Abstract
Brassinosteroids (BRs) are essential plant growth- and development-regulating phytohormones. When applied exogenously, BRs ameliorate heat shock (HS)-induced cell damage and enhance plant thermotolerance; however, the molecular mechanism by which BRs regulate plant thermotolerance is unknown. In this study, by analyzing the thermotolerance of a series of BR signaling mutants and plants that overexpressed different BR signaling components, we obtained comprehensive data showing that BRASSINOSTEROID INSENSITIVE 2 (BIN2) plays a major role in mediating the crosstalk between BR signaling and plant HS responses. By RNA-Seq, 608 HS- and BIN2-regulated genes were identified. An analysis of the 1-kb promoter sequences of these genes showed enrichment of an abscisic acid (ABA) INSENSITIVE 5 (ABI5)-binding cis-element. Physiological studies showed that thermotolerance was reduced in bin2-1 mutant and ABI5-OX plants but increased in the abi5 mutant, and that the abi5 mutation could recover the thermotolerance of bin2-1 plants to a wild-type level, suggesting that ABI5 functions downstream of BIN2 in regulating plant thermotolerance. Further, HS treatment increased the cellular abundance of BIN2. Both bin2-1 mutant and BIN2-OX plants showed early flowering, while the BIN2 loss-of-function mutant bin2-3 bil1 bil2 flowered late. Given these findings, we propose that under HS conditions plants increase BIN2 activity to promote early flowering and ensure species survival; however, this reduces the thermotolerance and survivability of individual plants partially by activating ABI5.
Highlights
With the increasing impact of the greenhouse effect, it is estimated that the global surface temperature has increased by approximately 1.09◦C compared with that observed in the preindustrial era1
By sequentially examining the thermotolerance of different BR signaling mutants and plants overexpressing major BR signaling components, we obtained comprehensive genetic evidence showing that BRASSINOSTEROID INSENSITIVE 2 (BIN2) mediates the crosstalk between BR signaling and plant heat shock (HS) responses
Several lines of evidence from our study suggest that HS can increase cellular BIN2 activity
Summary
With the increasing impact of the greenhouse effect, it is estimated that the global surface temperature has increased by approximately 1.09◦C compared with that observed in the preindustrial era. The appearance of seasonally extreme heat has become increasingly frequent. This makes heat stress one of the most important environmental factors limiting plant growth and productivity. Heat stress has a deleterious influence on almost every aspect of plant growth and development; it can change the thylakoid structure in chloroplasts, inactivate Rubisco, reduce the number of photosynthetic pigments, and destroy photosystem II to quickly inhibit photosynthesis (Danilova et al, 2018; Dogra et al, 2019; Hu et al, 2020). Uncovering the mechanism by which plants respond to heat stress and using that knowledge to promote the breeding of heat stress-tolerant crops will protect future global agricultural productivity
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