Susan M. Logan

Structural, genetic and functional characterization of the flagellin glycosylation process in Helicobacter pylori

Mass spectrometry analyses of the complex polar flagella from Helicobacter pylori demonstrated that both FlaA and FlaB proteins are post‐translationally modified with pseudaminic acid (Pse5Ac7Ac, 5,7‐diacetamido‐3,5,7,9‐tetradeoxy‐l‐glycero‐l‐manno ‐n o n‐ulosonic acid). Unlike Campylobacter, flagellar glycosylation in Helicobacter displays little heterogeneity in isoform or glycoform distribution, although all glycosylation sites are located in the central core region of the protein monomer in a manner similar to that found in Campylobacter. Bioinformatic analysis revealed five genes (HP0840, HP0178, HP0326A, HP0326B, HP0114) homologous to other prokaryote genes previously reported to be involved in motility, flagellar glycosylation or polysaccharide biosynthesis. Insertional mutagenesis of four of these homologues in Helicobacter (HP0178, HP0326A, HP0326B, HP0114) resulted in a non‐motile phenotype, no structural flagella filament and only minor amounts of flagellin protein detectable by Western immunoblot. However, mRNA levels for the flagellin structural genes remained unaffected by each mutation. In view of the combined bioinformatic and structural evidence indicating a role for these gene products in glycan biosynthesis, subsequent investigations focused on the functional characterization of the respective gene products. A novel approach was devised to identify biosynthetic sugar nucleotide precursors from intracellular metabolic pools of parent and isogenic mutants using capillary electrophoresis‐electrospray mass spectrometry (CE‐ESMS) and precursor ion scanning. HP0326A, HP0326B and the HP0178 gene products are directly involved in the biosynthesis of the nucleotide‐activated form of Pse, CMP‐Pse. Mass spectral analyses of the cytosolic extract from the HP0326A and HP0326B isogenic mutants revealed the accumulation of a mono‐ and a diacetamido trideoxyhexose UDP sugar nucleotide precursor.

Changes in flagellin glycosylation affect Campylobacter autoagglutination and virulence

Analysis of the complete flagellin glycosylation locus of Campylobacter jejuni strain 81–176 revealed a less complex genomic organization than the corresponding region in the genome strain, C. jejuni NCTC 11168. Twenty‐four of the 45 genes found between Cj1293 and Cj1337 in NCTC 11168 are missing in 81–176. Mutation of six new genes, in addition to three previously reported, resulted in a non‐motile phenotype, consistent with a role in synthesis of pseudaminic acid (PseAc) or transfer of PseAc to flagellin. Mutation of Cj1316c or pseA had been shown to result in loss of the acetamidino form of pseudaminic acid (PseAm). Mutation of a second gene also resulted in loss of PseAm, as well as a minor modification that appears to be PseAm extended with N‐acetyl‐glutamic acid. Previously described mutants in C. jejuni 81–176 and Campylobacter coli VC167 that produced flagella lacking PseAm or PseAc failed to autoagglutinate. This suggests that interactions between modifications on adjacent flagella filaments are required for autoagglutination. Mutants (81–176) defective in autoagglutination showed a modest reduction in adherence and invasion of INT407 cells. However, there was a qualitative difference in binding patterns to INT407 cells using GFP‐labelled 81–176 and mutants lacking PseAm. A mutant lacking PseAm was attenuated in the ferret diarrhoeal disease model.

Campylobacter - a tale of two protein glycosylation systems

Post-translational glycosylation is a universal modification of proteins in eukarya, archaea and bacteria. Two recent publications describe the first confirmed report of a bacterial N-linked glycosylation pathway in the human gastrointestinal pathogen Campylobacter jejuni. In addition, an O-linked glycosylation pathway has been identified and characterized in C. jejuni and the related species Campylobacter coli. Both pathways have similarity to the respective N- and O-linked glycosylation processes in eukaryotes. In bacteria, homologues of the genes in both pathways are found in other organisms, the complex glycans linked to the glycoproteins share common biosynthetic precursors and these modifications could play similar biological roles. Thus, Campylobacter provides a unique model system for the elucidation and exploitation of glycoprotein biosynthesis.

