Molecular basis of lipid-linked oligosaccharide recognition and processing by bacterial oligosaccharyltransferase.

Oligosaccharyltransferase (OST) is a membrane-integral enzyme that catalyzes the transfer of glycans from lipid-linked oligosaccharides (LLOs) onto asparagine side chains, the first step in protein N-glycosylation. Here, we report the X-ray structure of a single-subunit OST, PglB from Campylobacter lari, trapped in an intermediate state bound to an acceptor peptide and a synthetic LLO analog. The structure reveals the role of the external loop EL5, present in all OST enzymes, in substrate recognition. Whereas the N-terminal half of EL5 binds LLO, the C-terminal half interacts with the acceptor peptide. The glycan moiety of LLO must thread under EL5 to access the active site. Reducing EL5 mobility decreases the catalytic rate of OST when full-size heptasaccharide LLO is provided, but not for a monosaccharide-containing LLO analog. Our results define the chemistry of a ternary complex state, assign functional roles to conserved OST motifs, and provide opportunities for glycoengineering by rational design of PglB.

Transformation and characterization of an arsenic gene operon from urease-positive thermophilic Campylobacter (UPTC) in Escherichia coli.

An arsenate susceptibility test was performed with transformed and cultured Escherichia coli DH5α cells, which carried recombinant DNA of full-length arsenic (ars) operon, namely a putative membrane permease, ArsP; a transcriptional repressor, ArsR; an arsenate reductase, ArsC; and an arsenical-resistance membrane transporter, Acr3, from the Japanese urease-positive thermophilic Campylobacter lari (UPTC) CF89-12. The E. coli DH5α transformant showed reduced susceptibility to arsenate (~1536 µg/mL), compared to the control. Thus, these ars four-genes from the UPTC CF89-12 strain cells could confer a reduced susceptibility to arsenate in the transformed and E. coli DH5α cells. E. coli transformants with truncated ars operons, acr3 (acr3) and arsC-acr3 (∆arsC-acr3), of the ars operon, showed an MIC value of 384 µg/mL (~384 µg/mL), similar to the E. coli cells which carried the pGEM-T vector (control). Reverse transcription PCR confirmed in vivo transcription of recombinant full-length ars operon and deletion variants (∆acr3 and ∆arsC-acr3) in the transformed E. coli cells.

Mechanism of bacterial oligosaccharyltransferase: in vitro quantification of sequon binding and catalysis.

N-Linked glycosylation is an essential post-translational protein modification in the eukaryotic cell. The initial transfer of an oligosaccharide from a lipid carrier onto asparagine residues within a consensus sequon is catalyzed by oligosaccharyltransferase (OST). The first X-ray structure of a complete bacterial OST enzyme, Campylobacter lari PglB, was recently determined. To understand the mechanism of PglB, we have quantified sequon binding and glycosylation turnover in vitro using purified enzyme and fluorescently labeled, synthetic peptide substrates. Using fluorescence anisotropy, we determined a dissociation constant of 1.0 µm and a strict requirement for divalent metal ions for consensus (DQNAT) sequon binding. Using in-gel fluorescence detection, we quantified exceedingly low glycosylation rates that remained undetected using in vivo assays. We found that an alanine in the -2 sequon position, converting the bacterial sequon to a eukaryotic one, resulted in strongly lowered sequon binding, with in vitro turnover reduced 50,000-fold. A threonine is preferred over serine in the +2 sequon position, reflected by a 4-fold higher affinity and a 1.2-fold higher glycosylation rate. The interaction of the +2 sequon position with PglB is modulated by isoleucine 572. Our study demonstrates an intricate interplay of peptide and metal binding as the first step of protein N-glycosylation.

Biochemical characterisation of urease from urease-positive thermophilic campylobacter (UPTC).

This study aims to characterise biochemically urease from an atypical Campylobacter lari, namely urease-positive thermophilic Campylobacter (UPTC). Urease was purified from cells of a Japanese UPTC isolate (CF89-12) using phenyl-Sepharose chromatography. Two protein components (estimates molecular masses 24 kDa and 61 kDa) were obtained that appeared to be structural proteins of urease (subunits A and B), and these were fractionated by sodium dodecyl sulphate-polyacrylamide gel electrophoresis (PAGE). The native molecular weight for the final purified UPTC urease was estimated to be approximately 186,000 Da which is close to the calculated molecular weight (182,738 Da) based on all six open reading frames of UPTC CF89-12 urease genes (ureA, B, E, F, G and H), as described previously. Moreover, an active band was observed on phenol red staining after a nondenaturing native PAGE of the crude extract from the UPTC cells. In addition, the purified urease of UPTC CF8912 showed enzyme activity over a broad pH range (pH 6-10), with maximal activity at pH 8.0. The urease was also stable against heat treatment, with almost no loss of enzyme activity seen following 60-min incubation at temperatures of 20-60 degrees C. Urease subunits A and B were identified immunologically by Western blot analysis with rabbit anti-urease alpha (A) and beta (B) raised against Helicobacter pylori.

Expression and analysis of a cytolethal distending toxin (cdt) gene operon in Campylobacter lari.

