Project description:Campylobacter jejuni is susceptible to killing through exposure to blue light (405 nm) due to its poor ability to detoxify reactive oxygen species. This analysis aimed to elucidate the transcriptomic response of Campylobacter jejuni exposed to 405 nm light through illumina sequencing. C. jejuni was grown and exposed to 405nm light. Samples were taken at 15 min (7 J cm-1) and 30 min (14 J cm-1) after exposure. The data generated were compared to the transcriptome pre-exposure to determine the changes associated with blue light exposure

Project description:Campylobacter jejuni is a human pathogen which causes campylobacteriosis, one of the most widespread zoonotic enteric diseases worldwide. Most cases of sporadic C. jejuni infection occur through the handling or consumption of undercooked chicken meat, or cross-contamination of other foods with raw poultry fluid. A common practice to combat Campylobacter infection is to treat chickens with chlorine which kills the microbe. This analysis aimed to elucidate the transcriptomic response of Campylobacter jejuni treated with hypochlorite through Illumina sequencing. C. jejuni was grown and treated with hypochlorite. Samples were taken 5, 20 and 45 min after treatment for RNAseq analysis.The data generated were compared to the transcriptome pre-exposure to determine C. jejuni's response to hypochlorite.

Project description:To characterize the adaptation processes of C. jejuni to sublethal concentrations of bile acids, that are a crucial component of the intestinal antimicrobial defense, including cholic- , chenodeoxycholic-, taurocholic-, glycocholic-, deoxycholic-, lithocholic-, and ursodeoxycholic acid, we used proteome profiling by label-free mass spectrometry (SWATH-MS). The most toxic bile acids, deoxycholic- and chenodeoxycholic acid induced the most significant changes in protein expression. In detail we found a significant down-regulation of in principle all basic biosynthetic pathways and a general decrease of the transcription machinery. Concurrently, an induction of factors involved in detoxification of reactive oxygen species, protein folding, and bile acid exporting efflux pumps was detected. The metabolism was optimized in such a way that the more energy-efficient aerobic respiration pathway was increased, while the energy-inefficient anaerobic branches of the electron transport chain were down-regulated. Uptake of amino acids in order to catabolize them was also increased. These results show that C. jejuni has a well-built, differentiated system of adaptation to bile acids stress. The findings of this study will enhance the understanding of the biology on the interaction of C. jejuni with the human intestine, and may provide clues to future medical treatment and prevention of C. jejuni infections.

Project description:Campylobacter jejuni is a human pathogen which causes campylobacteriosis, one of the most widespread zoonotic enteric diseases worldwide. Growth of Campylobacter can be improved through the addition of glutamine to media which serves as the nitrogen source. RNAseq was used to identify the transcriptomic response of Campylobacter jejuni when the nitrogen source was switched from serine (poor growth) to glutamine (good growth) in chemostat cultures.

Project description:Campylobacter jejuni is a human pathogen which causes Campylobacteriosis, one of the most widespread zoonotic enteric diseases worldwide. ModE is a transcriptional regulator that controls molybdenum uptake in many bacteria. modE (cj1507c) was deleted from C. jejuni NCTC11168 and grown alongside the parental wild type to mid-log phase in defined medium containing replete Mo, W and Se. Samples were taken for RNAseq analysis and used to compare gene expression.

Project description:Campylobacter jejuni is the leading cause of foodborne human gastroenteritis in the developed world. Infections are largely acquired from poultry produced for human consumption and poor food handling is thus a major risk factor. In this study, C. jejuni were exposed to growth in a number of enviornmental conditions representative of the human gastrointestinal tract, including 0.1% deoxycholate (DOC), under iron limitation (induced by 1 mM deferroxamine, in the presence of chicken 'juice' or 'exudate (the thaw water of frozen commerical chicken products) and in the presence of mammalian mucin.

Project description:In eukaryotes glycosylation plays a role in proteome stability, protein quality control and modulating protein function, however, similar studies in bacteria are lacking. Here, we investigate the role of general protein glycosylation systems in bacteria using the enteropathogen Campylobacter jejuni as a well-defined example. By using a quantitative proteomics strategy, we were able to monitor changes in the C. jejuni proteome when glycosylation is disrupted. We demonstrate that in C. jejuni, N-glycosylation is essential to maintain proteome stability and protein quality control. These findings guided us to investigate the role of N-glycosylation in modulating bacterial cellular activities. In glycosylation deficient C. jejuni, the multidrug efflux pump and electron transport pathways were significantly impaired. In vivo, we demonstrate that fully glycosylation deficient C. jejuni were unable to colonise its natural avian host. These results provide the first evidence of a link between proteome stability and complex functions via a bacterial general glycosylation system.

Project description:Campylobacter jejuni is a major cause of food-borne gastroenteritis. Proteomics by label-based two-dimensional liquid chromatography coupled to tandem mass spectrometry (LC-MS/MS) identified proteins associated with growth in 0.1% sodium deoxycholate (DOC, a component of gut bile salts), and system-wide validation was performed by data-independent acquisition (DIA-SWATH-MS). Proteins involved in nutrient transport were altered by DOC and aligned with intracellular changes to their respective carbon sources. DOC increased intracellular levels of sulfur-containing amino acids (cysteine and methionine) and the dipeptide cystine (Cys-Cys). A DOC induced transport protein was Cj0025c, which has sequence similarity to bacterial Cys-Cys transporters. Deletion of cj0025c (Δcj0025c) resulted in proteome changes consistent with sulfur starvation.

Project description:The bacterial proteins of the Dsb family catalyze the formation of disulfide bridges between cysteine residues that stabilize protein structures and ensure their proper functioning. Here we report the detailed analysis of the Dsb pathway of Campylobacter jejuni. The oxidizing Dsb system of this pathogen is unique because it consists of two monomeric DsbAs (DsbA1 and DsbA2) and one dimeric bifunctional protein (C8J_1298). Previously, we showed that DsbA1 and C8J_1298 are redundant. Here we unraveled the interaction between the two monomeric DsbAs by in vitro and in vivo experiments and by solving their structures and found that both monomeric DsbAs are dispensable proteins. Their structures confirmed that they are homologs of EcDsbL. The slight differences seen in the surface charge of the proteins do not affect the interaction with their redox partner. Comparative proteomics showed that several respiratory proteins, as well as periplasmic transport proteins, are targets of the Dsb system. Some of these, both donors and electron acceptors, are essential elements of C. jejuni respiratory process under oxygen-limiting conditions in the host intestine. The data presented provides detailed information on function of the C. jejuni Dsb system, identifying it as a potential target for novel antibacterial molecules.

Project description:Expression arrays comparing Campylobacter jejuni NCTC11168 during growth in the cecum of germ-free C57 BL/6 IL-10 knockout mice to C. jejuni NCTC11168 during growth in Bolton broth. Four biological replicates comparing C. jejuni NCTC11168 growth in vivo to in vitro. Two biological replicates were dye swaps.