Project description:To identified the differential expressed genes between the arsenic exposure cells and wild type cells As is a well- known carcinogen, it receives special attention. Due to its ubiquitous distribution in the environment, a unicellular model system related to the environment will be useful in toxicological research of arsenic. The eukaryotic protist Tetrahymena thermophila is a well-established model in classical toxicology and now a potential model at genomic level. In the present study, Tetrahymena thermophila was inbred with arsenate. With the use of microarray technique, the genes differentially expressed at 4 time points in exposure to arsenate were screened out. The major biological processes involved and their changes over time were identified with enrichment analysis and transformed expression data. Characteristics of arsenic toxicity and response to arsenic were identified, proving T. thermophila a good unicellular model for arsenic toxicological research at genomic level.

Project description:The objective of this study is to identify genes involved in arsenic stress and more particularly to see whether the presence of arsenic can highlight a link between mobility and oxidation

Project description:Transcriptional response to growth with arsenite by the haloalkaliphilic sulfur-oxidizer Thioalkalivibrio thiocyanoxidans ARh2 and Tv. jannaschii by performing RNA-seq analysis

Project description:Transcriptional response to growth at low temperature in the haloalkaliphilic sulfur-oxidizer Thioalkalivibrio versutus AL2 and Tv. nitratis ALJ2 by performing RNA-seq analysis

Project description:Chemosynthetic symbioses between bacteria and invertebrates occur worldwide in a wide range of marine habitats. Although they have been intensively investigated, molecular physiological studies of chemoautotrophic bacteria colonizing the surface of animals (ectosymbioses) are scarce. Stilbonematinae nematodes are the only known invertebrates capable of cultivating monocultures of thiotrophic Gammaproteobacteria on their surface. Crucially, as these nematodes migrate through the redox zone of marine sediments, the ectosymbionts directly experience drastic variations in oxygen concentration. Here, by applying an array of omics, Raman microspectroscopy and stable isotope labeling-based techniques, we investigated the effect of varying concentrations of dissolved oxygen on physiology and metabolism of Candidatus Thiosymbion oneisti, the longitudinally dividing ectosymbiont of Laxus oneistus. We show that, unexpectedly, sulfur oxidation genes were upregulated in anoxic relative to oxic conditions, and that carbon fixation genes and incorporation of 13C-labeled bicarbonate were not. Instead, several genes involved in carbon fixation in addition to genes responsible for assimilating organic carbon compounds and polyhydroxyalkanoate (PHA) biosynthesis, as well as nitrogen fixation and urea utilization genes were upregulated in oxic versus anoxic conditions. Furthermore, in the presence of oxygen, stress-related genes were upregulated together with vitamin and cofactor biosynthesis genes likely necessary to withstand its deleterious effects. Based on this first global physiological study of an uncultured, chemosynthetic ectosymbiont, we propose that, in anoxic pore water, it proliferates by utilizing nitrate to oxidize reduced sulfur compounds, whereas, when exposed to oxygen, it exploits aerobic respiration to facilitate energetically costly assimilation of carbon and nitrogen to survive oxidative stress. Both anaerobic sulfur oxidation and its decoupling from carbon fixation represent unprecedented adaptations among chemosynthetic symbionts. We postulate that Ca. T. oneisti originated from an obligate anaerobic, denitrifying sulfur-oxidizer, which, while transitioning from the free-living to the symbiotic lifestyle, evolved mechanisms to survive the oxidative stress inherent to a life attached to an animal.

Project description:Abstract: The crenarchaeal order Sulfolobales collectively contains at least five major terminal oxidase complexes. Based on genome sequence information, all five complexes are found only in Metallosphaera sedula and Sulfolobus tokodaii, the two sequenced Sulfolobales capable of iron oxidization. While specific respiratory complexes in certain Sulfolobales have been characterized previously as proton pumps for maintaining intracellular pH and generating proton motive force (pmf), their contribution to sulfur and iron biooxidation has not been considered. For M. sedula growing in the presence of ferrous iron and reduced inorganic sulfur compounds (RISCs), global transcriptional analysis was used to track the response of specific genes associated with these complexes, as well as other known and putative respiratory electron transport chain elements. ORFs from all five terminal oxidase or bc1-like complexes were stimulated on one or more conditions tested. Components of the fox (Msed0467-0489) and soxNL-cbsABA (Msed0500-0505) terminal/quinol oxidase clusters were triggered by ferrous iron, while the soxABCDD' terminal oxidase cluster (Msed0285-0291) were induced by tetrathionate and S°. Chemolithotrophic electron transport elements, including a putative tetrathionate hydrolase (Msed0804), a novel polysulfide/sulfur/DMSO reductase-like complex (Msed0812-0818), and a novel heterodisulfide reductase-like complex (Msed1542-1550), were also stimulated by RISCs. Furthermore, several hypothetical proteins were found to have strong responses to ferrous iron or RISCs, suggesting additional candidates in iron or sulfur oxidation-related pathways. From this analysis, a comprehensive model for electron transport in M. sedula could be proposed as the basis for examining specific details of iron and sulfur oxidation in this bioleaching archaeon.

