Cell-surface alpha-glucan in Campylobacter jejuni 81-176

Campylobacter jejuni infection is a main source of severe gastroenteritis-related illnesses in humans and there is also evidence that it may be linked to neurological disorders. C. jejuni 81-176 is a virulent strain that has become the global model in the study of mechanisms and pathogenesis of C. jejuni infection. For this reason, we were engaged in studying the fine structures of cell-surface carbohydrate antigens of C. jejuni 81-176, namely, the capsule polysaccharide (CPS) and lipooligosaccharide (LOS). Serologically, C. jejuni 81-176 has been classified as belonging to serogroups HS23 and HS36, and indeed previous studies have shown that the LOS and CPS structures possess components similar to those expressed by serostrains HS23 and HS36. Here, we describe that in addition to the LOS and CPS, this strain also produced an independent cell-surface (1-->4)-alpha-glucan capsule.     

Genetic analysis of lipooligosaccharide core biosynthesis in Campylobacter jejuni 81-176

We report isolation and characterization of Campylobacter jejuni 81-176 lgtF and galT lipooligosaccharide (LOS) core mutants. It has been suggested that the lgtF gene of C. jejuni encodes a two-domain glucosyltransferase that is responsible for the transfer of a β-1,4-glucose residue on heptosyltransferase I (Hep I) and for the transfer of a β-1,2-glucose residue on Hep II. A site-specific mutation in the lgtF gene of C. jejuni 81-176 resulted in expression of a truncated LOS, and complementation of the mutant in trans restored the core mobility to that of the wild type. Mass spectrometry and nuclear magnetic resonance of the truncated LOS confirmed the loss of two glucose residues, a β-1,4-glucose on Hep I and a β-1,2-glucose on Hep II. Mutation of another gene, galT, encoding a glycosyltransferase, which maps outside the region defined as the LOS biosynthetic locus in C. jejuni 81-176, resulted in loss of the β-(1,4)-galactose residue and all distal residues in the core. Both mutants invaded intestinal epithelial cells in vitro at levels comparable to the wild-type levels, in marked contrast to a deeper inner core waaC mutant. These studies have important implications for the role of LOS in the pathogenesis of Campylobacter-mediated infection.     

A phase-variable capsule is involved in virulence of Campylobacter jejuni 81-176

Campylobacter jejuni strain 81-176 (HS36, 23) synthesizes two distinct glycan structures, as visualized by immunoblotting of proteinase K-digested whole-cell preparations. A site-specific insertional mutant in the kpsM gene results in loss of expression of a high-molecular-weight (HMW) glycan (apparent Mr 26 kDa to > 85 kDa) and increased resolution of a second ladder-like glycan (apparent Mr 26-50 kDa). The kpsM mutant of 81-176 is no longer typeable in either HS23 or HS36 antisera, indicating that the HMW glycan structure is the serodeterminant of HS23 and HS36. Both the kpsM-dependent HMW glycan and the kpsM-independent ladder-like structure appear to be capsular in nature, as both are attached to phospholipid rather than lipid A. Additionally, the 81-176 kpsM gene can complement a deletion in Escherichia coli kpsM, allowing the expression of an alpha2,8 polysialic acid capsule in E. coli. Loss of the HMW glycan in 81-176 kpsM also increases the surface hydrophobicity and serum sensitivity of the bacterium. The kpsM mutant is also significantly reduced in invasion of INT407 cells and reduced in virulence in a ferret diarrhoeal disease model. The expression of the kpsM-dependent capsule undergoes phase variation at a high frequency.     

Functional characterization of the flagellar glycosylation locus in Campylobacter jejuni 81-176 using a focused metabolomics approach

