Sex-specific multigenerational epigenetic responses to real-world chemical mixture exposure in an outbred sheep model

Establishing whether real-world environmental chemical (EC) exposure can induce heritable epigenetic modifications in large, outbred mammals is key to determining long-term developmental impacts of the human exposome. Using an established biosolids-treated pasture (BS) sheep model, we investigated whether gestational exposure to low-level mixtures of EC induced heritable changes in DNA methylation across three generations of sheep. Reduced-representation bisulfite sequencing of liver, blood, and sperm, combined with a structured, lineage-controlled breeding design, revealed widespread but lineage- and sex-specific differentially methylated loci (DML) in F1 offspring, with detectable alterations evident in F2 and F3 descendants. Although most DML were unique to individual sire lineages, or to a single generation, subsets of loci showed repeated involvement across generations and were associated with altered gene expression in F3 descendants. Sperm from F1 males exhibited reduced methylation at numerous loci and, together with seminal plasma, revealed differential expression of several microRNAs. These effects, however, showed limited persistence in F2 males, indicative of intergenerational rather than fully transgenerational persistence. Collectively, these findings demonstrate that complex, low-level chemical exposures can elicit recurrent, sexually dimorphic epigenetic responses in outbred species, but underscore the challenge of disentangling exposure-induced inheritance from genetically regulated methylation variation. Significance StatementEnvironmental chemical (EC) exposures are ubiquitous, yet their capacity to induce heritable epigenetic changes in large, genetically diverse mammals is poorly understood. Using a real-world exposome-based sheep model, we demonstrate that low-level gestational EC exposure leads to sexually-dimorphic and lineage-dependent alterations in DNA methylation that can extend to unexposed descendants. Although genetic ancestry exerts a dominant influence over these responses, repeated alterations at specific loci suggests that environmentally induced epimutations can reoccur across generations in certain genomic contexts.