HvPHR1 as a key gene in maintaining phosphate homeostasis in barley

Wenhao Yue; Xue Xia; Fangying Ge; Kangfeng Cai; Lei Liu; Yong Li; Chengdao Li; Junmei Wang

doi:10.1016/j.stress.2026.101220

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HvPHR1 as a key gene in maintaining phosphate homeostasis in barley

Journal article

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HvPHR1 as a key gene in maintaining phosphate homeostasis in barley

Wenhao Yue, Xue Xia, Fangying Ge, Kangfeng Cai, Lei Liu, Yong Li, Chengdao Li and Junmei Wang

Plant stress (Amsterdam), Vol.19, 101220

2026

DOI: https://doi.org/10.1016/j.stress.2026.101220

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Abstract

Barley

Domestication

Phosphate starvation signaling

Transcription factor

Phosphorus is an essential macronutrient for all living organisms. Although it is abundant in the Earth’s crust, inorganic phosphate (Pi)—accessible to plants—is often limited due to the soil’s physicochemical properties. To cope with Pi scarcity, plants have evolved a complex phosphate starvation response network centered around phosphate starvation response proteins (PHRs) to regulate cellular Pi homeostasis. However, a comprehensive understanding of physiological and molecular functions of PHRs in barley (Hordeum vulgare) remains elusive. In this study, we identified two homologous PHRs in barley, with HvPHR1 exhibiting higher expression across all developmental stages, suggesting a dominant role. Overexpression of HvPHR1 resulted in necrotic symptoms in mature leaf tips, which correlated with excessive Pi accumulation in leaves. Transcriptome analysis revealed 732 and 307 significantly differentially expressed genes in the roots and leaves, respectively, in the HvPHR1-overexpressing transgenic line grown under Pi-sufficient conditions. These genes were primarily associated with phosphate starvation responses and phosphate ion homeostasis. Using published exome resequencing data, we identified 12 SNPs in the CDS, introns, and 3’ UTR of HvPHR1, which were classified into four main haplotypes. Allele frequency analysis revealed that HvPHR1 underwent artificial selection during barley domestication. Furthermore, the nonsynonymous mutation of HvPHR1 did not affect its nuclear localization or transcriptional activation activity. These findings enhance our understanding of the vital role of HvPHR1 in maintaining Pi homeostasis in barley. [Display omitted]

Details

Title: HvPHR1 as a key gene in maintaining phosphate homeostasis in barley
Authors/Creators: Wenhao Yue - Hangzhou Academy of Agricultural Sciences
Xue Xia - Hangzhou Academy of Agricultural Sciences
Fangying Ge - Hangzhou Academy of Agricultural Sciences
Kangfeng Cai - Hangzhou Academy of Agricultural Sciences
Lei Liu - Hangzhou Academy of Agricultural Sciences
Yong Li - Hangzhou Academy of Agricultural Sciences
Chengdao Li - Murdoch University, Centre for Crop and Food Innovation
Junmei Wang - ZheJiang Academy of Agricultural Sciences
Publication Details: Plant stress (Amsterdam), