Stress Conditions Modulate the Chromatin Interactions Network in Arabidopsis

Yadav, Vikash Kumar; Singh, Swadha; Yadav, Amrita; Agarwal, Neha; Singh, Babita; Jalmi, Siddhi Kashinath; Tiwari, Vipin Kumar; Kumar, Verandra; Singh, Raghvendra; Sawant, Samir V.

doi:10.3389/fgene.2021.799805

Cited by 5 publications

(6 citation statements)

References 64 publications

(140 reference statements)

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“…S 2 ), similar to previous observations in rice in response to cold stress [ 12 ]. Interestingly, in Arabidopsis , it has been reported that heat stress induces long-range interactions but weakens short-range chromatin interactions [ 35 ]. These results suggest that cold and heat exert opposite effects on chromatin architecture, which might be intuitive as basic thermodynamics indicate that molecules expand with heat and contract with cold.…”

Section: Discussionmentioning

confidence: 99%

High-resolution Hi-C maps highlight multiscale chromatin architecture reorganization during cold stress in Brachypodium distachyon

Zhang

Dai

et al. 2023

BMC Plant Biol

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Background The adaptation of plants to cold stress involves changes in gene expression profiles that are associated with epigenetic regulation. Although the three-dimensional (3D) genome architecture is considered an important epigenetic regulator, the role of 3D genome organization in the cold stress response remains unclear. Results In this study, we developed high-resolution 3D genomic maps using control and cold-treated leaf tissue of the model plant Brachypodium distachyon using Hi-C to determine how cold stress affects the 3D genome architecture. We generated ~ 1.5 kb resolution chromatin interaction maps and showed that cold stress disrupts different levels of chromosome organization, including A/B compartment transition, a reduction in chromatin compartmentalization and the size of topologically associating domains (TADs), and loss of long-range chromatin loops. Integrating RNA-seq information, we identified cold-response genes and revealed that transcription was largely unaffected by the A/B compartment transition. The cold-response genes were predominantly localized in compartment A. In contrast, transcriptional changes are required for TAD reorganization. We demonstrated that dynamic TAD events were associated with H3K27me3 and H3K27ac state alterations. Moreover, a loss of chromatin looping, rather than a gain of looping, coincides with alterations in gene expression, indicating that chromatin loop disruption may play a more important role than loop formation in the cold-stress response. Conclusions Our study highlights the multiscale 3D genome reprogramming that occurs during cold stress and expands our knowledge of the mechanisms underlying transcriptional regulation in response to cold stress in plants.

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Section: Discussionmentioning

confidence: 99%

High-resolution Hi-C maps highlight multiscale chromatin architecture reorganization during cold stress in Brachypodium distachyon

Zhang

Dai

et al. 2023

BMC Plant Biol

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“…New 3C‐based methods that permit the study of how genomes remodel in response to the environment at a fine scale (reviewed in Kumar et al. [ 36 ] ) have revealed that plant genomes can remodel in response to salicylic acid [ 37 ] and probably light (reviewed in Perrella et al. [ 38 ] ).…”

Section: Environmental 3d Chromatin Regulationmentioning

confidence: 99%

“…[33][34][35] Recently, the implications for direct 3D genome remodelling by temperature have also been considered. New 3C-based methods that permit the study of how genomes remodel in response to the environment at a fine scale (reviewed in Kumar et al [36] ) have revealed that plant genomes can remodel in response to salicylic acid [37] and probably light (reviewed in Perrella et al [38] ). In mammals (e.g., mouse liver), TADs that harbour circadian genes switch between active and inactive compartments at different times of the day, resulting in cycles of transcription modulation.…”

Section: Environmental 3d Chromatin Regulationmentioning

confidence: 99%

“…[40] However, in plants and yeast, gene expression changes induced by heat stress were coupled with modification to 3D genome structure. [37,41,42] In different Drosophila cells, heat stress induces a redistribution of architectural proteins that modulate TAD boundaries. [43] This chromatin remodelling, coupled with covalent his-tone modifications, promoted new long-range interactions that formed new enhancer-promoter contacts that affected gene expression.…”

Section: Environmental 3d Chromatin Regulationmentioning

confidence: 99%

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Three dimensions of thermolabile sex determination

et al. 2022

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The molecular mechanism of temperature-dependent sex determination (TSD) is a long-standing mystery. How is the thermal signal sensed, captured and transduced to regulate key sex genes? Although there is compelling evidence for pathways via which cells capture the temperature signal, there is no known mechanism by which cells transduce those thermal signals to affect gene expression. Here we propose a novel hypothesis we call 3D-TSD (the three dimensions of thermolabile sex determination).We postulate that the genome has capacity to remodel in response to temperature by changing 3D chromatin conformation, perhaps via temperature-sensitive transcriptional condensates. This could rewire enhancer-promoter interactions to alter the expression of key sex-determining genes. This hypothesis can accommodate monogenic or multigenic thermolabile sex-determining systems, and could be combined with upstream thermal sensing and transduction to the epigenome to commit gonadal fate.high-throughput chromosome conformation capture; TAD, topologically associated domain; Pg, progesterone; PRC, polycomb repressive complex.

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“…Histone modifications are also crucial for thermotolerance (Zhao et al, 2020), as plants deficient in histone acetyltransferase GCN5 or histone deacetylase 6 ( HDA6 ) exhibit severe defects in thermotolerance under HS (Hu et al, 2015). Finally, HS has been shown to cause chromatin remodeling and change the 3D structure of the genome by altering the large-scale chromatin interactions (Yadav et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

Multi-omic dissection of ancestral heat stress memory responses inBrachypodium distachyon

Zheng

Tan

Lim

et al. 2023

Preprint

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Stressful environmental conditions, including heat stress (HS), are a major limiting factor in crop yield. Understanding the molecular mechanisms of plant stress memory and resilience is important for engineering more resistant plants and improving crop yield. To study how the different gene regulatory layers change upon repeated HS and how these layers are interconnected, we performed a dense temporal atlas of gene expression, alternative splicing, small and long noncoding RNAs, and DNA methylation inBrachypodium distachyon. Results show that a second HS induces changes in coding and noncoding RNA expression and alternative splicing and that DNA demethylation is responsible for mediating differential gene expression. We identified a long noncoding RNA regulatory network and provided evidence that lncRNAs positively regulate gene expression, while miRNAs are implicated in alternative splicing events. We reconstructed the ancestral heat memory network of flowering plants by comparing the dynamic responses ofArabidopsis thalianaandBrachypodium distachyon. These findings enhance our understanding of the complex inter-layer cross-talk governing HS resilience and memory and identify novel genes essential for these processes.

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Stress Conditions Modulate the Chromatin Interactions Network in Arabidopsis

Cited by 5 publications

References 64 publications

High-resolution Hi-C maps highlight multiscale chromatin architecture reorganization during cold stress in Brachypodium distachyon

High-resolution Hi-C maps highlight multiscale chromatin architecture reorganization during cold stress in Brachypodium distachyon

Three dimensions of thermolabile sex determination

Multi-omic dissection of ancestral heat stress memory responses inBrachypodium distachyon

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