Abstract
Summary Plants that successfully acclimate to stress can resume growth under stressful conditions. The grass Brachypodium distachyon can grow a cold‐adaptive morphology during cold acclimation. Studies on transcriptional memory (TM) have revealed that plants can be primed for stress by adjusting their transcriptional responses, but the function of TM in stress acclimation is not well understood. We investigated the function of TM during cold acclimation in B. distachyon.Quantitative polymerase chain reaction (qPCR), RNA‐seq and chromatin immunoprecipitation qPCR analyses were performed on plants exposed to repeated episodes of cold to characterize the presence and stability of TM during the stress and growth responses of cold acclimation.Transcriptional memory mainly dampened stress responses as growth resumed and as B. distachyon became habituated to cold stress. Although permanent on vernalization gene VRN1, TMs were short‐term and reversible on cold‐stress genes. Growing under cold conditions also coincided with the acquisition of new and targeted cold‐induced transcriptional responses.Overall, TM provided plasticity to cold stress responses during cold acclimation in B. distachyon, leading to stress habituation, acquired stress responses, and resumed growth. Our study shows that chromatin‐associated TMs are involved in tuning plant responses to environmental change and, as such, regulate both stress and developmental components that characterize cold‐climate adaptation in B. distachyon.
Highlights
Understanding the mechanisms of phenotypic plasticity in plants is crucial to building a sustainable agriculture, especially under the current world-wide climate and environmental crises
Our study shows that chromatin-associated transcriptional memory (TM) are involved in tuning plant responses to environmental change and, as such, regulate both stress and developmental components that characterize cold-climate adaptation in B. distachyon
As chilling led to the formation of TMs affecting C-REPEAT BINDING FACTOR1 (CBF1), COR410, ICE RECRYSTALLIZATION INHIBITOR (IRI) and VRN1, we investigated whether these were connected, at their gene loci, to nucleosome occupancy, to levels of H3K27me3 and to the levels of chromatin marks involved in stress-induced TMs, namely H3K4me2 and H3K4me3
Summary
Understanding the mechanisms of phenotypic plasticity in plants is crucial to building a sustainable agriculture, especially under the current world-wide climate and environmental crises. Stress responses were found to be plastic, improving over multiple exposures (Ding et al, 2012; Li et al, 2019; Zuther et al, 2019; Mayer et al, 2020). These modified responses are influenced by stress exposures during which plants build ‘experience’ through stress memories (Crisp et al, 2016; Yeung et al, 2018)
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