The present study examines the expression of cytolethal distending toxin (cdt) gene encoding a cytotoxin in Campylobacter lari (n=6 urease-negative [UN] C. lari; n=4 urease-positive thermophilic Campylobacter [UPTC]). When reverse transcription polymerase chain reaction (RT-PCR) was carried out with 10 C. lari isolates using a primer pair to amplify the cdtB gene transcript segment, an approximate 260 bp RT-PCR amplicon was generated with all the isolates. In addition, cdtA, cdtB and cdtC gene operon was identified to be polycistronicly transcribed in the C. lari cells. The cdtB gene translation in the C. lari cells was also confirmed by Western blot analysis. Thus, the cdt gene operon in C. lari organisms, including UN C. lari and UPTC, was expressed at the transcriptional and translational levels in the cells. The present results suggest that all three cdt genes may be functional in the cells.

Phylogenetic analysis of urease-positive thermophilic Campylobacter (UPTC) strains based on the molecular characterization of the flaA gene.

Molecular cloning, nucleotide sequencing, and characterization of the flaA gene from additional isolates of urease-positive thermophilic Campylobacter (UPTC) were performed. These isolates were obtained from the natural environment in Northern Ireland (n = 9 from mussels) and in England (n = 1 from sea water). All isolates carried the shorter flaA gene, [open reading frames (ORFs), 1,461 to 1,503 base pairs], without any internal termination codons, and did not carry any flaA pseudogenes. The UPTC isolates were well discriminated by the neighbor joining (NJ) phylogenetic tree constructed based on the putative flaA genes ORFs nucleotide sequence information. In addition, the NJ tree constructed based on the flaA-short variable region sequence information discriminated the Campylobacter lari isolates with a similar degree of discrimination power.

Structural analysis of the full-length gene encoding a fibronectin-binding-like protein (CadF) and its adjacent genetic loci within Campylobacter lari.

BACKGROUND: The combined sequences encoding a partial and putative rpsI open reading frame (ORF), non-coding (NC) region, a putative ORF for the Campylobacter adhesin to fibronectin-like protein (cadF), a putative Cla_0387 ORF, NC region and a partial and putative Cla_0388 ORF, were identified in 16 Campylobacter lari isolates, using two novel degenerate primer pairs. Probable consensus sequence at the -35 and -10 regions were identified in all C. lari isolates, as a promoter. RESULTS: Thus, cadF (-like) gene is highly conserved among C. lari organisms. Transcription of the cadF (-like) gene in C. lari cells in vivo was also confirmed and the transcription initiation site was determined. A peptidoglycan-associating alpha-helical motif in the C-terminal regions of some bacterial cell-surface proteins was completely conserved amongst the putative cadF (-like) ORFs from the C. lari isolates. CONCLUSION: The putative cadF (-like) ORFs from all C. lari isolates were nine amino acid larger than those from C. jejuni, and showed amino acid residues 137 -140 of FALG (50% identity), instead of the FRLS residues of the maximal fibronectin-binding activity site demonstrated within C. jejuni CadF. A neighbor joining tree constructed based on cadF (-like) gene sequence information formed a major cluster consisting of C. lari isolates, separating from the other three thermophilic campylobacters.

Cloning, sequencing and expression of full-length Campylobacter invasion antigen B gene operon from Campylobacter lari.

A novel PCR primer pair for amplification of full-length cia B gene from thermophilic campylobacters, generated an amplicon of approximately 2.2 kilo base pairs (kbp) with all 18 isolates (n = 7 for urease-negative (UN) C. lari; n = 9 urease-positive thermophilic Campylobacter (UPTC); n = 1 C. jejuni; n = 1 C. coli). The putative open reading frame (ORF) of the cia B from C. lari isolates consisted of 1,833 bp similarly, but differing from those of C. jejuni and C. coli isolates. The putative promoter structures consisting of a semi-conserved T -rich sequence and a consensus sequence at the -10 region were identified upstream of the putative ORF in all the C. lari isolates. A start codon ATG and a probable ribosome binding site were also identified in all the isolates. In addition, two distinctly different and taxon (UN C. lari and UPTC) dependent hypothetically intrinsic rho -independent transcriptional terminators for the cia B were identified to occur within the C. lari. Reverse transcription-PCR analysis identified the transcription of cia B gene in the C. lari cells. The neighbor joining tree suggested that the nucleotide sequence information of the cia B had molecular discrimination efficacy among UN C. lari, UPTC, C. jejuni and C. coli organisms.

The complete genome sequence and analysis of the human pathogen Campylobacter lari.

