ZmmiR1432‐ ZmCML21 ‐ ZmPMA2 Module Affects Maize Low Phosphate Tolerance via Regulating Organic Acid Secretion
Laming Pei, Yaqing Yang, Zhe Wang, Wencheng Duan, Ning Liu, Zhaohua Ding, Hui Li

TL;DR
This study identifies a genetic module in maize that helps plants tolerate low phosphorus by regulating organic acid secretion, offering new targets for improving phosphorus use efficiency in crops.
Contribution
The study reveals a novel ZmmiR1432-ZmCML21-ZmPMA2 regulatory module involved in maize's low phosphorus tolerance.
Findings
Suppression of ZmmiR1432 improves low Pi tolerance through enhanced organic acid exudation.
ZmCML21 interacts with ZmPMA2 to influence organic acid secretion and Pi use efficiency.
Overexpression of ZmCML21 disrupts organic acid secretion and alters TCA cycle gene expression.
Abstract
Phosphorus is indispensable in agricultural production. The growing global demand for food necessitates the development of crops with enhanced phosphorus utilisation efficiency. However, the molecular mechanisms coordinating phosphorus utilisation efficiency in plants remain incompletely characterised. MicroRNAs, pivotal regulators of plant developmental and physiological processes, have emerged as key targets for deciphering the regulatory networks underlying low phosphate (Pi) tolerance. Herein, we delineate the regulatory role of ZmmiR1432 in maize and elucidate its mechanistic basis in conferring low Pi tolerance. Suppression of ZmmiR1432 markedly improved tolerance to Pi deficiency via enhanced organic acid exudation, whereas its overexpression had the opposite effect. It is also indicated that ZmmiR1432 regulates low Pi tolerance through direct modulation of its target gene,…
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Taxonomy
TopicsPlant nutrient uptake and metabolism · Plant Micronutrient Interactions and Effects · Plant Molecular Biology Research
