Detection of a disulphide bond and conformational changes in Shigella flexneri Wzy,and the role of cysteine residues in polymerase activity

Shigella flexneri utilises the Wzy-dependent pathway for the production of a plethora of complex polysaccharides, including the lipopolysaccharide O-antigen (Oag) component. The inner membrane protein Wzy_SF polymerises Oag repeat units, whilst two co-polymerase proteins, Wzz_SF and Wzz_pHS-2, together interact with Wzy_SF to regulate production of short- (S-Oag) and very long- (VL-Oag) Oag modal lengths, respectively. The 2D arrangement of Wzy_SF transmembrane and soluble regions has been previously deciphered, however, attaining information on the 3D structural and conformational arrangement of Wzy_SF, or any homologue, has proven difficult. For the first time, the current study detected insights into the in situ Wzy_SF arrangement. In vitro assays using thiol-reactive PEG-maleimide were used to probe Wzy_SF conformation, which additionally detected novel, unique conformational changes in response to interaction with intrinsic factors, including Wzz_SF and Wzz_pHS-2, and extrinsic factors, such as temperature. Site-directed mutagenesis of Wzy_SF cysteine residues revealed the presence of a putative intramolecular disulphide bond, between cysteine moieties 13 and 60. Subsequent analyses highlighted both the structural and functional importance of Wzy_SF cysteines. Substitution of Wzy_SF cysteine residues significantly decreased biosynthesis of the VL-Oag modal length, without disruption to S-Oag production. This phenotype was corroborated in the absence of co-polymerase competition for Wzy_SF interaction. These data suggest Wzy_SF cysteine substitutions directly impair the interaction between Wzy/Wzz_pHS-2, without altering the Wzy/Wzz_SF interplay, and in combination with structural data, we propose that the N- and C-termini of Wzy_SF are arranged in close proximity, and together may form the unique Wzz_pHS-2 interaction site.     

The D3 Bacteriophage α-Polymerase Inhibitor (Iap) Peptide Disrupts O-Antigen Biosynthesis through Mimicry of the Chain Length Regulator Wzz in Pseudomonas aeruginosa

Lysogenic bacteriophage D3 causes seroconversion of Pseudomonas aeruginosa PAO1 from serotype O5 to O16 by inverting the linkage between O-specific antigen (OSA) repeat units from α to β. The OSA units are polymerized by Wzy to modal lengths regulated by Wzz₁ and Wzz₂. A key component of the D3 seroconversion machinery is the inhibitor of α-polymerase (Iap) peptide, which is able to solely suppress α-linked long-chain OSA production in P. aeruginosa PAO1. To establish the target specificity of Iap for Wzy_α, changes in OSA phenotypes were examined via Western immunoblotting for wzz₁ and wzz₂ single-knockout strains, as well as a wzz₁ wzz₂ double knockout, following the expression of iap from a tuneable vector. Increased induction of Iap expression completely abrogated OSA production in the wzz₁ wzz₂ double mutant, while background levels of OSA production were still observed in either of the single mutants. Therefore, Iap inhibition of OSA biosynthesis was most effective in the absence of both Wzz proteins. Sequence alignment analyses revealed a high degree of similarity between Iap and the first transmembrane segment (TMS) of either Wzz₁ or Wzz₂. Various topology prediction analyses of the Iap sequence consistently predicted the presence of a single TMS, suggesting a propensity for Iap to insert itself into the inner membrane (IM). The compromised ability of Iap to abrogate Wzy_α function in the presence of Wzz₁ or Wzz₂ provides compelling evidence that inhibition occurs after Wzy_α inserts itself into the IM and is achieved through mimicry of the first TMS from the Wzz proteins of P. aeruginosa PAO1.     

Mutagenesis and Chemical Cross-Linking Suggest that Wzz Dimer Stability and Oligomerization Affect Lipopolysaccharide O-Antigen Modal Chain Length Control

In Shigella flexneri, the polysaccharide copolymerase (PCP) protein Wzz_SF confers a modal length of 10 to 17 repeat units (RUs) to the O-antigen (Oag) component of lipopolysaccharide (LPS). PCPs form oligomeric structures believed to be related to their function. To identify functionally important regions within Wzz_SF, random in-frame linker mutagenesis was used to create mutants with 5-amino-acid insertions (termed Wzz_i proteins), and DNA sequencing was used to locate the insertions. Analysis of the resulting LPS conferred by Wzz_i proteins identified five mutant classes. The class I mutants were inactive, resulting in nonregulated LPS Oag chains, while classes II and III conferred shorter LPS Oag chains of 2 to 10 and 8 to 14 RUs, respectively. Class IV mutants retained near-wild-type function, and class V mutants increased the LPS Oag chain length to 16 to 25 RUs. In vivo formaldehyde cross-linking indicated class V mutants readily formed high-molecular-mass oligomers; however, class II and III Wzz_i mutants were not effectively cross-linked. Wzz dimer stability was also investigated by heating cross-linked oligomers at 100°C in the presence of SDS. Unlike the Wzz_SF wild type and class IV and V Wzz_i mutants, the class II and III mutant dimers were not detectable. The location of each insertion was mapped onto available PCP three-dimensional (3D) structures, revealing that class V mutations were most likely located within the inner cavity of the PCP oligomer. These data suggest that the ability to produce stable dimers may be important in determining Oag modal chain length.Lipopolysaccharide (LPS) of Shigella flexneri is an important virulence factor, providing protection against host defenses and affecting interaction with host cells. LPS is composed of three regions: the hydrophobic lipid A membrane anchor, the core sugar region, and the O-antigen (Oag) polysaccharide chain (18). The basic Oag repeat unit of S. flexneri is a tetrasaccharide consisting of three rhamnose sugars and one N-acetylglucosamine sugar (19). The contribution of Shigella Oag to establishing virulence has been extensively investigated, and results indicate that regulated Oag modal length is required for virulence (8, 23, 25). Loss of Oag modal chain length regulation affects virulence due to the masking of the outer membrane (OM) protein IcsA (8, 23), and the type III secretion system is also affected by Oag chain length (24).The current model for Oag biogenesis in S. flexneri involves the initiation of Oag repeat unit synthesis on the cytoplasmic face of the inner membrane (IM) and continues with a series of successive sugar transferase reactions. The repeat units are assembled on the lipid carrier undecaprenol phosphate (Und-P), and transported across the IM by the Wzx flippase to the periplasmic face of the IM. Polymerization of Oag repeat units is catalyzed by the Wzy polymerase, linking the individual oligosaccharide repeat units into a chain; the nascent chain is transferred from its lipid carrier to the nonreducing end of the newly flipped oligosaccharide repeat unit. The resulting chain is then ligated to the lipid A core by WaaL ligase (18, 26) to form LPS.The regulation of the chain length of the Oag polysaccharide is controlled by the Wzz protein, a member of the polysaccharide copolymerase 1a (PCP1a) family (13, 21). S. flexneri Wzz (Wzz_SF) confers an average chain modal length of 10 to 17 Oag repeat units. In addition to determining the Oag chain modal length, PCP proteins are involved in enterobacterial common antigen (ECA) modal chain length regulation and biosynthesis and in capsule polysaccharide (CPS) and exopolysaccharide (EPS) biosynthesis (13). The PCP1a proteins are located in the IM and have two transmembrane (TM) regions, TM1 and TM2 (14). TM1 is located close to the N-terminal end, and TM2 is located near the C-terminal end, while the hydrophilic region between TM regions is located in the periplasm (14). PCPs exhibit a conserved motif, proximal to and partly overlapping the TM2 region, rich in proline and glycine residues (2, 3, 13). Site-directed mutagenesis studies targeting a number of these conserved residues, singularly or in combination, indicate that changes to this region have a significant effect on the resulting Oag modal chain length (4). Many mutagenesis studies on residues throughout Wzz indicate that function may be an overall property of the protein and may not be limited to one particular region (4, 6, 21). Despite studies conducted to probe the Wzz structure function relationship, little is known about the mode of action in determining Oag modal chain length. Recently, the periplasmic domain structures of a collection of PCP proteins including Salmonella enterica serovar Typhimurium WzzB (Wzz_ST) and Escherichia coli O157 FepE and WzzE have been solved, and it has been deduced that these structures show marked similarities at the protomer and oligomer levels (21). These protomers are elongated and consist of two structural components: a trapezoidal α/β base domain close to the membrane and an extended α-helical hairpin containing an ∼100-Å-long helix forming anti-parallel coiled-coil interactions with two helices that fold back toward the membrane (21). The protomers self-assemble into bell-shaped oligomers displaying comparable structural features, with Wzz_ST forming pentameric oligomers, WzzE assembling into octameric oligomers, and FepE assembling into nonameric structures (21). In contrast, a recent study from Larue et al. reports that Wzz_ST, FepE, and Wzz_K40 favor hexameric structures (9). A previous study on the oligomeric status of S. flexneri WzzB (Wzz_SF) via in vivo cross-linking with formaldehyde indicated that Wzz_SF has the ability to form hexamers and high-order oligomers, suggesting that oligomerization is important in function (4). Related to this, Marolda et al. have shown that the ECA-associated Wzx can fully complement an LPS Oag-associated Wzx-deficient mutant if the remaining ECA gene cluster is deleted, providing genetic evidence that proteins involved in Oag/ECA biosynthesis and processing may function as a complex (11).Several models of the likely mechanisms of Oag chain regulation have been proposed. Bastin et al. initially suggested that Wzz acts as a molecular timer, allowing polymerization to occur to a particular point, hence increasing the number of repeat units added to the chain (1). An alternative model proposed by Morona et al. suggested that Wzz acts as a molecular chaperone, facilitating the interaction between Wzy and WaaL, and modal length is the result of the ratio of Wzy and WaaL (14). Published data indicated that the ratio of Wzy and Wzz was important in determining Oag modal chain length, which is supportive of the latter model (5). With recent developments in solving the PCP three-dimensional (3D) structure and oligomeric arrangement, a new model has been proposed by Tocilj et al. in which the Wzz oligomers act as molecular scaffolds for multiple Wzy polymerase molecules and the growing Oag chain is transferred from one Wzy to another Wzy molecule (21).In a previous study, site-directed mutagenesis analysis was conducted on Wzz_SF (4). Although mutational alterations targeting the TM regions caused dramatic changes in the resulting LPS Oag chain length, mutations targeting the periplasmic domain generally did not have an obvious effect on the resulting LPS Oag chain length. This was also shown for mutations in FepE (17). Hence, we decided that a more severe approach to Wzz_SF mutagenesis was needed to investigate the relationship between Wzz structure and function by increasing the likelihood of acquiring Wzz mutants displaying phenotypic changes. In this study, we have investigated the structure and function of Wzz_SF by constructing a library of in-frame linker mutants with 5-amino-acid (aa) insertions throughout the Wzz_SF protein. We have identified regions in Wzz_SF which alter the modal length in different ways and present biochemical evidence acquired by in vivo chemical cross-linking that indicates oligomeric differences exist between Wzz mutants and the wild type (WT). We also present evidence that suggests the dimeric form of Wzz_SF is important in establishing modal length.     

