Microrna164D Suppresses the Hvnac92-Hvhkt1;5 Module to Enhance Salinity Tolerance in Barley

Author(s)

Liuhui Kuang
Hongxing Zhou
Tongtong Zhang
Fei Gao
Tao Yan
Zhong-Hua Chen
Qiufang Shen
Guoping Zhang
Lin Li
Dezhi Wu, University of South CarolinaFollow

Document Type

Article

Subject Area(s)

Hordeum (genetics, metabolism, physiology); MicroRNAs (genetics, metabolism); Salt Tolerance (genetics); Plant Proteins (genetics, metabolism); Gene Expression Regulation, Plant; Sodium (metabolism); Plant Roots (genetics, metabolism); Potassium (metabolism); Cation Transport Proteins (genetics, metabolism); Symporters (genetics, metabolism); Plant Shoots (metabolism, genetics)

Abstract

Cereal crops (e.g., rice, wheat, maize, and barley) constituted the major component of global human diet and fundamentally changed human society since the dawn of agriculture around 12,000 y ago. Originated and domesticated in different continents and environments, cereal crops vary significantly in their salt tolerance. The High-Affinity K Transporter1;5s (HKT1;5s) predominately regulate Na accumulation and salt tolerance in salt-sensitive cereal crops by mediating shoot-to-root Na exclusion. However, HvHKT1;5 paradoxically promotes root-to-shoot Na translocation in salt-tolerant barley. Therefore, unravelling the regulatory mechanisms of HvHKT1;5 is critical to understanding the molecular basis of salt tolerance in barley. Here, we demonstrated that a microRNA164d-HvNAC92-HvHKT1;5 module improves salt tolerance via reduced shoot Na accumulation and increased K retention in barley, whereas miR164d suppresses HvNAC92 transcription factor to directly downregulate HvHKT1;5 expression. Under salinity condition, the MIR164d-OE, Hvnac92, and Hvhkt1;5 lines showed significantly reduced root-to-shoot Na translocation and shoot Na content compared with the wild-type. In conclusion, we resolve the species-specific function of HKT1;5s in cereal crops by establishing miRNA-guided Na and K transport regulation as a regulatory framework for engineering salt-tolerant crops.

Digital Object Identifier (DOI)

https://doi.org/10.1073/pnas.2514555122

Publication Info

Published in Proceedings of the National Academy of Sciences of the United States of America, Volume 122, Issue 52, 2025, pages e2514555122-.

APA Citation

Kuang, L., Zhou, H., Zhang, T., Gao, F., Yan, T., Chen, Z.-H., Shen, Q., Zhang, G., Li, L., & Wu, D. (2025). MicroRNA164d suppresses the HvNAC92-HvHKT1;5 module to enhance salinity tolerance in barley. Proceedings of the National Academy of Sciences, 122(52),e2514555122.https://doi.org/10.1073/pnas.2514555122

Rights

© 2025 the Author(s). Published by PNAS. This article is distributed under Creative Commons Attribution-NonCommercial-NoDerivatives License 4.0 (CC BY-NC-ND).