Project description:Pentachlorophenol (PCP) is a highly toxic pesticide that was first introduced in the 1930s. The a-proteobacterium Sphingobium chlorophenolicum, which was isolated from PCP-contaminated sediment, has assembled a metabolic pathway capable of mineralizing PCP. Interestingly, this pathway produces four toxic intermediates, which include a chlorinated benzoquinone that is a potent alkylating agent and three chlorinated hydroquinones that produce reactive oxygen species and benzoquinones upon reaction with O2. We sought to identify how the cell tolerates the onslaught of toxic effects associated with these intermediates. RNA-Seq and Tn-Seq were used to probe the response of S. chlorophenolicum to PCP as well as the stresses associated with its exposure and degradation. The results demonstrate that PCP exposure causes dissipation of the proton-motive force and perturbation of the cell envelope, and the downstream intermediates cause oxidative stress. However, the transcriptional response to PCP degradation far exceeds what is actually needed and, for many genes, is actually counter-productive. Prevention of PCP degradation by deletion of the transcriptional regulator, pcpR, increases growth rate in rich medium. These data suggest that, although PCP degradation allows access to a novel nutrient, the benefit of degrading it depends upon the availability of other resources. When resources are abundant, the detrimental effects of the toxic intermediates may outweigh the benefit of the carbon and energy that can be obtained by degrading PCP. However, when resources are scarce, degradation of PCP may provide access to a novel source of carbon and energy as well as detoxification of this anthropogenic pollutant.

Project description:PCP degradation under different electron acceptors Metagenome

Project description:We developed a customized RNA-Seq strategy to identify the 3' termini of degradation intermediates of histone mRNAs. Using this strategy, we identified two types of oligouridylated degradation intermediates: RNAs ending at different sites of the 3' side of the stemloop that resulted from initial degradation by 3'hExo and intermediates near the stop codon and within the coding region. We established a method for identifying degradation intermediates for replication-depdendent histone mRNAs. Histone mRNAs are present in large amounts in S-phase cells. Inhibition of DNA replication results in a rapid degradation of histone mRNA. We developed an approach to selectively amplify the 3' ends of histone mRNA molecules, including degradation intermediates, which we then sequenced. Using a novel bioinformatics platform we identified degradation intermediates including many that had untemplated nts added to the 3' end. We identified a large variety of degradation intermediates that contained oligo(U) tails. We were able to deduce the 3' to 5' pathway of histone mRNA degradation.

Project description:Bile acids are steroid compounds from the digestive tracts of vertebrates that enter agricultural environments in unusual high amounts with manure. Bacteria degrading bile acids can readily be isolated from soils and waters including agricultural areas. Under laboratory conditions, these bacteria transiently release steroid compounds as degradation intermediates into the environment. These compounds include androstadienediones (ADDs), which are C19-steroids with potential hormonal effects. Experiments with Caenorhabditis elegans showed that ADDs derived from bacterial bile acid degradation had effects on its tactile response, reproduction rate, and developmental speed. Additional experiments with a deletion mutant as well as transcriptomic analyses revealed that these effects might be conveyed by the putative testosterone receptor NHR-69. Soil microcosms showed that the natural microflora of agricultural soil is readily induced for bile acid degradation accompanied by the transient release of steroid intermediates. Establishment of a model system with a Pseudomonas strain and C. elegans in sand microcosms indicated transient release of ADDs during the course of bile acid degradation and negative effects on the reproduction rate of the nematode. This proof-of-principle study points at bacterial degradation of manure-derived bile acids as a potential and so-far overlooked risk for invertebrates in agricultural soils.

Project description:We developed a customized RNA-Seq strategy to identify the 3' termini of degradation intermediates of histone mRNAs. Using this strategy, we identified two types of oligouridylated degradation intermediates: RNAs ending at different sites of the 3' side of the stemloop that resulted from initial degradation by 3'hExo and intermediates near the stop codon and within the coding region. We established a method for identifying degradation intermediates for replication-depdendent histone mRNAs. Histone mRNAs are present in large amounts in S-phase cells. Inhibition of DNA replication results in a rapid degradation of histone mRNA. We developed an approach to selectively amplify the 3' ends of histone mRNA molecules, including degradation intermediates, which we then sequenced. Using a novel bioinformatics platform we identified degradation intermediates including many that had untemplated nts added to the 3' end. We identified a large variety of degradation intermediates that contained oligo(U) tails. We were able to deduce the 3' to 5' pathway of histone mRNA degradation. RNA-seq with a custom 3' linker: The samples analyzed included two biological replicates of RNAs before and 20 min after HU treatment (samples 1, 26, 27) capped RNAs from cells treated with HU for 20 min (samples 2,3,16,17) RNA isolated from polyribosomes 20 min after HU treatment, from untreated cells (samples 4-9) and cells treated with pactamycin for 5 min (samples 10-15); from cells in which the exosome subunit Pml/SC100 had been knocked down (samples 22-23) and cells treated with the control siRNA (samples 20-21). Please note that, for Sample 2 and Sample 3, the sequencer was unable to recover both ends in the mate pairs for these two sequencing runs, but we chose to use these data anyway since the reads that were recovered included the 3' linker that we used to determine the presence of untemplated additions.