Molecular Analysis of the O-Antigen Gene Cluster of Escherichia coli O86:B7 and Characterization of the Chain Length Determinant Gene (wzz)

Escherichia coli O86:B7 has long been used as a model bacterial strain to study the generation of natural blood group antibody in humans, and it has been shown to possess high human blood B activity. The O-antigen structure of O86:B7 was solved recently in our laboratory. Comparison with the published structure of O86:H2 showed that both O86 subtypes shared the same O unit, yet each of the O antigens is polymerized from a different terminal sugar in a different glycosidic linkage. To determine the genetic basis for the O-antigen differences between the two O86 strains, we report the complete sequence of O86:B7 O-antigen gene cluster between galF and hisI, each gene was identified based on homology to other genes in the GenBank databases. Comparison of the two O86 O-antigen gene clusters revealed that the encoding regions between galF and gnd are identical, including wzy genes. However, deletion of the two wzy genes revealed that wzy in O86:B7 is responsible for the polymerization of the O antigen, while the deletion of wzy in O86:H2 has no effect on O-antigen biosynthesis. Therefore, we proposed that there must be another functional wzy gene outside the O86:H2 O-antigen gene cluster. Wzz proteins determine the degree of polymerization of the O antigen. When separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the lipopolysaccharide (LPS) of O86:B7 exhibited a modal distribution of LPS bands with relatively short O units attached to lipid A-core, which differs from the LPS pattern of O86:H2. We proved that the wzz genes are responsible for the different LPS patterns found in the two O86 subtypes, and we also showed that the very short type of LPS is responsible for the serum sensitivity of the O86:B7 strain.     

Clinical and Veterinary Isolates of Salmonella enterica Serovar Enteritidis Defective in Lipopolysaccharide O-Chain Polymerization

Twelve human and chicken isolates of Salmonella enterica serovar Enteritidis belonging to phage types 4, 8, 13a, and 23 were characterized for variability in lipopolysaccharide (LPS) composition. Isolates were differentiated into two groups, i.e., those that lacked immunoreactive O-chain, termed rough isolates, and those that had immunoreactive O-chain, termed smooth isolates. Isolates within these groups could be further differentiated by LPS compositional differences as detected by gel electrophoresis and gas liquid chromatography of samples extracted with water, which yielded significantly more LPS in comparison to phenol-chloroform extraction. The rough isolates were of two types, the O-antigen synthesis mutants and the O-antigen polymerization (wzy) mutants. Smooth isolates were also of two types, one producing low-molecular-weight (LMW) LPS and the other producing high-molecular-weight (HMW) LPS. To determine the genetic basis for the O-chain variability of the smooth isolates, we analyzed the effects of a null mutation in the O-chain length determinant gene, wzz (cld) of serovar Typhimurium. This mutation results in a loss of HMW LPS; however, the LMW LPS of this mutant was longer and more glucosylated than that from clinical isolates of serovar Enteritidis. Cluster analysis of these data and of those from two previously characterized isogenic strains of serovar Enteritidis that had different virulence attributes indicated that glucosylation of HMW LPS (via oafR function) is variable and results in two types of HMW structures, one that is highly glucosylated and one that is minimally glucosylated. These results strongly indicate that naturally occurring variability in wzy, wzz, and oafR function can be used to subtype isolates of serovar Enteritidis during epidemiological investigations.     

