Evolutionarily Conserved Heat-Induced Chromatin Dynamics Drive Heat Stress Responses in Plants
Authors: Wu, T.-Y., Yen, M.-R., Lin, K.-H., Thalimaraw, L., Yang, H.-R., Boonyaves, K., Cheng, C.-Y.
Category: Plant Biology
Model Organism: Marchantia polymorpha
▶ AI Summary
Chromatin accessibility profiling and transcriptomics of Marchantia polymorpha heat‑shock transcription factor (HSF) mutants reveal that HSFA1 governs the placement of cis‑regulatory elements for heat‑induced gene activation, a mechanism conserved across plants, mice, and humans. Integrated gene regulatory network modeling identifies MpWRKY10 and MpABI5B as indirect regulators linking phenylpropanoid and stress pathways, while abscisic acid influences gene expression downstream of HSFA1 without broadly reshaping chromatin. A cross‑species, cross‑condition machine‑learning framework successfully predicts chromatin accessibility and expression, underscoring a conserved regulatory logic in stress responses.