The epigenetic set-point: metabolic and redox gating of developmental transitions in plants.

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Authors

Abstract

Plants survive fluctuating environments by converting transient stress signals into stable developmental decisions; however, the biophysical logic that filters environmental 'noise' from true 'signals' remains elusive. I propose the epigenetic set-point paradigm, in which chromatin acts as a biophysical integrator that couples metabolic and redox inputs to establish developmental thresholds. I delineate the molecular hardware, writers that nucleate chromatin states, readers that compact chromatin, and erasers that reset marks, which convert analog environmental cues into digital, bistable switches at master regulatory loci, such as FLOWERING LOCUS C and VERNALIZATION 1. I present a testable model showing how redox gating of histone erasers mediated by nitric oxide and reactive oxygen species and metabolic gating of chromatin writers mediated by Target of Rapamycin signaling and acetyl-CoA availability collectively modulate developmental transition probabilities. This integration generates a spectrum of memory stabilities, from the Digital Set-Point of vernalization to Metastable Set-Point underlying thermomemory and rare transgenerational inheritance. Finally, I translate this framework into an epibreeding roadmap, proposing the use of single-cell epigenomic approaches for predictive phenology and tunable epigenetic engineering to design crops with 'rheostat-like' resilience. Together, this synthesis positions the epigenetic set-point as a dynamic, programmable logic governing plant adaptation to climate change.

Keywords: chromatin, crop resilience, developmental transitions, epigenetics, metabolic sensing, plant adaptation, redox signaling, vernalization

Source

The New phytologist

Publication Type

Journal Article

Language

English

PubMed ID

41999178