Andrew Cox

A Heptosyltransferase Mutant of Pasteurella multocida Produces a Truncated Lipopolysaccharide Structure and Is Attenuated in Virulence

Publisher: American Society for Microbiology

Date: 06-2004

DOI: 10.1128/IAI.72.6.3436-3443.2004

Abstract: Pasteurella multocida is the causative agent of fowl cholera in birds. In a previous study using signature-tagged mutagenesis, we identified a mutant, AL251, which was attenuated for virulence in mice and in the natural chicken host. Sequence analysis indicated that AL251 had an insertional inactivation of the gene waaQ PM , encoding a putative heptosyl transferase, required for the addition of heptose to lipopolysaccharide (LPS) (M. Harper, J. D. Boyce, I. W. Wilkie, and B. Adler, Infect. Immun. 71:5440-5446, 2003). In the present study, using mass spectrometry and nuclear magnetic resonance, we have confirmed the identity of the enzyme encoded by waaQ PM as a heptosyl transferase III and demonstrated that the predominant LPS glycoforms isolated from this mutant are severely truncated. Complementation experiments demonstrated that providing a functional waaQ PM gene in trans can restore both the LPS to its full length and growth in mice to wild-type levels. Furthermore, we have shown that mutant AL251 is unable to cause fowl cholera in chickens and that the attenuation observed is not due to increased serum sensitivity.

Colistin Resistance in Acinetobacter baumannii Is Mediated by Complete Loss of Lipopolysaccharide Production

Publisher: American Society for Microbiology

Date: 12-2010

DOI: 10.1128/AAC.00834-10

Abstract: Infections caused by multidrug-resistant (MDR) Gram-negative bacteria represent a major global health problem. Polymyxin antibiotics such as colistin have resurfaced as effective last-resort antimicrobials for use against MDR Gram-negative pathogens, including Acinetobacter baumannii . Here we show that A. baumannii can rapidly develop resistance to polymyxin antibiotics by complete loss of the initial binding target, the lipid A component of lipopolysaccharide (LPS), which has long been considered to be essential for the viability of Gram-negative bacteria. We characterized 13 independent colistin-resistant derivatives of A. baumannii type strain ATCC 19606 and showed that all contained mutations within one of the first three genes of the lipid A biosynthesis pathway: lpxA , lpxC , and lpxD . All of these mutations resulted in the complete loss of LPS production. Furthermore, we showed that loss of LPS occurs in a colistin-resistant clinical isolate of A. baumannii . This is the first report of a spontaneously occurring, lipopolysaccharide-deficient, Gram-negative bacterium.

Natural Selection in the Chicken Host Identifies 3-Deoxy- d - manno - Octulosonic Acid Kinase Residues Essential for Phosphorylation o

Publisher: American Society for Microbiology

Date: 09-2010

DOI: 10.1128/IAI.00457-10

Abstract: Pasteurella multocida is the causative agent of a number of diseases in animals, including fowl cholera. P. multocida strains simultaneously express two lipopolysaccharide (LPS) glycoforms (glycoforms A and B) that differ only in their inner core structure. Glycoform A contains a single 3-deoxy- d - manno -octulosonic acid (Kdo) residue that is phosphorylated by the Kdo kinase, KdkA, whereas glycoform B contains two unphosphorylated Kdo residues. We have previously shown that P. multocida mutants lacking the heptosyltransferase, HptA, produce full-length glycoform B LPS and a large amount of truncated glycoform A LPS, as they cannot add heptose to the glycoform A inner core. These hptA mutants were attenuated in chickens because the truncated LPS made them vulnerable to host defense mechanisms, including antimicrobial peptides. However, here we show that birds inoculated with high doses of the hptA mutant developed fowl cholera and the P. multocida isolates recovered from diseased birds no longer expressed truncated LPS. Sequencing analysis revealed that the in vivo -derived isolates had mutations in kdkA , thereby suppressing the production of glycoform A LPS. Interestingly, a number of the spontaneous KdkA mutant strains produced KdkA with a single amino acid substitution (A112V, R123P, H168Y, or D193N). LPS structural analysis showed that complementation of a P. multocida kdkA mutant with wild-type kdkA restored expression of glycoform A to wild-type levels, whereas complementation with any of the mutated kdkA genes did not. We conclude that in P. multocida KdkA, the amino acids A112, R123, H168, and D193 are critical for Kdo kinase function and therefore for glycoform A LPS assembly.

