Project description:Cj0440c encodes a putative transcriptional regulator. To determine the role of Cj0440c in C.jejuni, we knocked out Cj0440c in the wild-type strain (S) to obtain the Cj0440c mutants (SM). Then we compared the transcriptome of the Cj0440c mutant with that of the parent strain using DNA microarray. These comparisons identified 19 genes that showed aM-bM-^IM-%2-fold change in expression in SM. The differentially expressed genes in SM encode proteins involved in flagellar biosynthesis, O-linked glycosylation and hypothetical proteins with unknown fuctions. Cj0440c may regulate flagellar structural element expression or as a compenent of flagellar complex co-expressed with other flagellar genes. Subsequent experiments demonstrated that inactivation of Cj0440c affected corresponding phenotypes of C.jejuni, including broken flagella, weaker motility and reduced colonization ability in chickens. These findings indicate that Cj0440c governs the expression of multiple genes related to flagellar biosynthesis and O-linked glycosylation. This study provides favorable evidence for completing the information of the Campylobacter jejuni genome. An eight chip study using total RNA recoverd from four separate wild-type cultures of Campylobacter jejuni NCTC111168 (S) and four separate cultures of a mutant strain, Campylobacter jejuni NCTC11168 delta- Cj0440c (SM), in which Cj0440c is deleted. Each chip measures the expression level of 1634 genes from Campylobacter jejuni NCTC11168.

Project description:DksA is well-known for its regulatory role in the transcription of ribosomal RNA and genes involved in amino acid synthesis in many bacteria. DksA is also reported to control expression of virulence genes in pathogenic bacteria. Here, we elucidated the roles of the DksA-like protein (CJJ81176_0160, Cj0125c) in the pathogenesis of Campylobacter jejuni. Like in other bacteria, transcription of stable RNA was repressed by DksA under stressful conditions in C. jejuni. Transcriptomic and proteomic analyses of C. jejuni 81-176 and its isogenic dksA mutant showed differential expression of many genes involved in iron-related metabolism, flagellar synthesis and amino acid metabolism. Also the dksA mutant of C. jejuni demonstrated a decreased ability to invade into intestinal cells and to induce release of interleukin-8 from intestinal cells. These results suggest the DksA-like protein plays an important regulatory role in the physiology and virulence of C. jejuni. Keywords: dksA mutation of Campylobacter jejuni

Project description:DksA is well-known for its regulatory role in the transcription of ribosomal RNA and genes involved in amino acid synthesis in many bacteria. DksA is also reported to control expression of virulence genes in pathogenic bacteria. Here, we elucidated the roles of the DksA-like protein (CJJ81176_0160, Cj0125c) in the pathogenesis of Campylobacter jejuni. Like in other bacteria, transcription of stable RNA was repressed by DksA under stressful conditions in C. jejuni. Transcriptomic and proteomic analyses of C. jejuni 81-176 and its isogenic dksA mutant showed differential expression of many genes involved in iron-related metabolism, flagellar synthesis and amino acid metabolism. Also the dksA mutant of C. jejuni demonstrated a decreased ability to invade into intestinal cells and to induce release of interleukin-8 from intestinal cells. These results suggest the DksA-like protein plays an important regulatory role in the physiology and virulence of C. jejuni. Keywords: dksA mutation of Campylobacter jejuni The design utilized a commercially available two color microarray slide for the enture transcriptome of Campylobacter jejuni. Six hybridizations were performed each with independently extracted samples of either C. jejuni wildtype of C. jejuni dksA mutant cDNA samples. A dye swap was utilized to help minimize dye dependent bias. Thus there were six biological replicates of each sample.

Project description:Competitive hybridization of V1 variant of genome sequenced C. jejuni strain 11168 versus V1 variant in which flhA gene has been disrupted. Keywords: repeat sample

Project description:Campylobacter jejuni produces a single flagellum on one or both poles of the cell, the polar flagella not only confer the bacterium darting motility but also involved in its virulence and metabolic processes. FlhF is a lately defined flagella biosynthesis regulator, but how it regulates flagella assembly isn’t clear at present. Previous research had indicated FlhF was associated with gene expression, to understanding its role in flagella system and its correlation with C. jejuni virulence, the global gene expression profiles of C. jejuni NCTC 11168 after inactivation of FlhF was analyzed. Transcriptome analysis revealed that ten genes were significantly differentially expressed with 6 down-regulated and 4 up-regulated, these genes are involved in diverse cellular functions including bacterial chemotaxis, flagellar assembly and two-component system, significance analysis revealed that the pathway of flagellar assembly was remarkable affected. Further studies were focused on the flagella system, FlhF was found play a global role as 63% (41/65) of the flagella genes were down-regulated, it influences flagella gene transcription from the early stage, this effect persists during the synthesis process and has a remarkable impact on the late part. The results above expand our cognition of this regulator, and also helpful for comprehensively and systematically reveal its role in flagella system.