Bacterial genome sequencing has provided a wealth of genetic data. However, the definitive functional characterization of hypothetical open reading frames and novel biosynthetic genes remains challenging. This is particularly true for genes involved in protein glycosylation because the isolation of their glycan moieties is often problematic. We have developed a focused metabolomics approach to define the function of flagellin glycosylation genes in Campylobacter jejuni 81-176. A capillary electrophoresis-electrospray mass spectrometry and precursor ion scanning method was used to examine cell lysates of C. jejuni 81-176 for sugar nucleotides. Novel nucleotide-activated intermediates of the pseudaminic acid (Pse5NAc7NAc) pathway and its acetamidino derivative (PseAm) were found to accumulate within select isogenic mutants, and use of a hydrophilic interaction liquid chromatography-mass spectrometry method permitted large scale purifications of the intermediates. NMR with cryo probe (cold probe) technology was utilized to complete the structural characterization of microgram quantities of CMP-5-acetamido-7-acetamidino-3,5,7,9-tetradeoxy-L-glycero-alpha-L-manno-nonulosonic acid (CMP-Pse5NAc7Am), which is the first report of Pse modified at C7 with an acetamidino group in Campylobacter, and UDP-2,4-diacetamido-2,4,6-trideoxy-alpha-D-glucopyranose, which is a bacillosamine derivative found in the N-linked proteinglycan. Using this focused metabolomics approach, pseB, pseC, pseF, pseI, and for the first time pseA, pseG, and pseH were found to be directly involved in either the biosynthesis of CMP-Pse5NAc7NAc or CMP-Pse5NAc7Am. In contrast, it was shown that pseD, pseE, Cj1314c, Cj1315c, Cjb1301, Cj1334, Cj1341c, and Cj1342c have no role in the CMP-Pse5NAc7NAc or CMP-Pse5NAc7Am pathways. These results demonstrate the usefulness of this approach for targeting compounds within the bacterial metabolome to assign function to genes, identify metabolic intermediates, and elucidate novel biosynthetic pathways.     

N-linked protein glycosylation is required for full competence in Campylobacter jejuni 81-176

The recent sequencing of the virulence plasmid of Campylobacter jejuni 81-176 revealed the presence of genes homologous to type IV secretion systems (TFSS) that have subsequently been found in Helicobacter pylori and Wolinella succinogenes. Mutational analyses of some of these genes have implicated their involvement in intestinal epithelial cell invasion and natural competence. In this report, we demonstrate that one of these type IV secretion homologs, Cjp3/VirB10, is a glycoprotein. Treatment with various glycosidases and binding to soybean agglutinin indicated that the structure of the glycan present on VirB10 contains a terminal GalNAc, consistent with previous reports of N-linked glycans in C. jejuni. Site-directed mutagenesis of five putative N-linked glycosylation sites indicated that VirB10 is glycosylated at two sites, N32 and N97. Mutants in the N-linked general protein glycosylation (pgl) system of C. jejuni are significantly reduced in natural transformation, which is likely due, in part, to lack of glycosylation of VirB10. The natural transformation defect in a virB10 mutant can be complemented in trans by using a plasmid expressing wild-type VirB10 or an N32A substitution but not by using a mutant expressing VirB10 with an N97A substitution. Taken together, these results suggest that glycosylation of VirB10 specifically at N97 is required for the function of the TFSS and for full competence in C. jejuni 81-176.     

Dynamic proteome changes in Campylobacter jejuni 81-176 after high pressure shock and subsequent recovery

Campylobacter jejuni is one of the most intriguing human foodborne bacterial pathogen. Its survival throughout the food processing chain and its pathogenesis mechanisms in humans remain enigmatic. Living in the animal guts and particularly in avian intestine as a commensal bacterium, this microorganism is frequently isolated from meat products. Ultra high pressure (HP) is a promising alternative to thermal technology for microbial safety of foodstuffs with less organoleptic and nutritional alterations. Its application could be extended to meat products potentially contaminated by C. jejuni. To evaluate the response of Campylobacter to this technological stress and subsequent recovery at a molecular level, a dynamic 2-DE-based proteomic approach has been implemented. After cultivation, C. jejuni cells were conditioned in a high-pressure chamber and transferred to fresh medium for recovery. The protein abundance dynamics at the proteome scale were analyzed by 2-DE during the cellular process of cell injury and recovery. Monitoring protein abundance through time unraveled the basic metabolisms involved in this cellular process. The significance of the proteome evolution modulated by HP and subsequent recovery is discussed in the context of a specific cellular response to stress and recovery of C. jejuni with 69 spots showing significant changes through time.     

Mutation of waaC, encoding heptosyltransferase I in Campylobacter jejuni 81-176, affects the structure of both lipooligosaccharide and capsular carbohydrate