Project description:Arsenic is ubiquitously present in nature and various mechanisms have evolved enabling cells to evade toxicity and acquire tolerance. Herein, we explored how Saccharomyces cerevisiae (budding yeast) respond to trivalent arsenic (arsenite) by quantitative and kinetic transcriptome, proteome and sulfur metabolite profiling. Arsenite exposure affected transcription of genes encoding functions related to protein biosynthesis, arsenic detoxification, oxidative stress defense, redox maintenance and proteolytic activity. Importantly, enzymes involved in sulfate assimilation and glutathione biosynthesis were induced at both gene and protein levels. Kinetic metabolic profiling evidenced a significant increase in the pools of sulfur metabolites as well as elevated glutathione levels. Moreover, the flux in the sulfur assimilation pathway as well as the glutathione synthesis rate strongly increased with a concomitant reduction of sulfur incorporation into proteins. By combining comparative genomics and molecular analyses, we pin-pointed transcription factors that mediate thecore of the transcriptional response to arsenite. Taken together, our data reveals that arsenite-exposed cells channel a large part of assimilated sulfur into glutathione biosynthesis and we provide evidence that the transcriptional regulators Yap1p and Met4p control this response in concert. Keywords: stress

Project description:Arsenic is ubiquitously present in nature and various mechanisms have evolved enabling cells to evade toxicity and acquire tolerance. Herein, we explored how Saccharomyces cerevisiae (budding yeast) respond to trivalent arsenic (arsenite) by quantitative and kinetic transcriptome, proteome and sulfur metabolite profiling. Arsenite exposure affected transcription of genes encoding functions related to protein biosynthesis, arsenic detoxification, oxidative stress defense, redox maintenance and proteolytic activity. Importantly, enzymes involved in sulfate assimilation and glutathione biosynthesis were induced at both gene and protein levels. Kinetic metabolic profiling evidenced a significant increase in the pools of sulfur metabolites as well as elevated glutathione levels. Moreover, the flux in the sulfur assimilation pathway as well as the glutathione synthesis rate strongly increased with a concomitant reduction of sulfur incorporation into proteins. By combining comparative genomics and molecular analyses, we pin-pointed transcription factors that mediate thecore of the transcriptional response to arsenite. Taken together, our data reveals that arsenite-exposed cells channel a large part of assimilated sulfur into glutathione biosynthesis and we provide evidence that the transcriptional regulators Yap1p and Met4p control this response in concert. Keywords: stress, time course

Project description:Arsenic is ubiquitously present in nature and various mechanisms have evolved enabling cells to evade toxicity and acquire tolerance. Herein, we explored how Saccharomyces cerevisiae (budding yeast) respond to trivalent arsenic (arsenite) by quantitative and kinetic transcriptome, proteome and sulfur metabolite profiling. Arsenite exposure affected transcription of genes encoding functions related to protein biosynthesis, arsenic detoxification, oxidative stress defense, redox maintenance and proteolytic activity. Importantly, enzymes involved in sulfate assimilation and glutathione biosynthesis were induced at both gene and protein levels. Kinetic metabolic profiling evidenced a significant increase in the pools of sulfur metabolites as well as elevated glutathione levels. Moreover, the flux in the sulfur assimilation pathway as well as the glutathione synthesis rate strongly increased with a concomitant reduction of sulfur incorporation into proteins. By combining comparative genomics and molecular analyses, we pin-pointed transcription factors that mediate thecore of the transcriptional response to arsenite. Taken together, our data reveals that arsenite-exposed cells channel a large part of assimilated sulfur into glutathione biosynthesis and we provide evidence that the transcriptional regulators Yap1p and Met4p control this response in concert. Keywords: stress

Project description:Arsenic is ubiquitously present in nature and various mechanisms have evolved enabling cells to evade toxicity and acquire tolerance. Herein, we explored how Saccharomyces cerevisiae (budding yeast) respond to trivalent arsenic (arsenite) by quantitative and kinetic transcriptome, proteome and sulfur metabolite profiling. Arsenite exposure affected transcription of genes encoding functions related to protein biosynthesis, arsenic detoxification, oxidative stress defense, redox maintenance and proteolytic activity. Importantly, enzymes involved in sulfate assimilation and glutathione biosynthesis were induced at both gene and protein levels. Kinetic metabolic profiling evidenced a significant increase in the pools of sulfur metabolites as well as elevated glutathione levels. Moreover, the flux in the sulfur assimilation pathway as well as the glutathione synthesis rate strongly increased with a concomitant reduction of sulfur incorporation into proteins. By combining comparative genomics and molecular analyses, we pin-pointed transcription factors that mediate thecore of the transcriptional response to arsenite. Taken together, our data reveals that arsenite-exposed cells channel a large part of assimilated sulfur into glutathione biosynthesis and we provide evidence that the transcriptional regulators Yap1p and Met4p control this response in concert. Keywords: stress