Project description:Major foodborne bacterial pathogens, such as Campylobacter jejuni, have devised complex strategies to establish and foster intestinal infections. For more than two decades researchers have used immortalized cell lines derived from human intestinal tissue to dissect C. jejuni-host cell interactions. Known from these studies is that C. jejuni virulence is multifactorial, requiring a coordinated response to produce virulence factors that facilitate the bacterium’s host-cell interactions. This study was initiated to identify C. jejuni proteins that contribute to adaptation to the host cell environment and cellular invasion. We demonstrated that C. jejuni responds to INT 407 and Caco-2 cells in a similar fashion at the cellular and molecular levels. Active protein synthesis was found to be required for C. jejuni to maximally invade these host cells. Proteomic and transcriptomic approaches were then used to define the protein and gene expression profiles of C. jejuni co-cultured with cells. By focusing on those genes showing increased expression by C. jejuni when co-cultured with epithelial cells, we discovered that C. jejuni quickly adapts to co-culture with epithelial cells by synthesizing gene products that enable it to acquire specific amino acids for growth, scavenge for inorganic molecules including iron, resist reactive oxygen/nitrogen species, and promote bacteria-host cell interactions. Based on these findings, we selected a subset of the genes involved in chemotaxis and the regulation of flagellar assembly and generated C. jejuni deletion mutants for phenotypic analysis. Binding and internalization assays revealed significant differences in the interaction of C. jejuni chemotaxis and flagellar regulatory mutants. The identification of genes involved in C. jejuni adaptation to culture with host cells provides new insights into the infection process.

Project description:Cj0440c, a putative transcriptional regulator, was over-expressed in the high-level erythromycin-resistant (Eryr) Campylobacter jejuni strains. To determine the role of Cj0440c on the development and fitness of erythromycin resistance in C. jejuni, we knocked out Cj0440c in Eryr strain (R) to obtain the Cj0440c mutants (RM). Then we compared the transcriptome of the Cj0440c mutant with that of the parent strain using DNA microarray. These comparisons identified 9 genes that showed a M-bM-^IM-%2-fold change in expression in RM. The differentially expressed genes in RM are related to flagellar biosynthesis and unknown functions. What's more, katA, encoding catalase, down-regulated in RM. Cj0440c may progress flagellar genes expression, help to escape drug pressure and disseminate and colonize smoothly, and Cj0440c in Eryr Campylobacter may protect bacteria from harmful oxygen stress from the host immune system, other microorganism in host intestinal and its own products. These findings indicate that Cj0440c is essential for the fitness (growth) of resistant C. jejuni by controlling the expression of several genes involved in flagellar assembly and catalase, enhancing cell motility for colonization and invasion under the pressure of drug. This study widened our understanding on the molecular mechanism of resistance and provides scientific reference for drug research and application. An eight-chip study using total RNA recoverd from four separate resistant-type cultures of Erythrocin-resistant Campylobacter jejuni NCTC 111168 (R) and four separate cultures of a mutant strain, erythrocin-resistant Campylobacter jejuni NCTC 11168 delta- Cj0440c (RM), in which Cj0440c is deleted. Each chip measures the expression level of 1634 genes from Campylobacter jejuni NCTC 11168.

Project description:Campylobacter jejuni is a major cause of food poisoning worldwide, and remains the main infective agent in gastroenteritis and related intestinal disorders in Europe and the USA. As with all bacterial infections, the stages of adhesion to host tissue, survival in the host and eliciting disease all require the synthesis of proteinaceous virulence factors on the ribosomes of the pathogen. Here, we describe how C. jejuni virulence is attenuated by altering the methylation of its ribosomes to disrupt the composition of its proteome, and how this in turn provides a means of identifying factors that are essential for infection and pathogenesis. Specifically, inactivation of the C. jejuni Cj0588/TlyA methyltransferase prevents methylation of nucleotide C1920 in the 23S rRNA of its ribosomes and reduces the pathogen’s ability to form biofilms, to attach, invade and survive in host cells, and to provoke the innate immune response. Mass spectrometric analyses of C. jejuni TlyA-minus strains revealed an array of subtle changes in the proteome composition. These included reduced amounts of the cytolethal distending toxin (CdtC) and the MlaEFD proteins connected with outer membrane vesicle (OMV) production. Inactivation of the cdtC and mlaEFD genes confirms the importance of the toxin and OMVs in establishing infection. Collectively, the data identify a collection of genes required for the onset of human campylobacteriosis, and serve as a proof of principle for use of this approach in detecting proteins involved in bacterial pathogenesis.