Overexpression and topology of the Shigella flexneri O-antigen polymerase (Rfc/Wzy)

Lipopolysaccharides (LPS), particularly the O-antigen component, are one of many virulence determinants necessary for Shigella flexneri pathogenesis. O-antigen biosynthesis is determined mostly by genes located in the rfb region of the chromosome. The rfc/wzy gene encodes the O-antigen polymerase, an integral membrane protein, which polymerizes the O-antigen repeat units of the LPS. The wild-type rfc/wzy gene has no detectable ribosome-binding site (RBS) and four rare codons in the translation initiation region (TIR). Site-directed mutagenesis of the rare codons at positions 4, 9 and 23 to those corresponding to more abundant tRNAs and introduction of a RBS allowed detection of the rfc/wzy gene product via a T7 promoter/polymerase expression assay. Complementation studies using the rfc/wzy constructs allowed visualization of a novel LPS with unregulated O-antigen chain length distribution, and a modal chain length could be restored by supplying the gene for the O-antigen chain length regulator (Rol/Wzz) on a low-copy-number plasmid. This suggests that the O-antigen chain length distribution is determined by both Rfc/Wzy and Rol/Wzz proteins. The effect on translation of mutating the rare codons was determined using an Rfc::PhoA fusion protein as a reporter. Alkaline phosphatase enzyme assays showed an approximately twofold increase in expression when three of the rare codons were mutated. Analysis of the Rfc/Wzy amino acid sequence using TM-PREDICT indicated that Rfc/Wzy had 10–13 transmembrane segments. The computer prediction models were tested by genetically fusing C-terminal deletions of Rfc/Wzy to alkaline phosphatase and β-galactosidase. Rfc::PhoA fusion proteins near the amino-terminal end were detected by Coomassie blue staining and Western blotting using anti-PhoA serum. The enzyme activities of cells with the rfc/wzy fusions and the location of the fusions in rfc/wzy indicated that Rfc/Wzy has 12 transmembrane segments with two large periplasmic domains, and that the amino- and carboxy-termini are located on the cytoplasmic face of the membrane.     

Relationships among the O-Antigen Gene Clusters of Salmonella enterica Groups B, D1, D2, and D3

The O antigen is an important cell wall antigen of gram-negative bacteria, and the genes responsible for its biosynthesis are located in a gene cluster. We have cloned and sequenced the DNA segment unique to the O-antigen gene cluster of Salmonella enterica group D3. This segment includes a novel O-antigen polymerase gene (wzy_D3). The polymerase gives α(1→6) linkages but has no detectable sequence similarity to that of group D2, which confers the same linkage. We find the remnant of a D3-like wzy gene in the O-antigen gene clusters of groups D1 and B and suggest that this is the original wzy gene of these O-antigen gene clusters.     

Characterization of the O-antigen Polymerase (Wzy) of Francisella tularensis

The O-antigen polymerase of Gram-negative bacteria has been difficult to characterize. Herein we report the biochemical and functional characterization of the protein product (Wzy) of the gene annotated as the putative O-antigen polymerase, which is located in the O-antigen biosynthetic locus of Francisella tularensis. In silico analysis (homology searching, hydropathy plotting, and codon usage assessment) strongly suggested that Wzy is an O-antigen polymerase whose function is to catalyze the addition of newly synthesized O-antigen repeating units to a glycolipid consisting of lipid A, inner core polysaccharide, and one repeating unit of the O-polysaccharide (O-PS). To characterize the function of the Wzy protein, a non-polar deletion mutant of wzy was generated by allelic replacement, and the banding pattern of O-PS was observed by immunoblot analysis of whole-cell lysates obtained by SDS-PAGE and stained with an O-PS-specific monoclonal antibody. These immunoblot analyses showed that O-PS of the wzy mutant expresses only one repeating unit of O-antigen. Further biochemical characterization of the subcellular fractions of the wzy mutant demonstrated that (as is characteristic of O-antigen polymerase mutants) the low molecular weight O-antigen accumulates in the periplasm of the mutant. Site-directed mutagenesis based on protein homology and topology, which was carried out to locate a catalytic residue of the protein, showed that modification of specific residues (Gly¹⁷⁶, Asp¹⁷⁷, Gly³²³, and Tyr³²⁴) leads to a loss of O-PS polymerization. Topology models indicate that these amino acids most likely lie in close proximity on the bacterial surface.     

Dam Methylation Participates in the Regulation of PmrA/PmrB and RcsC/RcsD/RcsB Two Component Regulatory Systems in Salmonella enterica Serovar Enteritidis

The absence of Dam in Salmonella enterica serovar Enteritidis causes a defect in lipopolysaccharide (LPS) pattern associated to a reduced expression of wzz gene. Wzz is the chain length regulator of the LPS O-antigen. Here we investigated whether Dam regulates wzz gene expression through its two known regulators, PmrA and RcsB. Thus, the expression of rcsB and pmrA was monitored by quantitative real-time RT-PCR and Western blotting using fusions with 3×FLAG tag in wild type (wt) and dam strains of S. Enteritidis. Dam regulated the expression of both rcsB and pmrA genes; nevertheless, the defect in LPS pattern was only related to a diminished expression of RcsB. Interestingly, regulation of wzz in serovar Enteritidis differed from that reported earlier for serovar Typhimurium; RcsB induces wzz expression in both serovars, whereas PmrA induces wzz in S. Typhimurium but represses it in serovar Enteritidis. Moreover, we found that in S. Enteritidis there is an interaction between both wzz regulators: RcsB stimulates the expression of pmrA and PmrA represses the expression of rcsB. Our results would be an example of differential regulation of orthologous genes expression, providing differences in phenotypic traits between closely related bacterial serovars.     

