Project description:Immune system threat detection hinges on T cells’ ability to perceive varying peptide major-histocompatibility complex (pMHC) antigens. As the Erk and NFAT pathways link T cell receptor engagement to gene regulation, their signaling dynamics may convey information about pMHC inputs. To test this idea, we developed a dual reporter mouse strain and a quantitative imaging assay that, together, enable simultaneous monitoring of Erk and NFAT dynamics in live T cells over day-long timescales as they respond to varying pMHC inputs. Both pathways initially activate uniformly across various pMHC inputs, but diverge only over longer (9+ hrs) timescales, enabling independent encoding of pMHC affinity and dose. These late signaling dynamics are decoded via multiple temporal and combinatorial mechanisms to generate pMHC-specific transcriptional responses. Our findings underscore the importance of long timescale signaling dynamics in antigen perception, and establish a framework for understanding T cell responses under diverse contexts.

Project description:Immune system threat detection hinges on T cells’ ability to perceive varying peptide major-histocompatibility complex (pMHC) antigens. As the Erk and NFAT pathways link T cell receptor engagement to gene regulation, their signaling dynamics may convey information about pMHC inputs. To test this idea, we developed a dual reporter mouse strain and a quantitative imaging assay that, together, enable simultaneous monitoring of Erk and NFAT dynamics in live T cells over day-long timescales as they respond to varying pMHC inputs. Both pathways initially activate uniformly across various pMHC inputs, but diverge only over longer (9+ hrs) timescales, enabling independent encoding of pMHC affinity and dose. These late signaling dynamics are decoded via multiple temporal and combinatorial mechanisms to generate pMHC-specific transcriptional responses. Our findings underscore the importance of long timescale signaling dynamics in antigen perception, and establish a framework for understanding T cell responses under diverse contexts.

Project description:The projected increase in the production and use of nanomaterials is expected to result in a corresponding increase in human exposure, potentially resulting in significant morbidity and mortality. Currently, the lung toxicity of multi-walled carbon nanotubes (MWCNT), a prototype nanomaterial, was investigated in a rat model. The rats were exposed by whole-body inhalation to air (controls) or MWCNT (6 hours/day, 3 days) to result in cumulative doses of 180, 90, 45, 22.5, or 11.25 mg/m3. Lung toxicity and gene expression profiles were determined in the lungs of the control and MWCNT exposed rats one day following termination of the exposures. Moderate lung histological changes, indicative of toxicity, were detected in rats exposed to MWCNT at doses > 45 mg/m3. Changes in toxicity parameters including, lactate dehydrogenase (LDH) activity, oxidant production, cell counts of phagocytes, and cytokine levels were detected in the bronchoalveolar lavage of rats exposed to > 22.5 mg/m3 MWCNT, compared with the air controls. Lung gene expression profiling detected differences in transcript levels (fold change >1.5 and FDR p<0.05) of several genes in the rats exposed to >22.5 mg/m3 MWCNT, compared with the controls. The changes in lung toxicity and gene expression profiles exhibited a dose-response to the MWCNT administered in the rats.

Project description:Hormesis is a dose response phenomenon characterized by a stimulation of an organismal response at low doses of a chemical and inhibition of the response (toxicity) at a higher dose. In the present study, Daphnia magna were exposed to the energetic compound 2,4,6-trinitrotoluene (TNT) for 21 days, and the endpoints survival, growth (length and dry weight), and reproduction (number of neonates per survivor) were assesed, identifying hormetic responses at the lower treatment levels. In order to elucidate the mechanisms leading to hormesis, microarray analysis was performed at 0.004 (hormetic), 0.12 (sometimes hormetic), and 1.85 (toxic) mg/L TNT. Functional and transcriptional benchmark dose analyses performed on differentially expressed genes suggested the involvement of lipid metabolism in hormetic responses and subsequently lipidomic analysis was performed on the same treatments. Lipid analysis supported the hypothesis that TNT exposure affected lipid metabolism, and showed that hormetic effects could be related to increases in some polyunsaturated fatty acids and ecosanoids known to be involved in Daphnia growth and reproduction.

Project description:Production of PFAS has shifted from the most-studied PFAS, longer-chain perfluorinated alkyl acids, to shorter-chain or other alternative moieties including fluoroethers like HFPO-DA (“GenX chemicals”), Nafion Byproducts, and the PFOx homologous series that includes PFO4DA and PFO5DoA. In contaminated study areas, the fluoroethers PFO4DA and PFO5DoA, although detected at relatively low levels in surface water, have been detected in serum and/or tissues with high frequency in humans, wildlife including fish and alligators, and pets including horses. Although these compounds have been detected, there are extremely limited toxicity data available and no developmental toxicology studies that could be used to inform risk assessment or regulatory actions. To address these data gaps, Sprague-Dawley rat dams were exposed via oral gavage from GD18-22 to PFO4DA or PFO5DoA across a series of doses ranging from 0.1 to 62.5 mg/kg/day and, in conjunction with apical measures of toxicity, hepatic transcriptomics in both dam and offspring and serum metabolomics in dams were performed. Differential expression analysis was performed for transcriptomics and metabolomics, and pathway analysis, including a multi-omic integrative analysis, was performed. For PFO5DoA, overt toxicity (substantial body weight loss, fetal mortality) was observed at the highest dose, so data only include up to 30 mg/kg/day. Dimensionality reduction measures including principal components analysis and heatmaps revealed strong separation of clustering between maternal and fetal samples and between chemicals (PFO4DA vs PFO5DoA). Both dams and fetuses exhibited dose-responsive patterns of hepatic gene expression in response to PFO4DA or PFO5DoA. Of the 14,928 genes included in differential expression analysis, PFO4DA exposure in dams resulted in a maximum of 367 differentially expressed genes (DEG) at the highest dose (62.5 mg/kg/d) whereas PFO5DoA resulted in 4,506 DEG at the highest dose (30 mg/kg/d). Even at 10 mg/kg/d, PFO5DoA resulted in 1,915 DEG in dam liver. Fetuses were more affected at lower doses, but the pattern was similar, with PFO4DA resulting in 1,378 DEG at 62.5 mg/kg/d and PFO5DoA 3,653 DEG at 30 mg/kg/d. Several DEG were changed by every dose of PFO5DoA (≥ 0.3 mg/kg/d) in both maternal and fetal samples, including multiple acyl-coA thioesterases (Acot1, Acot2, Acot3, Acot4) and related enzymes that hydrolyze acyl-coA to free fatty acids, as well as Vnn1, a corticosteroid-responsive gene. Hallmark and Reactome pathway analyses of fetal and maternal livers revealed remarkable changes in metabolism of bile acids and salts, fatty acid metabolism, metabolism of lipids and lipoproteins, PPARα activation of gene expression, and phospholipid metabolism. In maternal serum metabolomics, PFO4DA did not result in significant changes at doses up to 62.5 mg/kg/d. In contrast, PFO5DoA exposure resulted in differential metabolite abundance for 149 unique metabolites, with 4 significantly altered at 0.3 mg/kg, 31 metabolites at 1 mg/kg, 51 at 3 mg/kg, 58 at 10mg/kg, and 119 at 30 mg/kg/d. Multi-omics KEGG and Reactome pathway analyses of integrated maternal liver transcriptomics and serum metabolomics revealed significant convergent pathway-level changes as low as 3 mg/kg/d PFO4DA and 0.3 mg/kg/d PFO5DoA exposure. Notable multi-omics pathway level changes include fatty acid metabolism at all doses of PFO5DoA and at PFO4DA ≥ 10 mg/kg/d, with PFO4DA changes driven by the magnitude of transcriptomic changes and low/null detection of metabolites. Striking pathway-level changes identified for hepatic transcriptome and serum metabolome in exposed dams included metabolism, metabolism of lipids, hemostasis, signaling by G-protein coupled receptors (GPCRs), neuronal system, immune and innate immune system, PPARα activation of gene expression, and regulation of lipid metabolism by PPARα. The transcriptomic and metabolomic effects of PFO4DA and PFO5DoA appear consistent with other carboxylic acid PFAS, with primary changes related to lipid metabolism, bile acids, cholesterol, and cellular stress. Although PFO4DA and PFO5DoA are structurally similar, separated by only a CF2O, the potency of transcriptomic and metabolomic effects of developmental exposure to each was significantly different, with 5-day exposure to PFO5DoA causing changes in glucose and lipid metabolism and stress signals at much lower doses than PFO4DA in both dams (~ 35-fold more potent at inducing hepatic DEG) and fetuses (~ 11.6-fold more potent at inducing hepatic DEG). Although it is likely that some differences in toxicity between PFO4DA and PFO5DoA are caused by accumulation differences resulting in different dosimetry, PFO5DoA demonstrated much greater transcriptomic and metabolomic toxicity at equivalent oral doses.

Project description:Acetaminophen is the primary cause of acute liver toxicity in Europe/USA. Therefore, the FDA reconsiders recommendations concerning safe acetaminophen dosage/use. Current tests for liver toxicity are no ideal predictive markers for liver injury. Here, ‘omics techniques (global analysis of metabolomic/gene expression responses) may provide additional insight. To better understand acetaminophen-induced responses at low dose, we evaluated effects of (sub-)therapeutic acetaminophen doses on metabolite formation/global gene-expression changes (including, for the first time, miRNA) in blood/urine samples from healthy human volunteers. Three dose rounds with 6 individuals were performed with 0.5, 2 or 4 g APAP. In the 0.5 and 2 g dose-rounds T0(control) T1, T7 and T25 samples were collected in the 4g round only T0(control) and T25 samples are available.

