Sequencing samples from reactors treating wastewater with surfactant
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ABSTRACT: Four samples were collected from biological reactors treating wastewater containing an anionic surfactant (linear alklybenzene sulfonate - LAS)
Project description:The number and type of synthetic chemicals that are being produced worldwide continues to increase significantly. While these industrial chemicals provide numerous benefits, there is no doubt that some have potential to damage the environment and health. Toxicity must be evaluated and use must be carefully controlled and monitored in order to minimize potential damage. DNA microarray technology has become an important new technique in toxicology. We are using the yeast Saccharomyces cerevisiae as a model organism for toxicological study because it is a simple, fast-growing eukaryote that has been thoroughly characterized. In order to evaluate toxicity by newly synthesized or mixture chemicals, toxicity-induced gene expression alteration profiles by known chemicals should be collected. In our study, cells need to be exposed with same experimental cellular condition, semi lethal (IC50), respectively. In the case of SDS (CAS; 151-21-3), the exposure dose was decided as 0.01% by growth curve with continuously diluted exposure. SDS is an anionic surfactant that is suspected to be gastrointestinal or liver toxicant. // Toxicity of anionic detergents determined by Saccharomyces cerevisiae microarray analysis: Sodium n-dodecyl benzene sulfonate (LAS) and sodium dodecyl sulfate (SDS) are popular anionic detergents (surfactants) that are used worldwide and the toxicities of these chemicals have been characterized. We applied these chemicals in a DNA microarray bioassay and determined that the microarray data reflects previous findings and also provides some new information about anionic detergent toxicity. The mRNA expression profiles suggest that LAS and SDS cause damage to membranes and alterations in carbon metabolism, and induce the oxidative stress response. We also found that LAS and SDS induce the pleiotropic drug-resistance network, and that LAS and SDS may be pumped out of yeast cells by this network. Hierarchical clustering of the expression profiles showed that LAS and SDS cause similar features of toxicity and that the toxicity is similar to that of capsaicin but different from that of cadmium and mercury. Keywords: stress response
Project description:We report the discovery of a photo-cleavable anionic surfactant, 4-hexylphenylazosulfonate (Azo) that can be rapidly degraded upon UV irradiation, for top-down proteomics. Azo can effectively solubilize proteins with performance comparable to SDS and is mass spectrometry (MS)-compatible. Azo-aided top-down proteomics allowed the detection of 100-fold more unique proteoforms and enabled the solubilization of membrane proteins for comprehensive characterization of post-translational modifications. Azo is simple to synthesize in large quantity for general use as an SDS replacement.
Project description:The amount of pulmonary surfactant within type II cells and in the alveolar space, referred to as surfactant pool sizes, are tightly regulated. The molecular pathways that sense and regulate surfactant pool size within the alveolus have not been identified and constitute a fundamental knowledge gap in the field. Our data show that mice with a germline mutation in the orphan G-protein-coupled receptor, GPR116, have a 30-fold accumulation of surfactant phospholipids that causes respiratory distress in adult animals. This phenotype is associated with increased surfactant secretion and induction of the purinergic receptor P2RY2 in young animals, and lipid-laden macrophages and alveolar destruction in older animals. We further demonstrate that GPR116 mRNA expression is developmentally regulated in the murine lung with peak expression at birth when surfactant pool sizes are maximal. Within the lung, GPR116 protein expression is restricted to the apical plasma membrane of alveolar type I and type II epithelial cells. To better understand the roles and molecular mechanisms by which Gpr116 influences gene expression in lung, the effect of cell-selective deletion of Gpr116 (Gpr116D/D) on genome-wide mRNA expression profiles was determined in murine type II alveolar epithelial cells. Differentially expressed genes were identified from Affymetrix Murine GeneChips analysis and subjected to gene ontology classification promoter analysis, pathway mapping and literature mining.
Project description:The amount of pulmonary surfactant within type II cells and in the alveolar space, referred to as surfactant pool sizes, are tightly regulated. The molecular pathways that sense and regulate surfactant pool size within the alveolus have not been identified and constitute a fundamental knowledge gap in the field. Our data show that mice with a germline mutation in the orphan G-protein-coupled receptor, GPR116, have a 30-fold accumulation of surfactant phospholipids that causes respiratory distress in adult animals. This phenotype is associated with increased surfactant secretion and induction of the purinergic receptor P2RY2 in young animals, and lipid-laden macrophages and alveolar destruction in older animals. We further demonstrate that GPR116 mRNA expression is developmentally regulated in the murine lung with peak expression at birth when surfactant pool sizes are maximal. Within the lung, GPR116 protein expression is restricted to the apical plasma membrane of alveolar type I and type II epithelial cells.
Project description:The response of bacteria to the conditions at the site of infection is a key part of the transcriptional program that will determine the sucess of the infectious agent. To model the environment of the distal airway, we used bovine pulmonary surfactant (Survanta). P. aeruginosa transcript levels were measured in the presence or absence of Survanta in MOPS minimal medium to identify transcripts altered in response to surfactant. The most highly induced transcript in Survanta was PA5325, renamed sphA based on our findings that the gene was specifically induced by sphingosine derived from the sphingomyelin present in pulmonary surfactant. A divergently transcribed transcription factor, PA5324, was demonstrated to be critical for the sphingosine dependent induction of sphA and was therefore renamed SphR. Microarrays of the sphR mutant cells were compared to wild type to determine the likely SphR regulon. Wild type and sphR mutant cells were pre-grown in MOPS minimal media and then split and resuspended in MOPS pyruvate or MOPS pyruvate + surfactant