Modulation of O‐antigen chain length by the wzz gene in Escherichia coli O157 influences its sensitivities to serum complement

Escherichia coli O157 strains belonging to a distinct lineage and expressing different O‐antigen (Oag) lengths were isolated. Although the function of wzz in E. coli has not been adequately investigated, this gene is known to be associated with regulation of Oag length. Using E. coli O157:H7 ATCC43888 (wild‐type), several wzz mutants of E. coli O157, including a wzz deletion mutant, were generated and the relationship between the length of Oag modulated by the wzz gene and sensitivities to serum complement investigated. SDS–PAGE, immunoblot analyses and sensitivity tests to human serum complement were performed on these strains. The lengths of the O157‐antigen could be modulated by the wzz gene mutations and were classified into long, intermediate and short groups. The short chain mutant was more serum sensitive than the wild‐type strain and the other wzz mutants (P < 0.001). In conclusion, Oag chain length modulated by the wzz gene in E. coli O157 influences its sensitivities to serum complement. The present findings suggest that E. coli O157 strains with intermediate or long length Oag chains might show greater resistance to serum complement than those with short chains.     

Structural and Biochemical Analysis of a Single Amino-Acid Mutant of WzzBSF That Alters Lipopolysaccharide O-Antigen Chain Length in Shigella flexneri

Lipopolysaccharide (LPS), a surface polymer of Gram-negative bacteria, helps bacteria survive in different environments and acts as a virulence determinant of host infection. The O-antigen (Oag) component of LPS exhibits a modal chain-length distribution that is controlled by polysaccharide co-polymerases (PCPs). The molecular basis of the regulation of Oag chain-lengths remains unclear, despite extensive mutagenesis and structural studies of PCPs from Escherichia coli and Shigella. Here, we identified a single mutation (A107P) of the Shigella flexneri WzzB_SF, by a random mutagenesis approach, that causes a shortened Oag chain-length distribution in bacteria. We determined the crystal structures of the periplasmic domains of wild-type WzzB_SF and the A107P mutant. Both structures form a highly similar open trimeric assembly in the crystals, and show a similar tendency to self-associate in solution. Binding studies by bio-layer interferometry reveal cooperative binding of very short (VS)-core-plus-O-antigen polysaccharide (COPS) to the periplasmic domains of both proteins, but with decreased affinity for the A107P mutant. Our studies reveal that subtle and localized structural differences in PCPs can have dramatic effects on LPS chain-length distribution in bacteria, for example by altering the affinity for the substrate, which supports the role of the structure of the growing Oag polymer in this process.     

The Wzz (Cld) Protein in Escherichia coli: Amino Acid Sequence Variation Determines O-Antigen Chain Length Specificity

The O antigen is a polymer with a repeated unit. The chain length in most Escherichia coli strains has a modal value of 10 to 18 O units, but other strains have higher or lower modal values. wzz (cld/rol) mutants have a random chain length distribution, showing that the modal distribution is determined by the Wzz protein. Cloned wzz genes from E. coli strains with short (7 to 16), intermediate (10 to 18), and long (16 to 25) modal chain lengths were transferred to a model system, and their effects on O111 antigen were studied. The O111 chain length closely resembled that of the parent strains. We present data based on the construction of chimeric wzz genes and site-directed mutagenesis of the wzz gene to show that the modal value of O-antigen chain length of E. coli O1, O2, O7, and O157 strains can be changed by specific amino acid substitutions in wzz. It is concluded that the O-antigen chain length heterogeneity in E. coli strains is the result of amino acid sequence variation of the Wzz protein.     

Fruit softening: evidence for pectate lyase action in vivo in date (Phoenix dactylifera) and rosaceous fruit cell walls

Background and AimsThe programmed softening occurring during fruit development requires scission of cell wall polysaccharides, especially pectin. Proposed mechanisms include the action of wall enzymes or hydroxyl radicals. Enzyme activities found in fruit extracts include pectate lyase (PL) and endo-polygalacturonase (EPG), which, in vitro, cleave de-esterified homogalacturonan in mid-chain by β-elimination and hydrolysis, respectively. However, the important biological question of whether PL exhibits action in vivo had not been tested.MethodsWe developed a method for specifically and sensitively detecting in-vivo PL products, based on Driselase digestion of cell wall polysaccharides and detection of the characteristic unsaturated product of PL action.Key ResultsIn model in-vitro experiments, pectic homogalacturonan that had been partially cleaved by commercial PL was digested to completion with Driselase, releasing an unsaturated disaccharide (‘ΔUA–GalA’), taken as diagnostic of PL action. ΔUA–GalA was separated from saturated oligogalacturonides (EPG products) by electrophoresis, then subjected to thin-layer chromatography (TLC), resolving ΔUA–GalA from higher homologues. The ΔUA–GalA was confirmed as 4-deoxy-β-l-threo-hex-4-enopyranuronosyl-(1→4)-d-galacturonic acid by NMR spectroscopy. Driselase digestion of cell walls from ripe fruits of date (Phoenix dactylifera), pear (Pyrus communis), rowan (Sorbus aucuparia) and apple (Malus pumila) yielded ΔUA–GalA, demonstrating that PL had been acting in vivo in these fruits prior to harvest. Date-derived ΔUA–GalA was verified by negative-mode mass spectrometry, including collision-induced dissociation (CID) fragmentation. The ΔUA–GalA:GalA ratio from ripe dates was roughly 1:20 (mol mol^–1), indicating that approx. 5 % of the bonds in endogenous homogalacturonan had been cleaved by in-vivo PL action.ConclusionsThe results provide the first demonstration that PL, previously known from studies of fruit gene expression, proteomic studies and in-vitro enzyme activity, exhibits enzyme action in the walls of soft fruits and may thus be proposed to contribute to fruit softening.     

