Soil alkalinity and heavy metal toxicity are major abiotic stresses that severely limit plant growth and crop productivity. Wild soybean (Glycine soja) exhibits strong alkaline tolerance, making it a valuable genetic resource for improving cultivated soybean. Previous studies identified Gshdz4 and GsNAC019 as key alkaline-tolerant transcription factors, and GsEXPA8 as an alkaline-tolerant expansin protein. This study establishes a hierarchical "nucleus-nucleus-membrane" regulatory model in wild soybean, wherein the nuclear master transcription factor Gshdz4 transcriptionally upregulates GsNAC019, which in turn activates the expression of the plasma membrane-localized expansin GsEXPA8, collectively enhancing alkaline tolerance. We further investigated the role of Gshdz4 in conferring resistance to combined sodium bicarbonate and cadmium chloride stress in soybean. Through integrated RNA-seq and CUT under cadmium stress, it regulates GmGMFL01 and GmUNC, establishing a broad-spectrum defense mechanism. Additional targets encompass splicing factors, heat shock proteins, ABA signaling components, and ethylene-responsive factors. GO and KEGG enrichment analyses confirmed that Gshdz4 participates in multiple hormonal pathways (ABA, IAA, ET, JA) and stress response signaling. Our findings revealed Gshdz4 as a master transcriptional regulator under multiple stresses and provide a theoretical foundation for molecular breeding strategies to enhance soybean resilience.
Liu et al. (Thu,) studied this question.
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