Temporal orchestration of transcriptional and epigenomic programming underlying maternal embryonic diapause in a cricket model
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Facultative diapause, a programmed developmental arrest, enables organisms to survive adverse environmental conditions, representing environmentally induced phenotypic plasticity. The band-legged ground cricket Dianemobius nigrofasciatus provides a unique model for studying diapause mechanisms, exhibiting maternal diapause induction where short-day exposure of mothers triggers embryonic diapause in offspring at the cellular blastoderm stage, the earliest diapause entry point among insects. Here, we investigated how maternally transmitted environmental signals regulate embryonic development at the molecular level. We assembled a high-quality genome (1.45 Gbp) and performed time-series transcriptomic analyses of diapause and non-diapause eggs from 12 to 72 hours post-oviposition (hpo). Despite morphological similarity at 12-24 hpo, diapause-destined eggs showed specific upregulation of ATP-dependent chromatin remodeling genes, particularly Brahma complex core subunits, at 24 hpo. ATAC-seq analysis at 24 hpo revealed reduced chromatin accessibility near neural and cell cycle-related genes in these eggs. Time-series clustering identified a temporal shift, where RNA processing genes peaked at 24 hpo in diapause-destined eggs versus 40 hpo in non-diapause eggs that undergo direct development, suggesting temporal reorganization allows completion of transcriptional processing before developmental arrest. After diapause initiation (56-72 hpo), while non-diapause eggs upregulated neural differentiation and proliferation genes, diapause eggs showed enhanced expression of amino acid metabolism and gluconeogenesis genes, indicating metabolic regulation for long-term survival. Our findings reveal diapause as an actively regulated developmental state involving coordinated epigenetic, transcriptional, and metabolic remodeling. This cricket model provides insights into how maternal environmental signals guide offspring development through integrated molecular mechanisms, with implications for understanding phenotypic plasticity.
Significance Statement
Organisms have evolved sophisticated mechanisms to integrate environmental signals for developmental control, including diapause, a programmed developmental arrest that enables survival during adverse conditions. Maternal effects, where mothers transmit environmental information to influence offspring developmental fate, represent a particularly powerful strategy for controlling diapause induction across diverse taxa. Using the cricket Dianemobius nigrofasciatus , we reveal the molecular orchestration underlying maternal diapause induction. Our integrated multi-omics approach demonstrates that diapause preparation involves precocious activation of chromatin remodeling and RNA processing machinery, followed by comprehensive metabolic restructuring. These findings establish this cricket as an emerging model for diapause research, and reveal coordinated molecular mechanisms that provide a framework for understanding transgenerational environmental adaptation and maternal programming of developmental dormancy across diverse taxa.
