ALBERT

Notes: WbpM is essential for the biosynthesis of B-band lipopolysaccharide (LPS) in many serotypes of Pseudomonas aeruginosa. Homologues that can functionally complement a wbpM null mutant and that are also necessary for virulence have been identified in numerous pathogenic bacteria. WbpM and most of its homologues are large membrane proteins, which has long hampered the elucidation of their biochemical function. This paper describes the detailed characterization of WbpM using both in vivo and in vitro approaches. LacZ and PhoA fusion experiments showed that WbpM was anchored to the inner membrane via four N-terminal transmembrane domains, whereas the C-terminal catalytic domain resided in the cytoplasm. Although the membrane domains did not have any catalytic activity, complementation experiments suggested that they were important for the polymerization of high-molecular-weight B-band LPS. The biochemical characterization of a soluble truncated form of WbpM, His-S262, showed that WbpM was a C6 dehydratase specific for UDP-GlcNAc. It exhibited unusual low temperature (25–30°C) and high pH (pH 10) optima. Although WbpM possessed an altered catalytic triad composed of SMK as opposed to SYK commonly found in other dehydratases, its catalysis was very efficient, with a kcat of 168 min−1 and a kcat/Km of 58 mM−1 min−1. These unusual physico-kinetic properties suggested a potentially different mechanism of C6 dehydration for WbpM and its large homologues. His-S262 is now a precious tool for further structure–function studies.

Notes: Pseudomonas aeruginosa is an opportunistic pathogen capable of producing a wide variety of virulence factors, including extracellular rhamnolipids and lipopolysaccharide. Rhamnolipids are tenso-active glycolipids containing one (mono-rhamnolipid) or two (di-rhamnolipid) l-rhamnose molecules. Rhamnosyltransferase 1 (RhlAB) catalyses the synthesis of mono-rhamnolipid from dTDP-l-rhamnose and β-hydroxydecanoyl-β-hydroxydecanoate, whereas di-rhamnolipid is produced from mono-rhamnolipid and dTDP-l-rhamnose. We report here the molecular characterization of rhlC, a gene encoding the rhamnosyltransferase involved in di-rhamnolipid (l-rhamnose-l-rhamnose-β-hydroxydecanoyl-β-hydroxydecanoate) production in P. aeruginosa. RhlC is a protein consisting of 325 amino acids with a molecular mass of 35.9 kDa. It contains consensus motifs that are found in other glycosyltransferases involved in the transfer of l-rhamnose to nascent polymer chains. To verify the biological function of RhlC, a chromosomal mutant, RTII-2, was generated by insertional mutagenesis and allelic replacement. This mutant was unable to produce di-rhamnolipid, whereas mono-rhamnolipid was unaffected. In contrast, a null rhlA mutant (PAO1-rhlA) was incapable of producing both mono- and di-rhamnolipid. Complementation of mutant RTII-2 with plasmid pRTII-26 containing rhlC restored the level of di-rhamnolipid production in the recombinant to a level similar to that of the wild-type strain PAO1. The rhlC gene was located in an operon with an upstream gene (PA1131) of unknown function. A σ54-type promoter for the PA1131–rhlC operon was identified, and a single transcriptional start site was mapped. Expression of the PA1131–rhlC operon was dependent on the P. aeruginosa rhl quorum-sensing system, and a well-conserved lux box was identified in the promoter region. The genetic regulation of rhlC by RpoN and RhlR was in agreement with the observed increasing RhlC rhamnosyltransferase activity during the stationary phase of growth. This is the first report of a rhamnosyltransferase gene responsible for the biosynthesis of di-rhamnolipid.

Notes: Pseudomonas aeruginosa is an opportunistic pathogen that is notorious for its intrinsic drug resistance. We have used chemical and genetic techniques to characterize three putative kinase genes that are involved in the addition of phosphate to the inner core region of P. aeruginosa lipopolysaccharide. The first gene is a waaP homologue, whereas the other two (wapP and wapQ) are unique to P. aeruginosa. Repeated attempts using a variety of membrane-stabilizing conditions to generate waaP::Gm (Gm, gentamicin) or wapP::Gm mutants were unsuccessful. We were able to generate a chromosomal waaP mutant that had a wild-type copy of either waaPPa or waaPEcin trans, but were unable to cure this plasmid-borne copy of the gene. These results are consistent with the fact that P. aeruginosa mutants lacking inner core heptose (Hep) or phosphate have never been isolated and demonstrate the requirement of Hep-linked phosphate for P. aeruginosa viability. A wapQ::Gm mutant was isolated and it had an unaltered minimum inhibitory concentration (MIC) for novobiocin and only a small decrease in the MIC for sodium dodecyl sulphate (SDS), suggesting that the loss of a phosphate group transferred by WapQ may only be having a small impact on outer-membrane permeability. Nuclear magnetic resonance and methylation linkage analysis showed that WaaPPa could add one phosphate to O4 of HepI in a Salmonella typhimurium waaP mutant. The expression of WaaPPa increased the outer-membrane integrity of these complemented mutants, as evidenced by 35-fold and 75-fold increases in the MIC for novobiocin and SDS respectively. The S. typhimurium waaP mutant transformed with both waaP and wapP had over 250-fold and 1000-fold increases, respectively, in these MICs. The inner core phosphates of P. aeruginosa appear to be playing a key role in the intrinsic drug resistance of this bacterium.