Campylobacter jejuni 81-176 lipooligosaccharide (LOS) is composed of two covalently linked domains: lipid A, a hydrophobic anchor, and a nonrepeating core oligosaccharide, consisting of an inner and outer core region. We report the isolation and characterization of the deepest rough C. jejuni 81-176 mutant by insertional mutagenesis into the waaC gene, encoding heptosyltransferase I that catalyzes the transfer of the first L-glycero-D-manno-heptose residue to 3-deoxy-D-manno-octulosonic residue (Kdo)-lipid A. Tricine gel electrophoresis, followed by silver staining, showed that site-specific mutation in the waaC gene resulted in the expression of a severely truncated LOS compared to wild-type strain 81-176. Gas-liquid chromatography-mass spectrometry and nuclear magnetic resonance spectroscopy showed that the waaC LOS species lacked all sugars distal to Kdo-lipid A. Parallel structural studies of the capsular polysaccharides of the wild-type strain 81-176 and waaC mutant revealed loss of the 3-O-methyl group in the waaC mutant. Complementation of the C. jejuni mutant by insertion of the wild-type C. jejuni waaC gene into a chromosomal locus resulted in LOS and capsular structures identical to those expressed in the parent strain. We also report here the presence of O-methyl phosphoramidate in wild-type strain 81-176 capsular polysaccharide.     

Functional Characterization of Excision Repair and RecA-Dependent Recombinational DNA Repair in Campylobacter jejuni

The presence and functionality of DNA repair mechanisms in Campylobacter jejuni are largely unknown. In silico analysis of the complete translated genome of C. jejuni NCTC 11168 suggests the presence of genes involved in methyl-directed mismatch repair (MMR), nucleotide excision repair, base excision repair (BER), and recombinational repair. To assess the functionality of these putative repair mechanisms in C. jejuni, mutS, uvrB, ung, and recA knockout mutants were constructed and analyzed for their ability to repair spontaneous point mutations, UV irradiation-induced DNA damage, and nicked DNA. Inactivation of the different putative DNA repair genes did not alter the spontaneous mutation frequency. Disruption of the UvrB and RecA orthologues, but not the putative MutS or Ung proteins, resulted in a significant reduction in viability after exposure to UV irradiation. Assays performed with uracil-containing plasmid DNA showed that the putative uracil-DNA glycosylase (Ung) protein, important for initiation of the BER pathway, is also functional in C. jejuni. Inactivation of recA also resulted in a loss of natural transformation. Overall, the data indicate that C. jejuni has multiple functional DNA repair systems that may protect against DNA damage and limit the generation of genetic diversity. On the other hand, the apparent absence of a functional MMR pathway may enhance the frequency of on-and-off switching of phase variable genes typical for C. jejuni and may contribute to the genetic heterogeneity of the C. jejuni population.The gram-negative, microaerophilic bacterium Campylobacter jejuni is one of the most frequent causes of human bacterial gastroenteritis worldwide (7). Infections with C. jejuni are also associated with the development of a paralyzing neuropathy, the Guillain-Barré syndrome (64). C. jejuni can be isolated from various sources, including the chicken intestine and surface water (38). At the population level, C. jejuni is genetically highly diverse (11, 60, 62), which may facilitate bacterial environmental adaptation. Genetic diversity in C. jejuni is generated via horizontal gene transfer (9, 10, 51), intragenomic rearrangements (9), and the presence of numerous stretches of nucleotide repeats that are prone to mispairing during DNA replication (26, 41, 42, 46). In addition, the genomic DNA is probably subject to various types of damage caused by a range of endogenous and environmental factors which may cause single- or double-strand breaks, nucleotide modifications, abasic sites, bulky adducts, and mismatches (14). Virtually all bacteria have evolved more or less sophisticated DNA repair mechanisms to limit the detrimental effects of DNA damage and to maintain the structure and genetic integrity of their DNA (16). The importance of DNA repair for the survival and genetic diversity of C. jejuni, however, is still largely unknown.Bacterial DNA repair mechanisms can be divided into three classes, namely, direct repair, excision repair, and recombinational repair (14). Direct repair involves the reversal of the mutagenic event without the need for synthesis of a new phosphodiester bond. During excision repair, DNA abnormalities are removed and repaired using the intact strand as a template. Recombinational repair involves the reversal of DNA abnormalities via homologous recombination. In contrast to direct repair, DNA repair by excision and recombination does require synthesis of new phosphodiester bonds (56). The focus of the current work is on the presence of the latter two repair mechanisms in C. jejuni.Most knowledge of excision and recombinational DNA repair processes comes from studies of Escherichia coli. In E. coli, methyl-directed mismatch repair (MMR) is operating at the level of excision repair. MMR repairs replication errors that arise from misincorporations (mismatches) and strand slippage (frameshift errors). In addition, MMR inhibits recombination between homologous sequences (47). During MMR, MutS recognizes and binds to replication errors and, together with MutL, activates MutH. This protein cleaves the unmethylated daughter strand at hemimethylated GATC sequences. Part of the daughter strand with the mutation is excised by single-strand nucleases, and the gap is repaired (25, 37). A second excision repair mechanism of E. coli is nucleotide excision repair (NER). NER detects and repairs conformational changes present in DNA. Major components of the NER pathway are the UvrABC proteins. The UvrA and UvrB proteins form the damage recognition complex. After binding to the DNA, UvrB forms a stable complex with the damaged DNA (UvrB-DNA) and UvrA dissociates. UvrC binds to the UvrB-DNA complex, and incisions are made, thereby excising the damaged DNA as a 12- or 13-nucleotide-long oligomer. The resulting gap is repaired using the undamaged strand as a template (55). The third excision repair mechanism of E. coli is base excision repair (BER). This system detects and repairs modified bases. Different glycosylases, such as the uracil-DNA glycosylase Ung, are involved in the recognition of specific DNA alterations. These enzymes remove damaged bases from the DNA by cleavage of N-glycosylic bonds, leaving an apurinic or apyrimidinic site (AP site). An AP endonuclease (XthA) is necessary for cleavage of the phosphodiester bond, and the remaining deoxyribose phosphate moiety is removed by a deoxyribose phosphodiesterase (RecJ) after which the gap in the DNA is repaired (49). The recombinational repair mechanism of E. coli is involved in the repair of stalled or collapsed replication forks caused by conformational changes resulting from unrepaired mutations (8). When nicks or other lesions are present in the DNA, E. coli RecA binds to the damaged DNA and catalyzes recombinational repair via double-strand break repair or daughter strand gap repair (35).The subset and specificity of DNA repair mechanisms differ between species (1). The goal of this study was to decipher the presence and functionality of three excision repair mechanisms (MMR, NER, and BER) and RecA-dependent recombinational repair in C. jejuni. Using a set of genetically defined mutants, we present evidence that recombinational repair and the NER system, but not the MMR pathway, are functional in C. jejuni. In addition, proof was obtained that C. jejuni has a functional Ung protein involved in the BER pathway.     

