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ROS burst prolongs transcriptional condensation to slow shoot apical meristem maturation and achieve heat-stress resilience in tomato

Xiaozhen Huang, Nan Xiao, Yue Xie, Xu Cao

2025Developmental Cell17 citationsDOIOpen Access PDF

Abstract

The transition of the shoot apical meristem (SAM) from vegetative growth to flowering, a key step of angiosperm reproductive success, is highly vulnerable to heat stress. Overproduction of reactive oxygen species (ROS) is a hallmark of such environmental stresses, but how SAM exploits the extra ROS to achieve heat-stress resilience is largely unknown. Here, we report that tomato plants respond to heat-induced ROS burst by slowing down SAM maturation and lengthening the vegetative state to achieve heat resilience. Heat-induced extra ROS prolonged the transcriptional condensation status of TERMINATING FLOWER (TMF), a prion-like transcription repressor that undergoes phase separation by sensing hydrogen peroxide (H 2 O 2 ), therefore temporarily delaying activation of flowering transition and extending vegetative growth. Loss-of-function of TMF, or base editing of a single cysteine residue that senses H 2 O 2 , abolishes heat resilience. Our findings demonstrate that transcriptional reprogramming triggered by ROS might be a molecular basis of plant developmental plasticity underlying heat-stress resilience.

Topics & Concepts

BiologyMeristemCell biologyHeat stressResilience (materials science)ShootBotanyAnimal scienceThermodynamicsPhysicsPlant Molecular Biology ResearchPlant Reproductive BiologyPlant Stress Responses and Tolerance
ROS burst prolongs transcriptional condensation to slow shoot apical meristem maturation and achieve heat-stress resilience in tomato | Litcius