Notes: The Pseudomonas aeruginosa A-band lipopolysaccharide (LPS) molecule has an O-polysaccharide region composed of trisaccharide repeat units of α1 → 2, α1 → 3, α1 → 3 linked D-rhamnose (Rha). The A-band polysaccharide is assembled by the α-D-rhamnosyltransferases, WbpX, WbpY and WbpZ. WbpZ probably transfers the first Rha residue onto the A-band accepting molecule, while WbpY and WbpX subsequently transfer two α1 → 3 linked Rha residues and one α1 → 2 linked Rha respectively. The last two transferases are predicted to be processive, alternating in their activities to complete the A-band polymer. The genes coding for these transferases were identified at the 3′ end of the A-band biosynthetic cluster. Two additional genes, psecoA and uvrD, border the 3′ end of the cluster and are predicted to encode a co-enzyme A transferase and a DNA helicase II enzyme respectively. Chromosomal wbpX, wbpY and wbpZ mutants were generated, and Western immunoblot analysis demonstrates that these mutants are unable to synthesize A-band LPS, while B-band synthesis is unaffected. WbpL, a transferase encoded within the B-band biosynthetic cluster, was previously proposed to initiate B-band biosynthesis through the addition of Fuc2NAc (2-acetamido-2,6-dideoxy-D-galactose) to undecaprenol phosphate (Und-P). In this study, chromosomal wbpL mutants were generated that did not express A band or B band, indicating that WbpL initiates the synthesis of both LPS molecules. Cross-complementation experiments using WbpL and its homologue, Escherichia coli WecA, demonstrates that WbpL is bifunctional, initiating B-band synthesis with a Fuc2NAc residue and A-band synthesis with either a GlcNAc (N-acetylglucosamine) or GalNAc (N-acetylgalactosamine) residue. These data indicate that A-band polysaccharide assembly requires four glycosyltransferases, one of which is necessary for initiating both A-band and B-band LPS synthesis.

Notes: Di-N-acetylated uronic acid residues are unique sugar moieties observed in the lipopolysaccharides (LPS) of respiratory pathogens including several serotypes of Pseudomonas aeruginosa and several species of Bordetella. WbpD of P. aeruginosa PAO1 (serotype O5) is a putative 3-N-acetyltransferase that has been implicated in the biosynthesis of UDP-2,3-diacetamido-2,3-dideoxy-d-mannuronic acid [UDP-d-Man(2NAc3NAc)A], a precursor for the d-Man(2NAc3NAc)A residues in the B-band O antigen of this bacterium. A chromosomal knockout mutant of wbpD is incapable of producing either long-chain B-band O antigen (≥ 2 repeating units) or semi-rough LPS (lipid A-core + one repeat). Adding wbpD in trans restored LPS production to the wild-type level; this indicates that wbpD is important for biosynthesis of individual B-band O-antigen repeating units. WbpD contains left-handed beta-helical (LβH) structure as observed by Conserved Domain analysis and in silico secondary and tertiary structure predictions. This feature suggested that WbpD belongs to the hexapeptide acyltransferase (HexAT) superfamily of enzymes. WbpD was overexpressed as an N-terminally histidine-tagged fusion protein (His6–WbpD) and purified to 〉 95% purity. The protein was subjected to Far-UV circular dichroism spectroscopy, and the data revealed that WbpD contains left-handed helical structure, which substantiated in silico predictions made earlier. Results from SDS-PAGE, matrix-assisted laser desorption/ionization-time of flight (MALDI-TOF) mass spectrometry (MS), and gel filtration analyses indicated that His6-WbpD has trimeric organization, consistent with the quaternary structure of HexATs. The binding of acetyl-CoA by WbpD was demonstrated by MALDI-TOF MS, suggesting that WbpD is an acetyltransferase that utilizes a direct-transfer reaction mechanism. Incubation of WbpD with acetyl-CoA significantly enhanced the stability of the protein and prevented precipitation over a course of 14 days. As a substrate for studying the enzymatic activity of WbpD is unavailable at present, a structure-based model for the LβH domain of WbpD was generated. Comparisons between this model and the LβH domains of known HexATs suggested that Lys136 plays a role in acetyl-CoA binding. A K136A site-directed mutant construct could only partially complement the wbpD knockout, and this mutation also reduced the stabilizing effects of acetyl-CoA, while a K136R mutation showed no discernible effect on complementation of the wbpD mutant or the stabilizing effects of acetyl-CoA on the purified mutant protein. A modified pathway was proposed for the biosynthesis of UDP-d-Man(2NAc3NAc)A, in which WbpD is involved in the catalysis of the fourth step by acting as a UDP-2-acetamido-3-amino-2,3-dideoxy-d-glucuronic acid 3-N-acetyltransferase.