LPS Structure and PhoQ Activity Are Important for Salmonella Typhimurium Virulence in the Gallleria mellonella Infection Model

The larvae of the wax moth, Galleria  mellonella , have been used experimentally to host a range of bacterial and fungal pathogens. In this study we evaluated the suitability of G . mellonella as an alternative animal model of Salmonella infection. Using a range of inoculum doses we established that the LD₅₀ of Salmonella Typhimurium strain NCTC 12023 was 3.6 × 10³ bacteria per larva. Further, a set of isogenic mutant strains depleted of known virulence factors was tested to identify determinants essential for S . Typhimurium pathogenesis. Mutants depleted of one or both of the type III secretion systems encoded by Salmonella Pathogenicity Islands 1 and 2 showed no virulence defect. In contrast, we observed reduced pathogenic potential of a phoQ mutant indicating an important role for the PhoPQ two-component signal transduction system. Lipopolysaccharide (LPS) structure was also shown to influence Salmonella virulence in G . mellonella . A waaL (rfaL) mutant, which lacks the entire O-antigen (OAg), was virtually avirulent, while a wzz _ST/wzz _fepE double mutant expressing only a very short OAg was highly attenuated for virulence. Furthermore, shortly after infection both LPS mutant strains showed decreased replication when compared to the wild type in a flow cytometry-based competitive index assay. In this study we successfully established a G . mellonella model of S . Typhimurium infection. By identifying PhoQ and LPS OAg length as key determinants of virulence in the wax moth larvae we proved that there is an overlap between this and other animal model systems, thus confirming that the G . mellonella infection model is suitable for assessing aspects of Salmonella virulence function.     

Molecular analysis of the O-antigen gene cluster of Escherichia coli O86:B7 and characterization of the chain length determinant gene (wzz)

Escherichia coli O86:B7 has long been used as a model bacterial strain to study the generation of natural blood group antibody in humans, and it has been shown to possess high human blood B activity. The O-antigen structure of O86:B7 was solved recently in our laboratory. Comparison with the published structure of O86:H2 showed that both O86 subtypes shared the same O unit, yet each of the O antigens is polymerized from a different terminal sugar in a different glycosidic linkage. To determine the genetic basis for the O-antigen differences between the two O86 strains, we report the complete sequence of O86:B7 O-antigen gene cluster between galF and hisI, each gene was identified based on homology to other genes in the GenBank databases. Comparison of the two O86 O-antigen gene clusters revealed that the encoding regions between galF and gnd are identical, including wzy genes. However, deletion of the two wzy genes revealed that wzy in O86:B7 is responsible for the polymerization of the O antigen, while the deletion of wzy in O86:H2 has no effect on O-antigen biosynthesis. Therefore, we proposed that there must be another functional wzy gene outside the O86:H2 O-antigen gene cluster. Wzz proteins determine the degree of polymerization of the O antigen. When separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the lipopolysaccharide (LPS) of O86:B7 exhibited a modal distribution of LPS bands with relatively short O units attached to lipid A-core, which differs from the LPS pattern of O86:H2. We proved that the wzz genes are responsible for the different LPS patterns found in the two O86 subtypes, and we also showed that the very short type of LPS is responsible for the serum sensitivity of the O86:B7 strain.     

Development of PCR Assays Targeting Genes in O-Antigen Gene Clusters for Detection and Identification of Escherichia coli O45 and O55 Serogroups

The Escherichia coli O45 O-antigen gene cluster of strain O45:H2 96-3285 was sequenced, and conventional (singleplex), multiplex, and real-time PCR assays were designed to amplify regions in the wzx (O-antigen flippase) and wzy (O-antigen polymerase) genes. In addition, PCR assays targeting the E. coli O55 wzx and wzy genes were designed based on previously published sequences. PCR assays targeting E. coli O45 showed 100% specificity for this serogroup, whereas by PCR assays specific for E. coli O55, 97/102 strains serotyped as E. coli O55 were positive for wzx and 98/102 for wzy. Multiplex PCR assays targeting the E. coli O45 and the E. coli O55 wzx and wzy genes were used to detect the organisms in fecal samples spiked at levels of 10⁶ and 10⁸ CFU/0.2 g feces. Thus, the PCR assays can be used to detect and identify E. coli serogroups O45 and O55.     

