Abstract
A number of epigenetic modulating chemicals are known to affect multiple generations of a population from a single ancestral exposure, thus posing transgenerational hazards. The present study aimed to establish a high-throughput (HT) analytical workflow for cost-efficient concentration-response analysis of epigenetic and phenotypic effects, and to support the development of novel Adverse Outcome Pathway (AOP) networks for DNA methyltransferase (DNMT) inhibitor-mediated transgenerational effects on aquatic organisms. The model DNMT inhibitor 5-azacytidine (5AC) and the model freshwater crustacean Daphnia magna were used to generate new experimental data and served as prototypes to construct AOPs for aquatic organisms. Targeted HT bioassays (DNMT ELISA, MS-HRM and qPCR) in combination with multigenerational ecotoxicity tests revealed concentration-dependent transgenerational (F0-F3) effects of 5AC on total DNMT activity, DNA promoter methylation, gene body methylation, gene transcription and reproduction. Top sensitive toxicity pathways related to 5AC exposure, such as apoptosis and DNA damage responses were identified in both F0 and F3 using Gaussian Bayesian network modeling. Two novel epigenetic AOP networks on DNMT inhibitor mediated one-generational and transgenerational effects were developed for aquatic organisms and assessed for the weight of evidence. The new HT analytical workflow and AOPs can facilitate future ecological hazard assessment of epigenetic modulating chemicals.
Highlights
Heritable epigenetic marks, such as DNA methylation and histone modifications can in many cases reflect the life-time exposure history of an organism to environmental stressors (Mirbahai and Chipman, 2014)
The present study showed that the total activity of DNA methyltransferase (DNMT) in F0 D. magna decreased in a concentration-dependent manner after 7 days exposure to 5AC, with a significant reduction of approx. 40% at the highest concentration (Fig. 1)
The present study has integrated a high-throughput laboratory analytical workflow, Bayesian network modeling and bioinformatics to understand the transgenerational effects of DNMT inhibitors (5-azacy tidine) on aquatic organisms, and to support the develop ment of novel epigenetic Adverse Outcome Pathway (AOP) networks for cost-efficient ecological hazard and risk assessment of epigenetic modulators
Summary
Heritable epigenetic marks, such as DNA methylation and histone modifications can in many cases reflect the life-time exposure history of an organism to environmental stressors (Mirbahai and Chipman, 2014). In addition to high-content (HC) OMICS tools, targeted high-throughput (HT) bio assays are needed, allowing the inclusion of more life stages of an organism and exposure conditions of a stressor in the analysis to yield comparative dose/concentration-response data on a temporal scale. Such data can greatly facilitate the development of predictive (eco) toxicological approaches, such as Adverse Outcome Pathways (AOPs) for more efficient chemical safety assessment (Villeneuve et al, 2019).
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