Project description:It is postulated that below a transcriptomic-based point of departure, adverse effects are unlikely to occur, thereby providing a chemical concentration to use in screening level hazard assessment. The present study extends previous work describing a high throughput fathead minnow assay that can provide full transcriptomic data after exposure to a test chemical. One day post-hatch fathead minnows were exposed to ten concentrations of three representatives of four chemical modes of action: organophosphates, ecdysone receptor agonists, plant photosystem II inhibitors, and estrogen receptor agonists for 24 hours. Concentration response modeling was performed on whole body gene expression data from each exposure, using measured chemical concentrations when available. Transcriptomic points of departure in larval fathead minnow were lower than apical effect concentrations across fish species but not always lower than toxic effect concentrations in other aquatic taxa like crustaceans and insects. The point of departure was highly dependent on measured chemical concentration which were often lower than the nominal concentration. Differentially expressed genes between chemicals within modes of action were compared and often showed statistically significant overlap. In addition, reproducibility between identical exposures using a positive control chemical (CuSO4) and variability associated with the transcriptomic point of departure using in-silico sampling were considered. Results extend a transcriptomic-compatible fathead minnow high throughput assay for possible use in ecological hazard screening.

Project description:RNA-seq expression assays were done in larval Pimephales promelas (Fathead minnow, FHM) exposed to 10 chemicals (3 metals, 4 Neonicotinoids, and 3 pharmaceuticals) over a range of concentrations to derive relatively short term transcriptomics based points of departure (tPODs). tPODs were compared to apical points of departures (aPODs) to investigate the potential use of the FHM tPODS as part of a high throughput approach that might be used in a regulatory context.

Project description:Traditional toxicity testing has been unable to keep pace with the introduction of new chemicals into commerce. Consequently, there are limited or no toxicity data upon which to base a risk assessment for many chemicals to which fish and wildlife may be exposed. Per- and polyfluoroalkyl substances (PFAS) are emblematic of this issue in that most the ecological hazards of most PFAS remain uncharacterized. The present study employed a high throughput assay to identify the concentration at which 20 PFAS, with diverse properties, elicited a concerted gene expression response in larval fathead minnows (Pimephales promelas, 5-6 days post-fertilization) exposed for 24 h. Based on a reduced transcriptome approach that measured whole body expression of 1832 genes, the median transcriptomic point of departure (tPOD) for the 20 PFAS tested was 10 µM. Longer chain carboxylic acids (12-13 C-F) and an eight C-F di-alcohol, N-alkyl sulfonamide, and telomer sulfonic acid were among the most potent PFAS, eliciting gene expression responses at concentrations below 1 µM. With a few exceptions, larval fathead minnow tPODs were concordant with those based on whole transcriptome response in human cell lines. However, larval fathead minnow tPODs were often greater than those for Daphnia magna exposed to the same PFAS. The tPODs overlapped concentrations at which other sub-lethal effects have been reported in fish (available for 10 PFAS; including a range of species, life stages, and study designs). Nonetheless, fathead minnow tPODs were all orders of magnitude higher than aqueous PFAS concentrations detected in tributaries of the North American Great Lakes suggesting a substantial margin of safety in those systems, even for PFAS with significant potential for bioaccumulation. Overall, results broadly support the use of a fathead minnow larval transcriptomics assay to derive screening level potency estimates for use in ecological risk-based prioritization. Traditional toxicity testing has been unable to keep pace with the introduction of new chemicals into commerce. Consequently, there are limited or no toxicity data upon which to base a risk assessment for many chemicals to which fish and wildlife may be exposed. Per- and polyfluoroalkyl substances (PFAS) are emblematic of this issue in that most the ecological hazards of most PFAS remain uncharacterized. The present study employed a high throughput assay to identify the concentration at which 20 PFAS, with diverse properties, elicited a concerted gene expression response in larval fathead minnows (Pimephales promelas, 5-6 days post-fertilization) exposed for 24 h. Based on a reduced transcriptome approach that measured whole body expression of 1832 genes, the median transcriptomic point of departure (tPOD) for the 20 PFAS tested was 10 µM. Longer chain carboxylic acids (12-13 C-F) and an eight C-F di-alcohol, N-alkyl sulfonamide, and telomer sulfonic acid were among the most potent PFAS, eliciting gene expression responses at concentrations below 1 µM. With a few exceptions, larval fathead minnow tPODs were concordant with those based on whole transcriptome response in human cell lines. However, larval fathead minnow tPODs were often greater than those for Daphnia magna exposed to the same PFAS. The tPODs overlapped concentrations at which other sub-lethal effects have been reported in fish (available for 10 PFAS; including a range of species, life stages, and study designs). Nonetheless, fathead minnow tPODs were all orders of magnitude higher than aqueous PFAS concentrations detected in tributaries of the North American Great Lakes suggesting a substantial margin of safety in those systems, even for PFAS with significant potential for bioaccumulation. Overall, results broadly support the use of a fathead minnow larval transcriptomics assay to derive screening level potency estimates for use in ecological risk-based prioritization.