Proteomics Reveals Multiple Phenotypes Associated with N-linked Glycosylation in Campylobacter jejuni

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Highlights

• •Protein N-glycosylation is essential for nitrate reductase (Nap) activity in C. jejuni.
• •Removal of N-glycosylation results in a metabolic switch from Asp to Pro uptake.
• •N-glycosylation is required for optimal chemotaxis towards several substrates.
• •Loss of N-glycosylation reduces survival following temperature and osmotic shock.

     

Cloning and Characterization of Flagellin Genes and Identification of Flagellin Glycosylation from Thermophilic Bacillus Species

Flagellin glycosylation was identified in Bacillus sp. PS3 and Geobacillus stearothermophilus. In vivo complementation showed that these flagellin genes did not restore the motility of a Bacillus subtilis flagellin mutant, whereas the genes encoding non-glycosylated flagellin from Geobacillus kaustophilus and Bacillus sp. Kps3 restored motility. Moreover, four types of flagellins expressed in B. subtilis were not glycosylated. We speculate that glycosylation is required for flagellar filament assembly of these bacilli.     

Characterization of cross-reacting serotypes of Campylobacter jejuni

Some strains of Campylobacter jejuni react with more than one reference antiserum from the serotyping scheme based on heat-stable lipopolysaccharide antigens. To investigate the molecular basis of these cross-reactions, lipopolysaccharides from the reference strains for serotypes 4, 13, 16, 43, and 50 and isolates recovered during two different outbreaks of C. jejuni enteritis were analyzed by passive haemagglutination and sodium dodecyl sulphate-polyacrylamide gel electrophoresis coupled with silver staining or immunoblotting. The results showed that lipopolysaccharides from the reference strains and the isolates reacted with antisera prepared against heterologous strains in various combinations and that both silver-stainable, low Mr and non-silver-stainable, high Mr lipopolysaccharide components provided the antigenic determinants associated with the cross-reactions. There were strain-to-strain differences in the structural and antigenic properties of these macromolecules and shared antigenic determinants were not always provided by a common structure. Analysis of the silver-stained lipopolysaccharide profiles, outer membrane protein patterns, and chromosomal DNA restriction patterns indicated that strains with the same lipopolysaccharide profile could have the same outer membrane protein pattern and the same DNA restriction pattern. These results provided evidence for the presence of clones within this antigenic complex and implicated antigenic variation in some strains as the phenomenon responsible for the multiplicity of cross-reactions.     