Campylobacter lari is a member of the epsilon subdivision of the Proteobacteria and is part of the thermotolerant Campylobacter group, a clade that includes the human pathogen C. jejuni. Here we present the complete genome sequence of the human clinical isolate, C. lari RM2100. The genome of strain RM2100 is approximately 1.53 Mb and includes the 46 kb megaplasmid pCL2100. Also present within the strain RM2100 genome is a 36 kb putative prophage, termed CLIE1, which is similar to CJIE4, a putative prophage present within the C. jejuni RM1221 genome. Nearly all (90%) of the gene content in strain RM2100 is similar to genes present in the genomes of other characterized thermotolerant campylobacters. However, several genes involved in amino acid biosynthesis and energy metabolism, identified previously in other Campylobacter genomes, are absent from the C. lari RM2100 genome. Therefore, C. lari RM2100 is predicted to be multiply auxotrophic, unable to synthesize eight different amino acids, acetyl-coA, and pantothenate. Additionally, strain RM2100 does not contain a complete TCA cycle and is missing the CydAB terminal oxidase of the respiratory chain. Defects in the amino acid biosynthetic pathways in this organism could be potentially compensated by the large number of encoded peptidases. Nevertheless, the apparent absence of certain key enzymatic functions in strain RM2100 would be expected to have an impact on C. lari biology. It is also possible that the reduction in the C. lari metabolic machinery is related to its environmental range and host preference.

The omp50 gene is transcriptionally controlled by a temperature-dependent mechanism conserved among thermophilic Campylobacter species.

The thermophilic Campylobacters are enteropathogenic for humans. We recently showed that Omp50 is a Campylobacter species-specific porin produced in Campylobacter jejuni and Campylobacter lari but not in Campylobacter coli. In the present study, we investigated regulation of the omp50 gene and found that its expression in C. jejuni was temperature-dependent, but independent of growth phase or medium viscosity. The use of RT-PCR and omp50::lacZ fusions showed that growth temperature control occurred at the transcriptional level. The promoter and the coding sequence were cloned in an Escherichia coli-Campylobacter shuttle plasmid and transferred to E. coli and to a C. jejuni Omp50-deficient strain. Regulation of omp50 gene expression by growth temperature was observed in the recombinant C. jejuni strain, but not in E. coli. The same regulation was also observed in wild-type C. lari strains and in a C. coli strain supplemented by the plasmid, suggesting that omp50 expression is controlled by a mechanism conserved among Campylobacter species.

Amino acid sequence determination of protein biomarkers of Campylobacter upsaliensis and C. helveticus by "composite" sequence proteomic analysis.

We have identified the protein biomarkers observed in the matrix-assisted laser desorption/ionization time-of-flight mass spectra (MALDI-TOF-MS) of cell lysates of five strains of Campylobacter upsaliensis and one strain of C. helveticus by "bottom-up" proteomic techniques. Only one C. upsaliensis strain had previously been genomically sequenced. The significant findings are as follows: (1) The protein biomarkers identified were: 10 kD chaperonin, protein of unknown function (DUF465), phnA protein, probable periplasmic protein, D-methionine-binding lipoprotein MetQ, cytochrome c family protein, DNA-binding protein HU, thioredoxin, asparigenase family protein, helix-turn-helix domain protein, as well as several ribosomal and conserved hypothetical proteins. (2) Amino acid substitutions in protein biomarkers across species and strains account for variations in biomarker ion mass-to-charge (m/z). (3) The most common post-translational modifications (PTMs) identified were cleavage of N-terminal methionine and N-terminal signal peptides. The rule that predicts N-terminal methionine cleavage, based on the penultimate residue, does not appear to apply to C. upsaliensis proteins when the penultimate residue is threonine. (4) It was discovered that some protein biomarker genes of the genomically sequenced C. upsaliensis strain were found to have nucleotide sequences with GTG or TTG "start" codons that were not the actual start codon (ATG) of the protein based on proteomic analysis. (5) Proteomic identification of the protein biomarkers of the non-genomically sequenced C. upsaliensis and C. helveticus strains involved identification of homologous protein amino acid sequences to that of the sequenced strain. Interestingly, some protein sequence regions that were not completely homologous to the sequenced strain, due to amino acid substitutions, were found to have homologous sequence regions from more phyogenetically distant species/strains, e.g., C. jejuni. Exploiting this partial homology of more distant species/strains, it was possible to construct a "composite" amino acid sequence using multiple non-overlapping sequence regions from both phylogenetically proximate and distant strains. The new composite sequence was confirmed by both MS and MS/MS data. Thus, it was possible in some cases to determine the amino acid sequence of an unknown protein biomarker from a genomically non-sequenced bacterial strain without the necessity of either genetically sequencing the biomarker gene or resorting to de novo MS/MS analysis of the full protein sequence.

Amplified fragment-length polymorphism and protein profiling for identification of Campylobacter lari subgroups.

Amplified fragment-length polymorphism analysis (AFLP) has been shown to be a suitable method for subtyping of bacteria belonging to the genus Campylobacter. Campylobacter lari is a phenotypically and genotypically diverse species that comprises the classical nalidixic acid-resistant thermophilic campylobacters and the biochemical C. lari variants, urease-positive, nalidixic acid-susceptible, and urease producing nalidixic acid-susceptible strains. AFLP profiling and whole-cell protein profile analysis are suitable methods for studying the taxonomic and epidemiological relationships among strains of the C. lari variants. Numerical analysis of AFLP profiles and of partial protein profiles allows the discrimination of distinct C. lari genogroups. No correlation of these genogroups with different sources of the strains has been identified until now.