Structural Analysis of the Core Region of O-Lipopolysaccharide of Porphyromonas gingivalis from Mutants Defective in O-Antigen Ligase and O-Antigen Polymerase

Porphyromonas gingivalis synthesizes two lipopolysaccharides (LPSs), O-LPS and A-LPS. Here, we elucidate the structure of the core oligosaccharide (OS) of O-LPS from two mutants of P. gingivalis W50, ΔPG1051 (WaaL, O-antigen ligase) and ΔPG1142 (O-antigen polymerase), which synthesize R-type LPS (core devoid of O antigen) and SR-type LPS (core plus one repeating unit of O antigen), respectively. Structural analyses were performed using one-dimensional and two-dimensional nuclear magnetic resonance spectroscopy in combination with composition and methylation analysis. The outer core OS of O-LPS occurs in two glycoforms: an “uncapped core,” which is devoid of O polysaccharide (O-PS), and a “capped core,” which contains the site of O-PS attachment. The inner core region lacks l(d)-glycero-d(l)-manno-heptosyl residues and is linked to the outer core via 3-deoxy-d-manno-octulosonic acid, which is attached to a glycerol residue in the outer core via a monophosphodiester bridge. The outer region of the “uncapped core” is attached to the glycerol and is composed of a linear α-(1→3)-linked d-Man OS containing four or five mannopyranosyl residues, one-half of which are modified by phosphoethanolamine at position 6. An amino sugar, α-d-allosamine, is attached to the glycerol at position 3. In the “capped core,” there is a three- to five-residue extension of α-(1→3)-linked Man residues glycosylating the outer core at the nonreducing terminal residue. β-d-GalNAc from the O-PS repeating unit is attached to the nonreducing terminal Man at position 3. The core OS of P. gingivalis O-LPS is therefore a highly unusual structure, and it is the basis for further investigation of the mechanism of assembly of the outer membrane of this important periodontal bacterium.Porphyromonas gingivalis is a gram-negative anaerobe which is strongly implicated in the etiology of periodontal disease. Several putative virulence factors are produced by this organism. These virulence factors include the cysteine proteases Arg-gingipains (Rgps) and Lys-gingipain (Kgp) specific for Arg-X and Lys-X peptide bonds, respectively, which are capable of degrading several host proteins (56), and lipopolysaccharide (LPS), which has the potential to cause an inflammatory response in the periodontal tissues of the host. These factors are important antigens in patients with periodontal disease and may account for a considerable proportion of the immune response directed against P. gingivalis (58).LPS is a major constituent of the outer membrane of gram-negative bacteria and facilitates interactions with the external environment. It consists of three regions: a hydrophobic lipid A embedded in the outer leaflet of the outer membrane, a core oligosaccharide (OS), and the O-polysaccharide (O-PS) side chain composed of several repeating units. The hydrophobic lipid A serves as an anchor for the LPS and consists of β-1,6-linked d-glucosamine disaccharide, which is usually phosphorylated at the 1 and/or 4′ positions and N and/or O acylated at positions 2, 3, 2′, and 3′ with various amounts of fatty acids. The rest of the LPS molecule projects from the surface. The core region is attached to lipid A and is composed of ∼10 sugars in most bacteria studied to date and can be further subdivided into an inner core and an outer core. The inner core usually contains l(d)-glycero-d-(l)-manno-heptose and 3-deoxy-d-manno-octulosonic acid (Kdo) residues, whereas the outer core is usually composed of hexoses. Attached to the outer core are the repeating units of O antigen (O-PS), which vary in composition, stereochemistry, and the sequence of O-glycosidic linkages between bacterial strains and thereby give rise to O-serotype specificity within bacterial species. Attachment of O antigen to core lipid A results in “smooth” LPS (S-type LPS), whereas LPS lacking O antigen is “rough” LPS (R-type LPS). Attachment of one repeating unit of O-PS to core lipid A results in SR-LPS (core-plus-one repeating unit) (41, 47, 48). In addition, the outer core OS region can be either “uncapped” or “capped.” The “uncapped” core OS is devoid of O-PS repeating units, whereas the “capped” core OS contains attached O-PS repeating units (47, 53) due to modifications in the outer core region.P. gingivalis W50 was originally thought to synthesize a single LPS composed of a tetrasaccharide repeating unit in the O-PS, [→6)-α-d-Glcp-(1→4)-α-l-Rhap-(1→3)-β-d-GalNAc-(1→3)-α-d-Galp-(1→], which is modified by phosphoethanolamine (PEA) at position 2 of Rha in a nonstoichiometric manner (43). However, a second LPS in this organism, namely A-LPS (49), which has a phosphorylated mannan-containing anionic polysaccharide (A-PS), was identified in our laboratory. The A-PS repeating unit is built up of a phosphorylated branched d-Man-containing oligomer composed of an α1→6-linked d-mannose backbone to which α1→2-linked d-Man side chains of different lengths (one or two residues) are attached at position 2. One of the side chains contains Manα1→2-Manα-1-phosphate linked via phosphorus to a backbone Man residue at position O-2. Although A-LPS is predominantly composed of α-d-mannose residues, it cannot be referred to as a homopolymer due to the presence of Manα1→2Manα1-phosphate-containing OS side chains forming a nonglycosidic linkage between the backbone α-mannose and side chains. Hence, it is likely that the synthesis of A-PS (A-LPS) occurs via a “wzy-dependent” pathway in which repeating units formed on the cytoplasmic face of the inner membrane are polymerized at the periplasmic face following transport or flipping across the cytoplasmic membrane. A-LPS cross-reacts with monoclonal antibody (MAb) 1B5 raised against one of the isoforms of Arg-gingipains, a family of differentially glycosylated cysteine proteases (14, 19). Deglycosylation of the cross-reacting Rgps with anhydrous trifluoromethane sulfonic acid abolishes their immunoreactivity to MAb 1B5, indicating that this antibody recognizes a carbohydrate-containing epitope also present in A-LPS (14, 44). Hence, there appear to be common elements in the biosynthesis of A-LPS and the Arg-gingipains of this organism.Inactivation of P. gingivalis waaL (PG1051, O-antigen ligase) abolishes the synthesis of both O-LPS and A-LPS (49). Hence, the WaaL O-antigen ligase appears to have dual specificity and is capable of ligating both O-PS and A-PS chains to core lipid A. The dual specificity of WaaL in the final step of LPS biosynthesis has also been demonstrated in the synthesis of Escherichia coli O-LPS and M_LPS (38) and for Pseudomonas aeruginosa A-band and B-band LPSs (1).However, the linkage between O-PS and A-PS and core OS has not been identified in P. gingivalis. In this paper, we describe a structural investigation of the core OS of O-LPS in which we used R-LPS prepared from ΔPG1051 (49) and ΔPG1142 (putative O-antigen polymerase), which we hypothesized would synthesize an SR-LPS (core plus one repeating unit) (60). The putative O-antigen polymerase encoded at PG1142 (42) is a phenylalanine-rich membrane protein consisting of 347 amino acids which shows 46% similarity over 297 amino acids to EpsK of Lactobacillus delbrueckii subsp. bulgaricus. EpsK is proposed to be a polymerase on the basis of homology and topological similarity to the O-antigen polymerase (Wzy) of E. coli and is required for the synthesis of an exopolysaccharide composed of Gal, Glc, and Rha (5:1:1) containing repeating units in L. delbrueckii (32). Application of one-dimensional (1D) and two-dimensional (2D) nuclear magnetic resonance (NMR) spectroscopy and methylation and monosaccharide analyses using gas chromatography-mass spectrometry (GC-MS) to purified core-containing OSs isolated from LPS from ΔPG1051 and ΔPG1142 mutants enabled us to solve the LPS core structure of an oral gram-negative bacterium for the first time.     

