Project description:Mycobacterium tuberculosis (Mtb) survives host defenses by adapting to the environmental conditions during infection. A critical survival strategy involves pH homeostasis, mediated by complex signalling systems that regulate metabolic reprogramming and stress responses. While the lysine acetyltransferase Rv0998 is known to support Mtb hypoxia adaptation and metabolic flexibility, its role in acid stress remains unexplored. Here, we investigate how Rv0998 enables acid tolerance by analysing the transcriptomic profiles of the strains under physiological pH (pH 6.8) and acidic pH that mimics phagosomal environment (pH 5.7).

Project description:In order to cause disease, the food- and water-borne pathogen Campylobacter jejuni must face the extreme acidity of the host stomach as well as cope with pH fluctuations in the intestine. In the present study, C. jejuni NCTC 11168 was grown under mild acidic conditions mimicking those encountered in the intestine. The resulting transcriptional profiles revealed how this bacterium fine-tunes gene expression in response to acid stress. This adaptation involves differential expression of respiratory pathways, induction of genes for phosphate transport and repression of energy generation and intermediary metabolism genes. Keywords: acid shock; dose response; transcriptional response to 3 mild-acidic pH growth conditions (pH6.5, pH 6.0 and pH5.0)

Project description:The study of natural genetic variation for plant disease resistance responses is a complementary approach to utilizing mutants to elucidate genetic pathways. While some key genes involved in pathways controlling disease resistance, and signaling intermediates such as salicylic acid and jasmonic acid, have been identified through mutational analyses, the use of genetic variation in natural populations permits the identification of change-of-function alleles, which likely act in a quantitative manner. Whole genome microarrays, such as Affymetrix GeneChips, allow for molecular characterization of the disease response at a genomics level and characterization of differences in gene expression due to natural variation. Differences in the level of gene expression, or expression level polymorphisms (ELPs), can be mapped in a segregating population to identify regulatory quantitative trait loci (expression QTLs) affecting host resistance responses. In order to identify an appropriate RIL population to map QTL controlling disease resistance responses, we performed a parental survey of 7 different Arabidopsis accessions. We treated vegetatively grown plants with either salicylic acid or a control solution, and harvested the plants at 3 different time points after chemical treatment. We present Affymetrix GeneChip microarray expression data for 3 biological replications of this parental survey

Project description:In this study we performed a whole-transcriptome analysis of C. glabrata biofilm cells exposed to different environmental conditions and constraints in order to identify the molecular pathways involved in fluconazole resistance and understand how acidic pH niches, associated with the presence of acetic acid, are able to modulate these responses.

Project description:The success of Mycobacterium tuberculosis (Mtb) is largely due to its ability to withstand numerous stresses imposed by host immunity. Here, we present a data-driven model that captures these adaptive mechanisms and reveals the dynamic interplay of host-derived stresses and genome-encoded regulatory programs in Mtb. The model captures the genome-wide distribution of cis-acting gene regulatory elements and the conditional influences of transcription factors at those elements to elicit environment-specific responses. Analysis of transcriptional responses that may be essential for Mtb’s survival in acidic conditions identified regulatory control by the MtrAB two-component signal system. This data is a comparison of transcriptional differences (RNA-seq) between low pH (pH 5.6) and neutral pH (pH7) of Mtb