Project description:Understanding the interactions of nanostructures with biological systems is essential to nanotoxicological research. Using a microarray-based toxicogenomics approach at early stage, this study investigated the relationship between particle size and toxicity of silica particles (SP) with diameters of 30, 70, and 300 nm (SP30, SP70, and SP300) as well as the mechanism of injury in mice. Two experiments with SiO2 particles of different sizes were considered in mice. One was aimed to investigate the dose-response relationship of SP70 toxicity at a dose of 10, 20, or 40 mg/kg (experiment 1), and the other set to study the size-response relationship of SP-induced toxicity using SP30, SP70, or SP300 (experiment 2). In experiment 2, two dosages each of SP30, SP70, and SP300 were performed. One was 10 mg/kg at three particle sizes, and the other was toxic doses of the three particle sizes, i.e., 10 mg/kg for SP30, 40 mg/kg for SP70, and 200 mg/kg for SP300. The toxic doses of the three particle sizes of SP were decided on the basis of the results of histopathological examinations and serum biochemical analysis in our previous study.n = 5

Project description:Acetaminophen is the primary cause of acute liver toxicity in Europe/USA. Therefore, the FDA reconsiders recommendations concerning safe acetaminophen dosage/use. Current tests for liver toxicity are no ideal predictive markers for liver injury. Here, ‘omics techniques (global analysis of metabolomic/gene expression responses) may provide additional insight. To better understand acetaminophen-induced responses at low dose, we evaluated effects of (sub-)therapeutic acetaminophen doses on metabolite formation/global gene-expression changes (including, for the first time, miRNA) in blood/urine samples from healthy human volunteers.

Project description:The plant circadian clock is linked to development on every scale, from control of the cell cycle to determination of flowering time. Of particular importance is the photoperiodic pathway, through which changes of day length (photoperiod) are interpreted. Circadian regulation of this pathway is generally studied in seedlings. This allows researchers to test the effect of different environmental conditions, such as extreme photoperiods or temperature, more rapidly than in adult plants. However, this approach fails to identify links between the photoperiodic pathway and other ageing-related processes, such as senescence. To close this knowledge gap, we collected data from Arabidopsis thaliana at two different timescales: the ‘flowering’ timescale and the ‘daily’ timescale. By shifting the photoperiod from short days (SD) to long days (LD), we induced flowering, via the photoperiodic pathway. We then sampled across 24h at 2, 7, and 12 days after this transition. We find that the regulation of senescence-associated genes begins soon after the transition from SD to LD. We explore how downstream targets of the circadian clock have changes in expression across the flowering timescale. Surprisingly, many genes shift from their time of peak expression, suggesting a widespread rewiring of the circadian clock’s targets during the flowering transition.

Project description:Hormesis is a dose response phenomenon characterized by a stimulation of an organismal response at low doses of a chemical and inhibition of the response (toxicity) at a higher dose. In the present study, Daphnia magna were exposed to the energetic compound 2,4,6-trinitrotoluene (TNT) for 21 days, and the endpoints survival, growth (length and dry weight), and reproduction (number of neonates per survivor) were assesed, identifying hormetic responses at the lower treatment levels. In order to elucidate the mechanisms leading to hormesis, microarray analysis was performed at 0.004 (hormetic), 0.12 (sometimes hormetic), and 1.85 (toxic) mg/L TNT. Functional and transcriptional benchmark dose analyses performed on differentially expressed genes suggested the involvement of lipid metabolism in hormetic responses and subsequently lipidomic analysis was performed on the same treatments. Lipid analysis supported the hypothesis that TNT exposure affected lipid metabolism, and showed that hormetic effects could be related to increases in some polyunsaturated fatty acids and ecosanoids known to be involved in Daphnia growth and reproduction. Chronic toxicity tests was designed to identify the hormetic range of D. magna responses to TNT. Daphnia magna younger than 24 h old and obtained from in-house cultures at the U.S. Army Engineer Research and Development Center, Environmental Laboratory (Vicksburg, MS) were used to initiate the bioassay. The experimental design consisted of one D. magna per test chamber and 10 test chambers per treatment level. In the microarray mass exposure, nominal treatment levels were 0.004, 0.02, 0.12, 0.44, and 1.85 mg/L. Based on the results of the testing in the 50 ml beakers, organisms from three treatments were selected for analysis of gene expression: 0.004, 0.12, and 1.85 mg/L. These treatments were selected to represent a hormetic concentration (0.004 mg/L), a toxic concentration (1.85 mg/L), and an intermediate concentration (0.12 mg/L). A total of 23 arrays used, with 5-6 replicates per each dose (solvent control, 0.004 mg/L, 0.12 mg/L, and 1.85 mg/L).