Decoration of Pasteurella multocida Lipopolysaccharide with Phosphocholine Is Important for Virulence

Publisher: American Society for Microbiology

Date: 15-10-2007

DOI: 10.1128/JB.00948-07

Abstract: Phosphocholine (PCho) is an important substituent of surface structures expressed by a number of bacterial pathogens. Its role in virulence has been investigated in several species, in which it has been shown to play a role in bacterial adhesion to mucosal surfaces, in resistance to antimicrobial peptides, or in sensitivity to complement-mediated killing. The lipopolysaccharide (LPS) structure of Pasteurella multocida strain Pm70, whose genome sequence is known, has recently been determined and does not contain PCho. However, LPS structures from the closely related, virulent P. multocida strains VP161 and X-73 were shown to contain PCho on their terminal galactose sugar residues. To determine if PCho was involved in the virulence of P. multocida , we used subtractive hybridization of the VP161 genome against the Pm70 genome to identify a four-gene locus (designated pcgDABC ) which we show is required for the addition of the PCho residues to LPS. The proteins predicted to be encoded by pcgABC showed identity to proteins involved in choline uptake, phosphorylation, and nucleotide sugar activation of PCho. We constructed a P. multocida VP161 pcgC mutant and demonstrated that this strain produces LPS that lacks PCho on the terminal galactose residues. This pcgC mutant displayed reduced in vivo growth in a chicken infection model and was more sensitive to the chicken antimicrobial peptide fowlicidin-1 than the wild-type P. multocida strain.

The capsular polysaccharides of Pasteurella multocida serotypes B and E: Structural, genetic and serological comparisons

Publisher: Oxford University Press (OUP)

Date: 28-07-2020

DOI: 10.1093/GLYCOB/CWAA069

Abstract: We describe the structural characterization of the capsular polysaccharides (CPSs) of Pasteurella multocida serotypes B and E. CPS was isolated following organic solvent precipitation of the supernatant from flask grown cells. Structural analysis utilizing nuclear magnetic resonance spectroscopy enabled the determination of the CPS structures and revealed significant structural similarities between the two serotypes, but also provided an explanation for the serological distinction. This observation was extended by the development of polyclonal sera to the glycoconjugate of serotype B CPS that corroborated the structural likenesses and differences. Finally, identification of these structures enabled a more comprehensive interrogation of the genetic loci and prediction of roles for some of the encoded proteins in repeat unit biosynthesis.

Neisserial Lipooligosaccharide Is a Target for Complement Component C4b

Publisher: Elsevier BV

Date: 12-2003

DOI: 10.1074/JBC.M308364200

Pasteurella multocida lipopolysaccharide: The long and the short of it

Publisher: Elsevier BV

Date: 11-2011

DOI: 10.1016/J.VETMIC.2011.05.022

Abstract: Pasteurella multocida is a capsulated, gram-negative cocco-bacillus that can cause serious disease in a wide range of mammals and birds. P. multocida strains are classified into 16 serovars based on lipopolysaccharide (LPS) antigens. LPS is an essential virulence factor of P. multocida mutants expressing severely truncated LPS are completely attenuated in chickens. LPS is also a major immunogen of P. multocida and protection against infections caused by P. multocida is generally considered to be serovar specific. In this review we summarize current knowledge of the structure and genetics of LPS assembly of P. multocida strains belonging to five different serovars. These include strains belonging to serovars 1 and 3, the most common serovars found in the poultry industry, and strains belonging serovars 2 and 5, the serovars associated with bovine haemorrhagic septicaemia outbreaks. A number of the serovars are genetically related serovars 1 and 14 share the same LPS outer core biosynthesis locus, but due to a mutation within the phosphocholine biosynthesis gene, pcgA, the serovar 14 strain produces a truncated LPS structure. Similarly serovars 2 and 5 share an identical LPS outer core locus and express near-identical LPS structures. However, due to a single point mutation in the phosphoethanolamine (PEtn) transferase gene, lpt_3, the serovar 2 strain does not elaborate a PEtn residue on heptose II. Knowledge of the genetic basis for the LPS structures expressed by P. multocida will facilitate the development of rapid molecular methods for typing and diagnosis and will be essential for a rational approach to vaccine formulation.