Project description:Narcosis or baseline toxicity is the inert toxicity of hydrophobic compounds, supposed to take place at the level of the cellular membranes. Based on the linear relationship between the toxicity (logEC50) and the hydrophobicity (logKow), class I and II narcotizing compounds are recognized, in which the latter group is assumed to exert additional toxic mechanisms by hydrogen bond donor acidity by their polar groups. Chlorinated anilines, which occur often in the environment as degradation products of certain pesticides , are considered to be narcotizing compounds. In this study the transcriptional responses of the soil arthropod Folsomia candida are investigated upon exposure to a series of anilines with increasing chlorination. A discrimination between class1 and class2 narcotizing compound is being made.

Project description:Through chemical contamination of natural environments, microbial communities are exposed to many different types of chemical stressors; however, research on whole genome responses to this contaminant stress is limited. This study examined the transcriptome response of a common soil bacterium, Pseudomonas aeruginosa, to the common environmental contaminant pentachlorophenol (PCP). Cells were grown in chemostats at a low growth rate to obtain substrate-limited, steady-state, balanced-growth conditions. The PCP stress was administered as a continuous increase in concentration, and samples taken over time were examined for physiological function changes with whole cell acetate uptake rates (WAUR) and cell viability, and for gene expression changes using Affymetrix GeneChip technology and RT-PCR. Cell viability, measured by heterotrophic plate counts, showed a moderately steady decrease after exposure to the stressor, but WAURs did not change in response to PCP. In contrast to the physiological data, the microarray data showed significant changes in the expression of several genes. In particular, genes coding for multi-drug efflux pumps, including MexAB-OprM, were strongly upregulated. The upregulation of these efflux pumps protected the cells from the potentially toxic effects of PCP, allowing the physiological whole-cell function to remain constant. Experiment Overall Design: Cells of P. aeruginosa were grown in steady-state nutrient-limiting conditions using a minimal medium with acetate as the sole carbon source. PCP was added as a continuous input, and the samples were taken at timepoints corresponding to approximately 0.5, 1, and 2 generation times. Reactors were run at least in triplicate, and samples from duplicate WT reactors and a single RpoS- reactor were used for the microarrays. Gene expression is reported as the average fold-change associated with gene expression of PCP-shocked cells compared with the pre-PCP timepoint (0 hours) for the WT.

Project description:Through chemical contamination of natural environments, microbial communities are exposed to many different types of chemical stressors; however, research on whole genome responses to this contaminant stress is limited. This study examined the transcriptome response of a common soil bacterium, Pseudomonas aeruginosa, to the common environmental contaminant pentachlorophenol (PCP). Cells were grown in chemostats at a low growth rate to obtain substrate-limited, steady-state, balanced-growth conditions. The PCP stress was administered as a continuous increase in concentration, and samples taken over time were examined for physiological function changes with whole cell acetate uptake rates (WAUR) and cell viability, and for gene expression changes using Affymetrix GeneChip technology and RT-PCR. Cell viability, measured by heterotrophic plate counts, showed a moderately steady decrease after exposure to the stressor, but WAURs did not change in response to PCP. In contrast to the physiological data, the microarray data showed significant changes in the expression of several genes. In particular, genes coding for multi-drug efflux pumps, including MexAB-OprM, were strongly upregulated. The upregulation of these efflux pumps protected the cells from the potentially toxic effects of PCP, allowing the physiological whole-cell function to remain constant. Keywords: stress response to pentachlorophenol

Project description:Insulin degrading enzyme (IDE) is a major enzyme responsible for insulin degradation in the liver. The modulation of insulin degrading enzyme activity is hypothesized to be a link between T2DM and liver cancer. Results provide insight into role of IDE in proliferation and other cell functions.

Project description:This study examines genome-wide expression of the phenanthrene-degrading Sphingomonas sp. LH128 as a response to long-term starvation stress. For this purpose, the strain was subjected to complete nutrient starvation for 6 months after growth on a rich medium. Survival was monitored by plating, physiological response was examined by flow cytometry and FAME analysis, and this response was related to transcriptomic response as determined by whole-genome microarray analysis. The data showed that decreased gene functions involved in ribosomal proteins biosynthesis, decreased chromosomal replication, increased gene functions involved in stringent regulation of gene expression, increased gene functions involved in genetic exchange and recombination, increased efflux systems, increased degradation of rRNA, and increased M-NM-2-oxidation of fatty acids to access stored nutrients. Genes involved in PAH degradations appears to be with decreased expression. Transcriptomic response of phenanthrene degrading Sphingomonas sp. LH128 starved for 6 month in isotonic solution of 0.01 mM MgS04 was studied using genome-wide gene expression analysis. For this purpose, the strain was pregrown in minimal medium to an OD600 of 0.5, washed twice with 0.01 mM MgS04 and resuspended in the same solution to an OD of 0.5. RNA was extracted both from starved cells and from the initial culture (non-starved cells) and cDNA was synthesized and labeled with Cy3. Transcriptomic response of three replicates were analyzed and compared with the initial inoculum