ZmSnRK2.10‐mediated phosphorylation of ZmDNL1 attenuates ZmYAB15 activity to enhance drought resilience in maize

ABSTRACT Drought stress represents a critical challenge to global agriculture, severely compromising plant growth and crop productivity through its disruption of intracellular signaling networks, with particular emphasis on protein kinase‐mediated pathways and transcriptional regulation. In this study, we identified and characterized ZmDNL1 as a novel transcriptional regulator that serves as a negative modulator of drought tolerance in maize. Through comprehensive biochemical analyses, we demonstrated that ZmDNL1 physically interacts with ZmYAB15, a known negative regulator of drought tolerance, and potentiates its transcriptional regulatory activity. Most significantly, our investigation revealed that ZmSnRK2.10‐mediated phosphorylation of three specific N‐terminal residues in ZmDNL1 effectively attenuates ZmYAB15's transcriptional activity while maintaining the structural integrity of the ZmDNL1‐ZmYAB15 protein complex, ultimately enhancing drought tolerance. These findings elucidate a previously unrecognized regulatory mechanism in which ZmSnRK2.10 orchestrates drought tolerance through phosphorylation‐dependent fine tuning of the ZmDNL1–ZmYAB15 transcriptional regulatory module. Beyond advancing our fundamental understanding of drought response mechanisms in maize, this study provides valuable molecular targets for precision breeding strategies aimed at developing drought‐resilient crop varieties.