Characterization of Two Novel Lipopolysaccharide Phosphoethanolamine Transferases in Pasteurella multocida and Their Role in Resistance to Cathelicidin-2

Publisher: American Society for Microbiology

Date: 11-2017

DOI: 10.1128/IAI.00557-17

Abstract: The lipopolysaccharide (LPS) produced by the Gram-negative bacterial pathogen Pasteurella multocida has phosphoethanolamine (PEtn) residues attached to lipid A, 3-deoxy- d -manno-octulosonic acid (Kdo), heptose, and galactose. In this report, we show that PEtn is transferred to lipid A by the P. multocida EptA homologue, PetL, and is transferred to galactose by a novel PEtn transferase that is unique to P. multocida called PetG. Transcriptomic analyses indicated that petL expression was positively regulated by the global regulator Fis and negatively regulated by an Hfq-dependent small RNA. Importantly, we have identified a novel PEtn transferase called PetK that is responsible for PEtn addition to the single Kdo molecule (Kdo 1 ), directly linked to lipid A in the P. multocida glycoform A LPS. In vitro assays showed that the presence of a functional petL and petK , and therefore the presence of PEtn on lipid A and Kdo 1 , was essential for resistance to the cationic, antimicrobial peptide cathelicidin-2. The importance of PEtn on Kdo 1 and the identification of the transferase responsible for this addition have not previously been shown. Phylogenetic analysis revealed that PetK is the first representative of a new family of predicted PEtn transferases. The PetK family consists of uncharacterized proteins from a range of Gram-negative bacteria that produce LPS glycoforms with only one Kdo molecule, including pathogenic species within the genera Vibrio , Bordetella , and Haemophilus . We predict that many of these bacteria will require the addition of PEtn to Kdo for maximum protection against host antimicrobial peptides.

Pasteurella multocida Expresses Two Lipopolysaccharide Glycoforms Simultaneously, but Only a Single Form Is Required for Virulence: Identification of Two Acceptor-Specific Heptosyl

Publisher: American Society for Microbiology

Date: 08-2007

DOI: 10.1128/IAI.00212-07

Abstract: Lipopolysaccharide (LPS) is a critical virulence determinant in Pasteurella multocida and a major antigen responsible for host protective immunity. In other mucosal pathogens, variation in LPS or lipooligosaccharide structure typically occurs in the outer core oligosaccharide regions due to phase variation. P. multocida elaborates a conserved oligosaccharide extension attached to two different, simultaneously expressed inner core structures, one containing a single phosphorylated 3-deoxy- d -manno-octulosonic acid (Kdo) residue and the other containing two Kdo residues. We demonstrate that two heptosyltransferases, HptA and HptB, add the first heptose molecule to the Kdo 1 residue and that each exclusively recognizes different acceptor molecules. HptA is specific for the glycoform containing a single, phosphorylated Kdo residue (glycoform A), while HptB is specific for the glycoform containing two Kdo residues (glycoform B). In addition, KdkA was identified as a Kdo kinase, required for phosphorylation of the first Kdo molecule. Importantly, virulence data obtained from infected chickens showed that while wild-type P. multocida expresses both LPS glycoforms in vivo, bacterial mutants that produced only glycoform B were fully virulent, demonstrating for the first time that expression of a single LPS form is sufficient for P. multocida survival in vivo. We conclude that the ability of P. multocida to elaborate alternative inner core LPS structures is due to the simultaneous expression of two different heptosyltransferases that add the first heptose residue to the nascent LPS molecule and to the expression of both a bifunctional Kdo transferase and a Kdo kinase, which results in the initial assembly of two inner core structures.

National Research Council Canada

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National Research Council Canada

Location: Canada

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Discovery Projects - Grant ID: DP210103610

Start Date: 06-2021

End Date: 05-2024

Amount: $737,180.00

Funder: Australian Research Council