Genomic Characterization of Campylobacter jejuni Strain M1

Campylobacter jejuni strain M1 (laboratory designation 99/308) is a rarely documented case of direct transmission of C. jejuni from chicken to a person, resulting in enteritis. We have sequenced the genome of C. jejuni strain M1, and compared this to 12 other C. jejuni sequenced genomes currently publicly available. Compared to these, M1 is closest to strain 81116. Based on the 13 genome sequences, we have identified the C. jejuni pan-genome, as well as the core genome, the auxiliary genes, and genes unique between strains M1 and 81116. The pan-genome contains 2,427 gene families, whilst the core genome comprised 1,295 gene families, or about two-thirds of the gene content of the average of the sequenced C. jejuni genomes. Various comparison and visualization tools were applied to the 13 C. jejuni genome sequences, including a species pan- and core genome plot, a BLAST Matrix and a BLAST Atlas. Trees based on 16S rRNA sequences and on the total gene families in each genome are presented. The findings are discussed in the background of the proven virulence potential of M1.     

Characterization of mono- and mixed-culture Campylobacter jejuni biofilms

Campylobacter jejuni, one of the most common causes of human gastroenteritis, is a thermophilic and microaerophilic bacterium. These characteristics make it a fastidious organism, which limits its ability to survive outside animal hosts. Nevertheless, C. jejuni can be transmitted to both humans and animals via environmental pathways, especially through contaminated water. Biofilms may play a crucial role in the survival of the bacterium under unfavorable environmental conditions. The goal of this study was to investigate survival strategies of C. jejuni in mono- and mixed-culture biofilms. We grew monoculture biofilms of C. jejuni and mixed-culture biofilms of C. jejuni with Pseudomonas aeruginosa. We found that mono- and mixed-culture biofilms had significantly different structures and activities. Monoculture C. jejuni biofilms did not consume a measurable quantity of oxygen. Using a confocal laser scanning microscope (CLSM), we found that cells from monoculture biofilms were alive according to live/dead staining but that these cells were not culturable. In contrast, in mixed-culture biofilms, C. jejuni remained in a culturable physiological state. Monoculture C. jejuni biofilms could persist under lower flow rates (0.75 ml/min) but were unable to persist at higher flow rates (1 to 2.5 ml/min). In sharp contrast, mixed-culture biofilms were more robust and were unaffected by higher flow rates (2.5 ml/min). Our results indicate that biofilms provide an environmental refuge that is conducive to the survival of C. jejuni.     

Characterization of Campylobacter jejuni biofilms under defined growth conditions

Campylobacter jejuni is a major cause of human diarrheal disease in many industrialized countries and is a source of public health and economic burden. C. jejuni, present as normal flora in the intestinal tract of commercial broiler chickens and other livestock, is probably the main source of human infections. The presence of C. jejuni in biofilms found in animal production watering systems may play a role in the colonization of these animals. We have determined that C. jejuni can form biofilms on a variety of abiotic surfaces commonly used in watering systems, such as acrylonitrile butadiene styrene and polyvinyl chloride plastics. Furthermore, C. jejuni biofilm formation was inhibited by growth in nutrient-rich media or high osmolarity, and thermophilic and microaerophilic conditions enhanced biofilm formation. Thus, nutritional and environmental conditions affect the formation of C. jejuni biofilms. Both flagella and quorum sensing appear to be required for maximal biofilm formation, as C. jejuni flaAB and luxS mutants were significantly reduced in their ability to form biofilms compared to the wild-type strain.     

Characterization of Campylobacter jejuni Biofilms under Defined Growth Conditions

Campylobacter jejuni is a major cause of human diarrheal disease in many industrialized countries and is a source of public health and economic burden. C. jejuni, present as normal flora in the intestinal tract of commercial broiler chickens and other livestock, is probably the main source of human infections. The presence of C. jejuni in biofilms found in animal production watering systems may play a role in the colonization of these animals. We have determined that C. jejuni can form biofilms on a variety of abiotic surfaces commonly used in watering systems, such as acrylonitrile butadiene styrene and polyvinyl chloride plastics. Furthermore, C. jejuni biofilm formation was inhibited by growth in nutrient-rich media or high osmolarity, and thermophilic and microaerophilic conditions enhanced biofilm formation. Thus, nutritional and environmental conditions affect the formation of C. jejuni biofilms. Both flagella and quorum sensing appear to be required for maximal biofilm formation, as C. jejuni flaAB and luxS mutants were significantly reduced in their ability to form biofilms compared to the wild-type strain.