An H3K27me3 demethylase-HSFA2 regulatory loop orchestrates transgenerational thermomemory in Arabidopsis

Liu, Junzhong; Li, Feng; Gu, Xueting; Deng, Xian; Qiu, Qi; Li, Qun; Zhang, Yingying; Wang, Muyang; Deng, Yiwen; Wang, Ertao; He, Yuqing; Bäurle, Isabel; Li, Jianming; Cao, Xiaofeng; He, Zhonghu

doi:10.1038/s41422-019-0145-8

Cited by 166 publications

(161 citation statements)

References 51 publications

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“…miR319 is upregulated and TCP family genes are downregulated during HS (Hivrale et al 2016). ta-siRNAs also affect flowering time regulation (Liu et al 2019) (see later). In summary, the spectrum of sRNAome fine-tunes stress response both through positive and negative activities in order to mitigate the detrimental impact of heat and successfully accomplish reproduction.…”

Section: Role Of Srnas In Acquired Thermotolerance and Heat Stress Mementioning

confidence: 92%

“…Besides HSFA2, a growing number of stress memory factors have been discovered (Brzezinka et al 2018;Charng et al 2006;Lin et al 2014;Liu et al 2018;Meiri and Breiman 2009). Thermomemory was shown to be transmitted transgenerationally (Liu et al 2019). Micro RNAs (miRNA) and small interfering RNAs (siRNA) are intimately involved in high-temperature stress response and thermomemory.…”

Section: Regulation Of Hsrmentioning

confidence: 99%

“…Moderate heat stress (30°C) induces the epigenetic release of RNA silencing through inhibition of ta-siRNA biogenesis (Zhong et al 2013). It was shown recently that this pathway requires the activity of HSFA2, REF6, and SGIP1 (Liu et al 2019). HSFA2 transcriptionally activates RELATIVE OF EARLY FLOWERING 6 (REF6), an H3K27-demethylase gene (Lu et al 2011).…”

Section: Srnas Are Required For Trans-generational Stress Memorymentioning

confidence: 99%

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Regulation of High-Temperature Stress Response by Small RNAs

Szaker

Gyula

Szittya

et al. 2020

Concepts and Strategies in Plant Sciences

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Temperature extremes constitute one of the most common environmental stresses that adversely affect the growth and development of plants. Transcriptional regulation of temperature stress responses, particularly involving protein-coding gene networks, has been intensively studied in recent years. High-throughput sequencing technologies enabled the detection of a great number of small RNAs that have been found to change during and following temperature stress. The precise molecular action of some of these has been elucidated in detail. In the present chapter, we summarize the current understanding of small RNA-mediated modulation of hightemperature stress-regulatory pathways including basal stress responses, acclimation, and thermo-memory. We gather evidence that suggests that small RNA network changes, involving multiple upregulated and downregulated small RNAs, balance the trade-off between growth/development and stress responses, in order to ensure successful adaptation. We highlight specific characteristics of small RNA-based temperature stress regulation in crop plants. Finally, we explore the perspectives of the use of small RNAs in breeding to improve stress tolerance, which may be relevant for agriculture in the near future.

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Section: Role Of Srnas In Acquired Thermotolerance and Heat Stress Mementioning

confidence: 92%

Section: Regulation Of Hsrmentioning

confidence: 99%

Section: Srnas Are Required For Trans-generational Stress Memorymentioning

confidence: 99%

See 1 more Smart Citation

Regulation of High-Temperature Stress Response by Small RNAs

Szaker

Gyula

Szittya

et al. 2020

Concepts and Strategies in Plant Sciences

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“…These lasting epigenetic modifications include DNA methylation, histone methylation and histone acetylation and can alter the RNA expression, chromatin accessibility and splicing that occurs proximal to these markings [ 1 , 2 , 3 ]. Additionally, these markings can be transmitted between mitotic and sometimes meiotic cell divisions [ 4 , 5 ] allowing developmental and environmental cues to leave a lasting impact on a cell lineage, altering the development of cells in later life history stages or even in the next generation.…”