Project description:Comparing transcriptomic points of departure to apical effect concentrations for larval fathead minnow exposed to chemicals with four different modes of action

Project description:As part of the Great Lakes Restoration Initiative, a series of chemical monitoring and surveillance efforts have detected approximately 550 chemicals in Great Lakes tributaries. Among these, there were 140 chemicals for which no empirical toxicity data were available to support prioritization. The aim of the present study was to generate transcriptomic points of departure (tPODs) for 10 of these compounds and demonstrate how they could be applied in a screening-level prioritization. Organisms representing three different trophic levels of the aquatic food-web (Pimephales promelas – secondary consumer, Daphnia magna-primary consumer, and R. subcapitata-primary producer). were exposed for 24 h to a ½-log dilution series of nominal exposure concentrations typically ranging from 66.7 to 0.021 µM of each chemical. In addition to observations of apical effects such as survival and morphology, whole body transcriptomic responses to each chemical were evaluated with targeted analysis using TempO-seq for P. promelas and D. magna and non-targeted full RNA-seq for R. subcapitata. Benchmark concentrations (BMCs) were calculated for each gene showing a concentration-dependent expression pattern. The tPOD for each chemical-species combination was defined as the 10th percentile of the BMCs. The tPODs ranged from 0.18 to 10.8 µM for P. promelas and 0.32 to 29 µM for D. magna, with the most potent of the chemicals tested being fipronil carboxamide. For R. subcapitata, the tPODs ranged from 0.04 to 1.77 µM, with gabapentin as the most potent chemical tested. Empirically derived tPODs from these data poor chemicals, as well as tPODs from previously tested data rich chemicals, were compared with concentrations detected in the Great Lakes basin. This work demonstrates the potential utility of emerging ecological high-throughput transcriptomics assays to support timely screening and prioritization of data poor environmental contaminants.

Project description:As part of the Great Lakes Restoration Initiative, a series of chemical monitoring and surveillance efforts have detected approximately 550 chemicals in Great Lakes tributaries. Among these, there were 140 chemicals for which no empirical toxicity data were available to support prioritization. The aim of the present study was to generate transcriptomic points of departure (tPODs) for 10 of these compounds and demonstrate how they could be applied in a screening-level prioritization. Organisms representing three different trophic levels of the aquatic food-web (Pimephales promelas – secondary consumer, Daphnia magna-primary consumer, and R. subcapitata-primary producer). were exposed for 24 h to a ½-log dilution series of nominal exposure concentrations typically ranging from 66.7 to 0.021 µM of each chemical. In addition to observations of apical effects such as survival and morphology, whole body transcriptomic responses to each chemical were evaluated with targeted analysis using TempO-seq for P. promelas and D. magna and non-targeted full RNA-seq for R. subcapitata. Benchmark concentrations (BMCs) were calculated for each gene showing a concentration-dependent expression pattern. The tPOD for each chemical-species combination was defined as the 10th percentile of the BMCs. The tPODs ranged from 0.18 to 10.8 µM for P. promelas and 0.32 to 29 µM for D. magna, with the most potent of the chemicals tested being fipronil carboxamide. For R. subcapitata, the tPODs ranged from 0.04 to 1.77 µM, with gabapentin as the most potent chemical tested. Empirically derived tPODs from these data poor chemicals, as well as tPODs from previously tested data rich chemicals, were compared with concentrations detected in the Great Lakes basin. This work demonstrates the potential utility of emerging ecological high-throughput transcriptomics assays to support timely screening and prioritization of data poor environmental contaminants.