Functional characterization of dehydratase/aminotransferase pairs from Helicobacter and Campylobacter: enzymes distinguishing the pseudaminic acid and bacillosamine biosynthetic pathways.

Helicobacter pylori and Campylobacter jejuni have been shown to modify their flagellins with pseudaminic acid (Pse), via O-linkage, while C. jejuni also possesses a general protein glycosylation pathway (Pgl) responsible for the N-linked modification of at least 30 proteins with a heptasaccharide containing 2,4-diacetamido-2,4,6-trideoxy-α-d-glucopyranose, a derivative of bacillosamine. To further define the Pse and bacillosamine biosynthetic pathways, we have undertaken functional characterization of UDP-α-d-GlcNAc modifying dehydratase/aminotransferase pairs, in particular the H. pylori and C. jejuni flagellar pairs HP0840/HP0366 and Cj1293/Cj1294, as well as the C. jejuni Pgl pair Cj1120c/Cj1121c using His6-tagged purified derivatives. The metabolites produced by these enzymes were identified using NMR spectroscopy at 500 and/or 600 MHz with a cryogenically cooled probe for optimal sensitivity. The metabolites of Cj1293 (PseB) and HP0840 (FlaA1) were found to be labile and could only be characterized by NMR analysis directly in aqueous reaction buffer. The Cj1293 and HP0840 enzymes exhibited C6 dehydratase as well as a newly identified C5 epimerase activity that resulted in the production of both UDP-2-acetamido-2,6-dideoxy-β-l-arabino-4-hexulose and UDP-2-acetamido-2,6-dideoxy-α-d-xylo-4-hexulose. In contrast, the Pgl dehydratase Cj1120c (PglF) was found to possess only C6 dehydratase activity generating UDP-2-acetamido-2,6-dideoxy-α-d-xylo-4-hexulose. Substrate-specificity studies demonstrated that the flagellar aminotransferases HP0366 and Cj1294 utilize only UDP-2-acetamido-2,6-dideoxy-β-l-arabino-4-hexulose as substrate producing UDP-4-amino-4,6-dideoxy-β-l-AltNAc, a precursor in the Pse biosynthetic pathway. In contrast, the Pgl aminotransferase Cj1121c (PglE) utilizes only UDP-2-acetamido-2,6-dideoxy-α-d-xylo-4-hexulose producing UDP-4-amino-4,6-dideoxy-α-d-GlcNAc (UDP-2-acetamido-4-amino-2,4,6-trideoxy-α-d-glucopyranose), a precursor used in the production of the Pgl glycan component 2,4-diacetamido-2,4,6-trideoxy-α-d-glucopyranose.

Pseudaminic acid, the major modification on Campylobacter flagellin, is synthesized via the Cj1293 gene