Section: Introductionmentioning

confidence: 99%

“…Meiotic transmission of epigenetic markings resulting from environmental cues provides a mechanism through which plastic responses to the environment can be transmitted from one generation to the next (transgenerational plasticity [ 6 ]). While plant germline cells do undergo a number of rounds of epigenetic reprogramming prior to the formation of a new seed [ 7 ], it is clear that environmental conditions experienced by parents can alter phenotypes [ 8 , 9 , 10 , 11 ], epigenetic profiles [ 4 , 10 , 12 , 13 ] and gene expression [ 14 , 15 , 16 ] in the next generation. Importantly, autocorrelation between offspring and parent environment can favor mechanisms that establish such patterns of transgenerational plasticity [ 17 , 18 ], perhaps leading to natural selection that either favors or disfavors this transmission depending on local environmental patterns [ 11 ].…”

Section: Introductionmentioning

confidence: 99%

Mimulus sRNAs Are Wound Responsive and Associated with Transgenerationally Plastic Genes but Rarely Both

Colicchio

Kelly

Hileman

2020

IJMS

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Organisms alter development in response to environmental cues. Recent studies demonstrate that they can transmit this plasticity to progeny. While the phenotypic and transcriptomic evidence for this “transgenerational plasticity” has accumulated, genetic and developmental mechanisms remain unclear. Plant defenses, gene expression and DNA methylation are modified as an outcome of parental wounding in Mimulus guttatus. Here, we sequenced M. guttatus small RNAs (sRNA) to test their possible role in mediating transgenerational plasticity. We sequenced sRNA populations of leaf-wounded and control plants at 1 h and 72 h after damage and from progeny of wounded and control parents. This allowed us to test three components of an a priori model of sRNA mediated transgenerational plasticity—(1) A subset of sRNAs will be differentially expressed in response to wounding, (2) these will be associated with previously identified differentially expressed genes and differentially methylated regions and (3) changes in sRNA abundance in wounded plants will be predictive of sRNA abundance, DNA methylation, and/or gene expression shifts in the following generation. Supporting (1) and (2), we found significantly different sRNA abundances in wounded leaves; the majority were associated with tRNA fragments (tRFs) rather than small-interfering RNAs (siRNA). However, siRNAs responding to leaf wounding point to Jasmonic Acid mediated responses in this system. We found that different sRNA classes were associated with regions of the genome previously found to be differentially expressed or methylated in progeny of wounded plants. Evidence for (3) was mixed. We found that non-dicer sRNAs with increased abundance in response to wounding tended to be nearby genes with decreased expression in the next generation. Counter to expectations, we did not find that siRNA responses to wounding were associated with gene expression or methylation changes in the next generation and within plant and transgenerational sRNA plasticity were negatively correlated.

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The Role of Histone Modifications in Heat Signal Transduction in Plants

2023

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Global warming and the more frequent occurrence of extremly high temperatures seriously affect crop yields. Heat stress (HS) has become a major environmental factor threatening food security worldwide. Understanding how plants sense and respond to HS is of clear interest to plant scientists and crop breeders. However, it is not trivial to elucidate the underlying signaling cascade, as specific cellular responses (ranging from detrimental to systemic effects) must be disentangled. Plants respond and adapt to high temperatures in many ways. In this review, recent progress in understanding heat signal transduction and the role of histone modifications in regulating the expression of genes involved in HS responses are discussed. The outstanding issues that are crucial for understanding the interactions between plants and HS are also discussed. The study of heat signal transduction mechanisms in plants is essential to facilitate the cultivation of heat‐resistant crop varieties.

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An H3K27me3 demethylase-HSFA2 regulatory loop orchestrates transgenerational thermomemory in Arabidopsis

Cited by 166 publications

References 51 publications

Regulation of High-Temperature Stress Response by Small RNAs

Regulation of High-Temperature Stress Response by Small RNAs

Mimulus sRNAs Are Wound Responsive and Associated with Transgenerationally Plastic Genes but Rarely Both

The Role of Histone Modifications in Heat Signal Transduction in Plants

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