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ZmCIPK33 and ZmSnRK2.10 mutually reinforce the abscisic acid signaling pathway for combating drought stress in maize

Shan Jiang, Zhihui Sun, Zhenkai Feng, Yuanpeng Qi, Hui Chen, Yu Wang, Junsheng Qi, Yan Guo, Shuhua Yang, Zhizhong Gong

2025Journal of Integrative Plant Biology12 citationsDOI

Abstract

The calcineurin B-like protein (CBL)-CBL-interacting protein kinase (CIPK) Ca²⁺ sensors play crucial roles in the plant's response to drought stress. However, there have been few reports on the synergistic regulation of drought stress by CBL-CIPK and abscisic acid (ABA) core signaling components. In this study, we discovered that ZmCIPK33 positively regulates drought resistance in maize. ZmCIPK33 physically interacts with and is enhanced by phosphorylation from ZmSnRK2.10. Drought stress can activate ZmCIPK33, which is partially dependent on ZmSnRK2.10. ZmCIPK33 in combination with ZmSnRK2.10 can activate the slow anion channel ZmSLAC1 in Xenopus laevis oocytes independently of CBLs, whereas ZmCIPK33 or ZmSnRK2.10 alone is unable to do so. Furthermore, ZmCIPK33 phosphorylates ZmPP2C11 at Ser60, which leads to a reduction in the interaction between ZmPP2C11 and ZmEAR1 (the ortholog of Arabidopsis Enhancer of ABA co-Receptor 1) and weakens the phosphatase activity of ZmPP2C11, consequently, enhancing the activity of ZmSnRK2.10 in an in vitro assay and in the in-gel assay of the zmcipk33 mutant. Our findings provide novel insights into the molecular mechanisms underlying the reciprocal enhancement of Ca²⁺ and ABA signaling under drought stress in maize.

Topics & Concepts

Abscisic acidXenopusPhosphatasePhosphorylationArabidopsisMutantCell biologyBiologySignal transductionPsychological repressionArabidopsis thalianaBiochemistryGeneGene expressionPlant Stress Responses and TolerancePlant nutrient uptake and metabolismPlant Molecular Biology Research
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