Project description:Campylobacter jejuni is the prevalent cause of bacterial gastroenteritis in human worldwide. The ability to survive stomach acidity is a fundamental requirement for C. jejuni to colonize the host and cause disease. However, the mechanism of C. jejuni acid survival is still unknown. Herein, we demonstrated that C. jejuni is able to survive acidic conditions at pH 4 up to 8 min without a drop in viability. The acid stimulon of C. jejuni 81-176 revealed the up-regulation of many genes important for Campylobacter acid survival such as heat shock genes and genes involved in energy metabolism. On the other hand, the repression of ribosomal genes highlights the ability of C. jejuni to direct its machinery to survive stressful conditions. Prior acid exposure cross-protected C. jejuni against oxidative stress suggesting an overlap in C. jejuni’s responses to various stresses. Interestingly, the induced expression of virulence genes in C. jejuni upon acid exposure such as the Campylobacter invasion antigen (ciaB) indicates that acid stress plays a role in C. jejuni host pathogenesis. Acid exposure significantly enhanced C. jejuni pathogenesis in both eukaryotic cells and G. melonella. To the best of our knowledge, this is the first study characterizes the influence of acid stress on C. jejuni pathogenesis in an infection model. Altogether, this study uncovers the transcriptional profile of C. jejuni in response to acidic conditions as those encountered in the stomach. In addition, our results demonstrate that acid stress jump-starts C. jejuni for efficient gut colonization and host pathogenesis. Campylobacter jejuni is the prevalent cause of bacterial gastroenteritis in human worldwide. The ability to survive stomach acidity is a fundamental requirement for C. jejuni to colonize the host and cause disease. However, the mechanism of C. jejuni acid survival is still unknown. Herein, we demonstrated that C. jejuni is able to survive acidic conditions at pH 4 up to 8 min without a drop in viability. The acid stimulon of C. jejuni 81-176 revealed the up-regulation of many genes important for Campylobacter acid survival such as heat shock genes and genes involved in energy metabolism. On the other hand, the repression of ribosomal genes highlights the ability of C. jejuni to direct its machinery to survive stressful conditions. Prior acid exposure cross-protected C. jejuni against oxidative stress suggesting an overlap in C. jejuni’s responses to various stresses. Interestingly, the induced expression of virulence genes in C. jejuni upon acid exposure such as the Campylobacter invasion antigen (ciaB) indicates that acid stress plays a role in C. jejuni host pathogenesis. Acid exposure significantly enhanced C. jejuni pathogenesis in both eukaryotic cells and G. melonella. To the best of our knowledge, this is the first study characterizes the influence of acid stress on C. jejuni pathogenesis in an infection model. Altogether, this study uncovers the transcriptional profile of C. jejuni in response to acidic conditions as those encountered in the stomach. In addition, our results demonstrate that acid stress jump-starts C. jejuni for efficient gut colonization and host pathogenesis.

Project description:Bacteria that live in the acidic environment face number of growth-related challenges from the intracellular pH changes. In order to survive under acidic environment, Lactic acid bacteria must employ multiple genes and proteins to regulate the relative pathways.

Project description:Bacteria that live in the acidic environment face number of growth-related challenges from the intracellular pH changes. In order to survive under acidic environment, Lactic acid bacteria must employ multiple genes and proteins to regulate the relative pathways.

Project description:Global transcriptional analysis of acid-inducible genes in Streptococcus mutans: multiple two-component systems involved in acid adaptation pH is a major environmental factor that regulates gene expression in many bacteria. Streptococcus mutans in dental biofilms is regularly exposed to cycles of acidic pH during the ingestion of fermentable dietary carbohydrates. The ability of S. mutans to tolerate low pH is crucial for its virulence and the pathogenesis in dental caries. To better understand its acid tolerance mechanisms, we used DNA microarray to perform genome-wide transcriptional analysis of S. mutans in response to acidic pH. The results showed that adaptation of S. mutans to pH 5.5 for 2 hrs induced differential expression of nearly 14% of genes in the genome, including 169 up-regulated genes and 108 down-regulated genes, largely categorized into six groups. Especially, we found that the genes encoding multiple two-component systems, including CiaHR, LevSR, LiaSR, ScnKR, HK/RR07 and ComDE, were up-regulated during acid adaptation. These findings were further confirmed by real time qRT-PCR and phenotypic assays of the gene deletion mutants. The results support that the multiple two-component systems are required for S. mutans to orchestrate its signal transduction networks for optimal adaptation to acidic pH.

Project description:As a successful commensal and pathogen of humans, Candida albicans encounters a wide range of environmental changes. Among them, ambient pH is an important factor, which changes frequently and affects many biological processes in this species. The ability to adapt to pH changes is tightly linked with pathogenesis and morphogenesis. In this study, we report that pH has a profound effect on white-opaque switching and sexual mating in C. albicans. Acidic pHs promote white-to-opaque switching but repress sexual mating of opaque cells. The cAMP signaling and Rim101-mediated pH sensing pathways are involved in the regulation of pH-regulated white-opaque switching. Interestingly, white and opaque cells of the cyr1/cyr1 mutant, which is defective in producing cAMP, show distinct growth defects under acidic and alkaline conditions. Phr2 could play a major role in acidic pHs-induced opaque cell formation. We further discover that acidic pH conditions repress sexual mating due to the failure of activation of the Ste2-mediated a-pheromone response pathway. The effects of pH changes on phenotypic switching and sexual mating could be a balance behavior between host adaptation and sexual reproduction.