establish that long O‐antigen inhibits growth in bile only in the presence of enterobacterial common antigen, an outer‐membrane glycolipid that contributes to bile resistance. Our results suggest that Salmonella regulates the proportion of long O‐antigen in its LPS to respond to the different conditions it faces during infection.     

Sequence Analysis of the rfb Loci, Encoding Proteins Involved in the Biosynthesis of the Salmonella enterica O17 and O18 Antigens: Serogroup-Specific Identification by PCR

We report sequencing of the O antigen encoded by the rfb gene cluster of Salmonella enterica serotype Jangwani (O17) and Salmonella serotype Cerro (O18). We developed serogroup O17- and O18-specific PCR assays based on rfb gene targets and found them to be sensitive and specific for rapid identification of Salmonella serogroups O17 and O18.     

A Novel Glucosyltransferase Involved in O-Antigen Modification of Shigella flexneri Serotype 1c

The O antigen of serotype 1c differs from the unmodified O antigen of serotype Y by the addition of a disaccharide (two glucosyl groups) to the tetrasaccharide repeating unit. It was shown here that addition of the first glucosyl group is mediated by the previously characterized gtrI cluster, which is found within a cryptic prophage at the proA locus in the bacterial chromosome. Transposon mutagenesis was performed to disrupt the gene responsible for addition of the second glucosyl group, causing reversion to serotype 1a. Colony immunoblotting was used to identify the desired revertants, and subsequent sequencing, cloning, and functional expression successfully identified the gene encoding serotype 1c-specific O-antigen modification. This gene (designated gtrIC) was present as part of a three-gene cluster, similar to other S. flexneri glucosyltransferase genes. Relative to the other S. flexneri gtr clusters, the gtrIC cluster is more distantly related and appears to have arrived in S. flexneri from outside the species. Analysis of surrounding sequence suggests that the gtrIC cluster arrived via a novel bacteriophage that was subsequently rendered nonfunctional by a series of insertion events.Shigella flexneri is a pathovar of Escherichia coli that is the main causative agent of endemic bacillary dysentery (shigellosis). It is estimated that S. flexneri is responsible for approximately 100 million shigellosis cases annually, resulting in hundreds of thousands of deaths, predominantly in young children (11). Currently no vaccine is available, although there is evidence to suggest that serotype-specific immunity occurs following infection and that induction of immunity can be replicated with vaccines (9). Shigella serotype diversity arises due to differences in the chemical structure of the O-antigen repeating unit in the lipopolysaccharide, which is the main target of the adaptive host immune response following infection.Because immunity to S. flexneri can be conferred by the induction of antibodies directed against the O antigen, an understanding of the prevalence of different serotypes and the underlying basis of serotype diversity can inform appropriate vaccine design. All S. flexneri serotypes (with the exception of serotype 6) share a common O-antigen backbone, consisting of a repeating tetrasaccharide unit that is comprised of one N-acetylglucosamine residue (GlcNAc) and three rhamnose residues (RhaI, RhaII, and RhaIII) (14). The 12 traditionally recognized S. flexneri serotypes differ by the presence or absence of just six different chemical modifications (glucosylations or O acetylations) of the O antigen. The genes responsible for these O-antigen modifications are introduced into the bacterial genome via bacteriophages (3). Glucosylation of the S. flexneri O antigen is mediated by three genes [gtrA, gtrB, and gtr(type)] that are arranged in a single operon known as a gtr cluster. gtrA and gtrB are highly conserved between different gtr clusters and encode proteins involved in transferring the glucosyl group from the cytoplasm into the periplasm, where O-antigen modification is thought to take place. gtr(type) is unique to each gtr cluster and encodes a glucosyltransferase that is responsible for attaching the glucosyl group to a specific sugar unit of the O antigen via a specific linkage (3).Investigations of S. flexneri have typically focused on serotypes for which commercially available typing sera are available. More recently, it has become clear that other serotypes are also epidemiologically important. In Bangladesh in the late 1980s, two novel S. flexneri strains that did not agglutinate with antibodies specific for the traditionally recognized serotypes were isolated (4). Chemical analysis of the O antigen revealed that these strains belonged to a new serotype, which was named serotype 1c due to the similarity its O antigen shares with the O antigens of serotype 1a and 1b strains (19). Serotype 1c has since been isolated in Egypt, Indonesia, Pakistan, and Vietnam (6, 15, 18). Serotype 1c was shown to be the most prevalent S. flexneri serotype in a northern province of Vietnam, accounting for more than a third of all S. flexneri strains isolated from 1998 to 1999 (15). Identification of serotype 1c currently relies on agglutination testing using monoclonal antibody MASF Ic (19).The O antigen of serotype 1c is distinguished by the presence of a disaccharide (two glucosyl groups) linked to the GlcNAc in the tetrasaccharide repeating unit of the O antigen. The first glucosyl group is joined to GlcNAc via an α1→4 linkage, as occurs in the O antigen of serotype 1a and serotype 1b strains (type I modification). The O antigen of serotype 1c is distinguished by the presence of a second glucosyl group that is linked to the first via an α1→2 linkage (Fig. ​(Fig.1).1). Type Ia modification is prerequisite to type Ic modification.Open in a separate windowFIG. 1.Chemical structure of the tetrasaccharide repeat units in the O antigens of S. flexneri serotypes 1a and 1c. Note that the O antigen of serotype 1b (not shown) differs from that of serotype 1a by the O acetylation of l-RhaIII.In this study, the genetic basis of O-antigen modification in serotype 1c was elucidated. Serotype 1c strains isolated from different locations and times were compared to gain insight into the evolution of this serotype. This is the first report of the identification of a glucosyltransferase gene that is responsible for addition of the second glucosyl group, causing serotype conversion from serotype 1a to serotype 1c.     