LPS Unmasking of Shigella flexneri Reveals Preferential Localisation of Tagged Outer Membrane Protease IcsP to Septa and New Poles

The Shigella flexneri outer membrane (OM) protease IcsP (SopA) is a member of the enterobacterial Omptin family of proteases which cleaves the polarly localised OM protein IcsA that is essential for Shigella virulence. Unlike IcsA however, the specific localisation of IcsP on the cell surface is unknown. To determine the distribution of IcsP, a haemagglutinin (HA) epitope was inserted into the non-essential IcsP OM loop 5 using Splicing by Overlap Extension (SOE) PCR, and IcsP^HA was characterised. Quantum Dot (QD) immunofluorescence (IF) surface labelling of IcsP^HA was then undertaken. Quantitative fluorescence analysis of S. flexneri 2a 2457T treated with and without tunicaymcin to deplete lipopolysaccharide (LPS) O antigen (Oag) showed that IcsP^HA was asymmetrically distributed on the surface of septating and non-septating cells, and that this distribution was masked by LPS Oag in untreated cells. Double QD IF labelling of IcsP^HA and IcsA showed that IcsP^HA preferentially localised to the new pole of non-septating cells and to the septum of septating cells. The localisation of IcsP^HA in a rough LPS S. flexneri 2457T strain (with no Oag) was also investigated and a similar distribution of IcsP^HA was observed. Complementation of the rough LPS strain with rmlD resulted in restored LPS Oag chain expression and loss of IcsP^HA detection, providing further support for LPS Oag masking of surface proteins. Our data presents for the first time the distribution for the Omptin OM protease IcsP, relative to IcsA, and the effect of LPS Oag masking on its detection.     

Detection of Escherichia coli Serogroups O26 and O113 by PCR Amplification of the wzx and wzy Genes

PCR-based assays for detecting enterohemorrhagic Escherichia coli serogroups O26 and O113 were developed by targeting the wzx (O-antigen flippase) and the wzy (O-antigen polymerase) genes found in the O-antigen gene cluster of each organism. The PCR assays were specific for the respective serogroups, as there was no amplification of DNA from non-O26 and non-O113 E. coli serogroups or from other bacterial genera tested. Using the PCR assays, we were able to detect the organisms in seeded apple juice inoculated at concentration levels as low as ≤10 CFU/ml. The O26- and O113-specific PCR assays can potentially be used for typing E. coli O26 and O113 serogroups; these assays will offer an advantage to food and environmental microbiology laboratories in terms of identifying these non-O157 serogroups by replacing antigen-based serotyping.