Project description:As part of the Great Lakes Restoration Initiative, a series of chemical monitoring and surveillance efforts have detected approximately 550 chemicals in Great Lakes tributaries. Among these, there were 140 chemicals for which no empirical toxicity data were available to support prioritization. The aim of the present study was to generate transcriptomic points of departure (tPODs) for 10 of these compounds and demonstrate how they could be applied in a screening-level prioritization. Organisms representing three different trophic levels of the aquatic food-web (Pimephales promelas – secondary consumer, Daphnia magna-primary consumer, and R. subcapitata-primary producer). were exposed for 24 h to a ½-log dilution series of nominal exposure concentrations typically ranging from 66.7 to 0.021 µM of each chemical. In addition to observations of apical effects such as survival and morphology, whole body transcriptomic responses to each chemical were evaluated with targeted analysis using TempO-seq for P. promelas and D. magna and non-targeted full RNA-seq for R. subcapitata. Benchmark concentrations (BMCs) were calculated for each gene showing a concentration-dependent expression pattern. The tPOD for each chemical-species combination was defined as the 10th percentile of the BMCs. The tPODs ranged from 0.18 to 10.8 µM for P. promelas and 0.32 to 29 µM for D. magna, with the most potent of the chemicals tested being fipronil carboxamide. For R. subcapitata, the tPODs ranged from 0.04 to 1.77 µM, with gabapentin as the most potent chemical tested. Empirically derived tPODs from these data poor chemicals, as well as tPODs from previously tested data rich chemicals, were compared with concentrations detected in the Great Lakes basin. This work demonstrates the potential utility of emerging ecological high-throughput transcriptomics assays to support timely screening and prioritization of data poor environmental contaminants.

Project description:Multiple new approach methods (NAMs) are being developed to rapidly screen large numbers of chemicals to aid in hazard evaluation and risk assessments. High-throughput transcriptomics (HTTr) in human cell lines has been proposed as a first-tier screening approach for determining the types of bioactivity a chemical can cause (activation of specific targets vs. generalized cell stress) and for calculating transcriptional points of departure (tPODs) based on changes in gene expression. In the present study, we examine a range of computational methods to calculate tPODs from HTTr data, using six data sets in which MCF7 cells cultured in two different media formulations were treated with a panel of 44 chemicals for 3 different exposure durations (6, 12, 24 hr).

Project description:In this study, fathead minnow larvae were exposed to eight concentrations of two glucocorticoid receptor agonists, dexamethasone and fluticasone, and assessed transcriptome-wide gene expression changes using RNA-seq. Differential gene expression analysis revealed substantial overlap in affected genes between the two compounds, supporting their shared mechanism of action. Transcriptomic points of departure (tPODs) were calculated to identify concentrations at which early transcriptomic responses would likely occur. Functional enrichment analysis identified activated biological pathways and enabled the calculation of biological pathway altering concentrations (BPACs). Both compounds significantly altered pathways related to glucocorticoid activity, with fluticasone showing higher potency in most of the pathways. The significant overlap in differentially expressed genes and enriched pathways provides evidence that transcriptomic profiling can effectively detect shared mechanisms of action between related compounds. These findings support the utility of RNA-seq data in read-across approaches for chemical risk assessment and highlight the conserved molecular responses to glucocorticoid receptor activation in fathead minnows.

Project description:Per- and polyfluoroalkyl substances (PFAS) represent a large group of contaminants of concern based on their widespread use, distribution and persistence in the environment, and potential toxicity. Many of the traditional models for estimating toxicity, bioaccumulation, and other relevant toxicological properties are not well suited for PFAS. Consequently, there is a need to generate hazard information for a large number of PFAS in an efficient and cost-effective manner. In the present study, Daphnia magna were exposed to multiple concentrations of 22 different PFAS for 24 h, in a 96-well plate format. Following exposure, whole body RNA was extracted and pooled extracts, each representing five exposed individuals, were subjected to RNA sequencing. Following analytical measurements to verify PFAS exposure concentrations in-well, and quality control on processed cDNA libraries for sequencing, concentration-response modeling was applied to the data sets for 18 of the tested compounds, and the concentration at which a concerted molecular response occurred (transcriptomic point of departure; tPOD) was calculated. The tPODs, based on average measured concentration of PFAS in the exposure wells, generally ranged from 0.03-0.58 µM (9.9-350 µg/L; interquartile range). In most cases, these concentrations were two orders of magnitude lower than similarly calculated tPODs for human cell lines exposed to PFAS. They were also lower than apical effect concentrations reported for seven PFAS for which some crustacean or invertebrate toxicity data were available, although there were a few exceptions. However, despite being lower than most other available hazard benchmarks, the Daphnia magna tPODs were, on average, four orders of magnitude greater than the maximum aqueous concentrations of PFAS measured in Great Lakes tributaries. Overall, this high throughput transcriptomics assay with Daphnia magna holds promise as a component of a tiered hazard evaluation strategy employing new approach methodologies.