Molecular Analysis of the rfb O Antigen Gene Cluster of Salmonella enterica Serogroup O:6,14 and Development of a Serogroup-Specific PCR Assay

The Kauffmann-White scheme for serotyping Salmonella recognizes 46 somatic (O) antigen groups, which together with detection of the flagellar (H) antigens form the basis for serotype identification. Although serotyping has become an invaluable typing method for epidemiological investigations of Salmonella, it does have some practical limitations. We have been characterizing the genes required for O and H antigen biosynthesis with the goal of developing a DNA-based system for the determination of serotype in Salmonella. The majority of the enzymes involved in O antigen biosynthesis are encoded by the rfb gene cluster. We report the sequencing of the rfb region from S. enterica serotype Sundsvall (serogroup O:6,14). The S. enterica serotype Sundsvall rfb region is 8.4 kb in length and comprises six open reading frames. When compared with other previously characterized rfb regions, the serogroup O:6,14 sequence is most related to serogroup C₁. On the basis of DNA sequence similarity, we identified two genes from the mannose biosynthetic pathway, two mannosyl transferase genes, the O unit flippase gene and, possibly, the O antigen polymerase. The whole cluster is derived from a low-G+C-content organism. Comparative sequencing of an additional serogroup O:6,14 isolate (S. enterica serotype Carrau) revealed a highly homologous sequence, suggesting that O antigen factors O:24 and O:25 (additional O factors associated with serogroup O:6,14) are encoded outside the rfb gene cluster. We developed a serogroup O:6,14-specific PCR assay based on a region of the putative wzx (O antigen flippase) gene. This provides the basis for a sensitive and specific test for the rapid identification of Salmonella serogroup O:6,14.     

The major phase-variable outer membrane protein of Escherichia coli structurally resembles the immunoglobulin A1 protease class of exported protein and is regulated by a novel mechanism involving Dam and oxyR

Here we report the characterization of an Escherichia coli gene (agn43) which encodes the principal phase-variable outer membrane protein termed antigen 43 (Ag43). The agn43 gene encodes a precursor protein of 107 kDa containing a 52-amino-acid signal sequence. Posttranslational processing generates an alpha43 subunit (predicted Mr of 49,789) and a C-terminal domain (beta43) with features typical of a bacterial integral outer membrane protein (predicted Mr of 51, 642). Secondary structure analysis predicts that beta43 exists as an 18-stranded beta barrel and that Ag43 shows structural organization closely resembling that of immunoglobulin A1 protease type of exoprotein produced by pathogenic Neisseria and Haemophilus spp. The correct processing of the polyprotein to alpha43 and beta43 in OmpT, OmpP, and DegP protease-deficient E. coli strains points to an autocatalytic cleavage mechanism, a hypothesis supported by the occurrence of an aspartyl protease active site within alpha43. Ag43, a species-specific antigen, possesses two RGD motifs of the type implicated in binding to human integrins. The mechanism of reversible phase variation was studied by immunochemical analysis of a panel of well-defined regulatory mutants and by analysis of DNA sequences upstream of agn43. Evidence strongly suggests that phase variation is regulated by both deoxyadenosine methylase (Dam) and by OxyR. Thus, oxyR mutants are locked on for Ag43 expression, whereas dam mutants are locked off for Ag43 expression. We propose a novel mechanism for the regulation of phase switching in which OxyR competes with Dam for unmethylated GATC sites in the regulatory region of the agn43 gene.     

The flagellotropic bacteriophage YSD1 targets Salmonella Typhi with a Chi‐like protein tail fibre

The discovery of a Salmonella‐targeting phage from the waterways of the United Kingdom provided an opportunity to address the mechanism by which Chi‐like bacteriophage (phage) engages with bacterial flagellae. The long tail fibre seen on Chi‐like phages has been proposed to assist the phage particle in docking to a host cell flagellum, but the identity of the protein that generates this fibre was unknown. We present the results from genome sequencing of this phage, YSD1, confirming its close relationship to the original Chi phage and suggesting candidate proteins to form the tail structure. Immunogold labelling in electron micrographs revealed that YSD1_22 forms the main shaft of the tail tube, while YSD1_25 forms the distal part contributing to the tail spike complex. The long curling tail fibre is formed by the protein YSD1_29, and treatment of phage with the antibodies that bind YSD1_29 inhibits phage infection of Salmonella. The host range for YSD1 across Salmonella serovars is broad, but not comprehensive, being limited by antigenic features of the flagellin subunits that make up the Salmonella flagellum, with which YSD1_29 engages to initiate infection.     

Amplification of rfbE and fliC Genes by Polymerase Chain Reaction for Identification and Detection of Salmonella Serovar Enteritidis,Dublin and Gallinarum-Pullorum

Polymerase chain reaction (PCR) primers for O9 antigen (rfbE) and phase 1 flagellin antigen (fliC) were designed for the rapid identification and detection of Salmonella serovar Enteritidis and Dublin. The rfbE primer pairs selectively amplified the rfbE region of group O9 Salmonella serovars. The fliC primer pairs amplified the DNAs of g,m and g,p-type flagellar antigen; Salmonella serovar Enteritidis, Dublin, and Essen. However, DNA from flagellar-negative Salmonella serovar Gallinarum-Pullorum was also amplified. The sensitivity of PCR primer pairs was 10 CFU/assay by boiled DNA preparation and 10² CFU/assay by proteinase K-treated DNA preparation.