Project description:Campylobacter jejuni is a prevalent cause of bacterial gastroenteritis in humans worldwide. The mechanism by which C. jejuni survives stomach acidity remains unknown. Herein, we have demonstrated that C. jejuni with a fur deletion was more sensitive to acid than the wild-type strain. Profiling the acid stimulon of the C. jejuni ∆fur mutant allowed us to uncover Fur-regulated genes under acidic conditions. The up-regulation of heat shock genes and the down-regulation of genes involved in flagellar and cell envelope biogenesis in the fur mutant highlight the importance of Fur in Campylobacter acid survival. Interestingly, prior acid exposure of C. jejuni cross-protected the bacterium against oxidative stress. Western-blot analysis and real-time qRT-PCR revealed an increased expression of the catalase KatA in acid-stressed C. jejuni relative to unstressed bacteria. The enhanced survival of C. jejuni to oxidative stress was shown to be Fur-dependent through the regulation of katA expression. Electrophoretic mobility shift assay (EMSA) demonstrated that the binding affinity between Fur and katA is reduced under low pH allowing for higher expression of katA and the defense against oxidative stress. Strikingly, the ∆fur mutant exhibited a reduced virulence capacity in both human epithelial cells and G. mellonella infection model as compared to C. jejuni wild-type. Altogether, this is the first study showing that in addition to its role in iron metabolism, Fur is an important regulator of C. jejuni acid response and cross-protection against other stresses. Moreover, our results clearly demonstrate that Fur plays a substantial role in C. jejuni host pathogenesis. Campylobacter jejuni is a prevalent cause of bacterial gastroenteritis in humans worldwide. The mechanism by which C. jejuni survives stomach acidity remains unknown. Herein, we have demonstrated that C. jejuni with a fur deletion was more sensitive to acid than the wild-type strain. Profiling the acid stimulon of the C. jejuni ∆fur mutant allowed us to uncover Fur-regulated genes under acidic conditions. The up-regulation of heat shock genes and the down-regulation of genes involved in flagellar and cell envelope biogenesis in the fur mutant highlight the importance of Fur in Campylobacter acid survival. Interestingly, prior acid exposure of C. jejuni cross-protected the bacterium against oxidative stress. Western-blot analysis and real-time qRT-PCR revealed an increased expression of the catalase KatA in acid-stressed C. jejuni relative to unstressed bacteria. The enhanced survival of C. jejuni to oxidative stress was shown to be Fur-dependent through the regulation of katA expression. Electrophoretic mobility shift assay (EMSA) demonstrated that the binding affinity between Fur and katA is reduced under low pH allowing for higher expression of katA and the defense against oxidative stress. Strikingly, the ∆fur mutant exhibited a reduced virulence capacity in both human epithelial cells and G. mellonella infection model as compared to C. jejuni wild-type. Altogether, this is the first study showing that in addition to its role in iron metabolism, Fur is an important regulator of C. jejuni acid response and cross-protection against other stresses. Moreover, our results clearly demonstrate that Fur plays a substantial role in C. jejuni host pathogenesis.

Project description:Cj0440c encodes a putative transcriptional regulator. To determine the role of Cj0440c in C.jejuni, we knocked out Cj0440c in the wild-type strain (S) to obtain the Cj0440c mutants (SM). Then we compared the transcriptome of the Cj0440c mutant with that of the parent strain using DNA microarray. These comparisons identified 19 genes that showed a≥2-fold change in expression in SM. The differentially expressed genes in SM encode proteins involved in flagellar biosynthesis, O-linked glycosylation and hypothetical proteins with unknown fuctions. Cj0440c may regulate flagellar structural element expression or as a compenent of flagellar complex co-expressed with other flagellar genes. Subsequent experiments demonstrated that inactivation of Cj0440c affected corresponding phenotypes of C.jejuni, including broken flagella, weaker motility and reduced colonization ability in chickens. These findings indicate that Cj0440c governs the expression of multiple genes related to flagellar biosynthesis and O-linked glycosylation. This study provides favorable evidence for completing the information of the Campylobacter jejuni genome.