Flagellins from Campylobacter jejuni 81‐176 and Campylobacter coli VC167 are heavily glycosylated. The major modifications on both flagellins are pseudaminic  acid (Pse5Ac7Ac), a  nine  carbon sugar that is similar to sialic acid, and an acetamidino‐substituted analogue of pseudaminic acid (PseAm). Previous data have indicated that PseAm is synthesized via Pse5Ac7Ac in C. jejuni 81‐176, but that the two sugars are synthesized using independent pathways in C. coli VC167. The Cj1293 gene of C. jejuni encodes a putative UDP‐GlcNAc C6‐dehydratase/C4‐reductase that is similar to a protein required for glycosylation of Caulobacter crescentus flagellin. The Cj1293 gene is expressed either under the control of a σ54 promoter that overlaps the coding region of Cj1292 or as a polycistronic message under the control of a σ70 promoter upstream of Cj1292. A mutant in gene Cj1293 in C. jejuni 81‐176 was non‐motile and non‐flagellated and accumulated unglycosylated flagellin intracellularly. This mutant was complemented in trans with the homologous C. jejuni gene, as well as the Helicobacter pylori homologue, HP0840, which has been shown to encode a protein with UDP‐GlcNAc C6‐dehydratase/C4‐reductase activity. Mutation of Cj1293 in C. coli VC167 resulted in a fully motile strain that synthesized a flagella filament composed of flagellin in which Pse5Ac7Ac was replaced by PseAm. The filament from the C. coli Cj1293 mutant displayed increased solubility in SDS compared with the wild‐type filament. A double mutant in C. coli VC167, defective in both Cj1293 and ptmD, encoding part of the independent PseAm pathway, was also non‐motile and non‐flagellated and accumulated unglycosylated flagellin intracellularly. Collectively, the data indicate that Cj1293 is essential for Pse5Ac7Ac biosynthesis from UDP‐GlcNAc, and that glycosylation is required for flagella biogenesis in campylobacters.

Independent evolution of neurotoxin and flagellar genetic loci in proteolytic Clostridium botulinum

BackgroundProteolytic Clostridium botulinum is the causative agent of botulism, a severe neuroparalytic illness. Given the severity of botulism, surprisingly little is known of the population structure, biology, phylogeny or evolution of C. botulinum. The recent determination of the genome sequence of C. botulinum has allowed comparative genomic indexing using a DNA microarray.ResultsWhole genome microarray analysis revealed that 63% of the coding sequences (CDSs) present in reference strain ATCC 3502 were common to all 61 widely-representative strains of proteolytic C. botulinum and the closely related C. sporogenes tested. This indicates a relatively stable genome. There was, however, evidence for recombination and genetic exchange, in particular within the neurotoxin gene and cluster (including transfer of neurotoxin genes to C. sporogenes), and the flagellar glycosylation island (FGI). These two loci appear to have evolved independently from each other, and from the remainder of the genetic complement. A number of strains were atypical; for example, while 10 out of 14 strains that formed type A1 toxin gave almost identical profiles in whole genome, neurotoxin cluster and FGI analyses, the other four strains showed divergent properties. Furthermore, a new neurotoxin sub-type (A5) has been discovered in strains from heroin-associated wound botulism cases. For the first time, differences in glycosylation profiles of the flagella could be linked to differences in the gene content of the FGI.ConclusionProteolytic C. botulinum has a stable genome backbone containing specific regions of genetic heterogeneity. These include the neurotoxin gene cluster and the FGI, each having evolved independently of each other and the remainder of the genetic complement. Analysis of these genetic components provides a high degree of discrimination of strains of proteolytic C. botulinum, and is suitable for clinical and forensic investigations of botulism outbreaks.

Identification of genes involved in the biosynthesis and attachment of Methanococcus voltae N-linked glycans: insight into N-linked glycosylation pathways in Archaea.

N‐linked glycosylation is recognized as an important post‐translational modification across all three domains of life. However, the understanding of the genetic pathways for the assembly and attachment of N‐linked glycans in eukaryotic and bacterial systems far outweighs the knowledge of comparable processes in Archaea. The recent characterization of a novel trisaccharide [β‐ManpNAcA6Thr‐(1‐4)‐β‐GlcpNAc3NAcA‐(1‐3)‐β‐GlcpNAc]N‐linked to asparagine residues in Methanococcus voltae flagellin and S‐layer proteins affords new opportunities to investigate N‐linked glycosylation pathways in Archaea. In this contribution, the insertional inactivation of several candidate genes within the M. voltae genome and their resulting effects on flagellin and S‐layer glycosylation are reported. Two of the candidate genes were shown to have effects on flagellin and S‐layer protein molecular mass and N‐linked glycan structure. Further examination revealed inactivation of either of these two genes also had effects on flagella assembly. These genes, designated agl (archaeal glycosylation) genes, include a glycosyl transferase (aglA) involved in the attachment of the terminal sugar to the glycan and an STT3 oligosaccharyl transferase homologue (aglB) involved in the transfer of the complete glycan to the flagellin and S‐layer proteins. These findings document the first experimental evidence for genes involved in any glycosylation process within the domain Archaea.

Structural heterogeneity of carbohydrate modifications affects serospecificity of Campylobacter flagellins

Flagellin from Campylobacter coli VC167 is post‐translationally modified at ≥ 16 amino acid residues with pseudaminic acid and three related derivatives. The predominant modification was 5,7‐diacetamido‐3,5,7,9 ‐ tetradeoxy ‐ l ‐ glycero ‐ l ‐ manno ‐ nonulosonic acid (pseudaminic acid, Pse5Ac7Ac), a modification that has been described previously on flagellin from Campylobacter jejuni 81‐176. VC167 lacked two modi‐fications present in 81‐176 and instead had two unique modifications of masses 431 and 432 Da. Flagellins from both C. jejuni 81‐176 and C. coli VC167 were also modified with an acetamidino form of pseudaminic acid (PseAm), but tandem mass spectrometry indicated that the structure of PseAm differed in the two strains. Synthesis of PseAm in C. coli VC167 requires a minimum of six ptm genes. In contrast, PseAm is synthesized in C. jejuni 81‐176 via an alternative pathway using the product of the pseA gene. Mutation of the ptm genes in C. coli VC167 can be detected by changes in apparent Mr of flagellin in SDS‐PAGE gels, changes in isoelectric focusing (IEF) patterns and loss of immunoreactivity with antiserum LAH2. These changes corresponded to loss of both 315 Da and 431 Da modifications from flagellin. Complementation of the VC167 ptm mutants with the 81‐176 pseA gene in trans resulted in flagellins containing both 315 and 431 Da modifications, but these flagellins remained unreactive in LAH2 antibody, suggesting that the unique form of PseAm encoded by the ptm genes contributes to the serospecificity of the flagellar filament.

Motility and Flagellar Glycosylation in Clostridium difficile

In this study, intact flagellin proteins were purified from strains of Clostridium difficile and analyzed using quadrupole time of flight and linear ion trap mass spectrometers. Top-down studies showed the flagellin proteins to have a mass greater than that predicted from the corresponding gene sequence. These top-down studies revealed marker ions characteristic of glycan modifications. Additionally, diversity in the observed masses of glycan modifications was seen between strains. Electron transfer dissociation mass spectrometry was used to demonstrate that the glycan was attached to the flagellin protein backbone in O linkage via a HexNAc residue in all strains examined. Bioinformatic analysis of C. difficile genomes revealed diversity with respect to glycan biosynthesis gene content within the flagellar biosynthesis locus, likely reflected by the observed flagellar glycan diversity. In C. difficile strain 630, insertional inactivation of a glycosyltransferase gene (CD0240) present in all sequenced genomes resulted in an inability to produce flagellar filaments at the cell surface and only minor amounts of unmodified flagellin protein.

Structural and Genetic Characterization of Glycosylation of Type a Flagellin in Pseudomonas aeruginosa

Type a flagellins from two strains of Pseudomonas aeruginosa, strains PAK and JJ692, were found to be glycosylated with unique glycan structures. In both cases, two sites of O-linked glycosylation were identified on each monomer, and these sites were localized to the central, surface-exposed domain of the monomer in the assembled filament. The PAK flagellin was modified with a heterogeneous glycan comprising up to 11 monosaccharide units that were O linked through a rhamnose residue to the protein backbone. The flagellin of JJ692 was less complex and had a single rhamnose substitution at each site. The role of the glycosylation island gene cluster in the production of each of these glycosyl moieties was investigated. These studies revealed that the orfA and orfN genes were required for attachment of the heterologous glycan and the proximal rhamnose residue, respectively.