A Review of Differential Plant Responses to Drought, Heat, and Combined Drought + Heat Stress
Ning Li, Zhi Geng, Xiaodong Huang, Shunqi Huang, Lulu Song, Ruirui Chen, Ziping Chen, Longmeng Du, Congshan Xu
Abstract
Global warming increases the frequency with which drought and heat stress occur simultaneously, especially in semi-arid regions. Such combined stress imposes a non-additive and more severe impact on plant growth, yield, and quality than either stress alone. Here, we integrate recent physiological, biochemical, and multi-omics studies to compare individual and combined stress responses and to dissect the underlying signal transduction networks. We show that drought-dominated phases rapidly elevate ABA concentrations and activate SnRK2-AREB cascades, whereas heat pulses trigger jasmonic acid and ethylene signals that antagonize ABA-driven stomatal closure. Under combined stress, these hormonal modules converge on a "competitive TF marketplace", where ABA, JA, and GA cis-elements co-regulate invertase-sugar checkpoints, heat shock factor/ROS oscillators, and chromatin-remodeling events that determine reproductive fate. Recent advances using multi-omics approaches and systems biology have further elucidated these complex networks. These insights will inform future breeding strategies aiming to develop stress-tolerant crops. We highlight emerging tools-weighted gene co-expression networks, kinetic multi-omics, and cis-regulatory CRISPR editing-that can exploit these signaling hubs for breeding crops with improved combined stress tolerance.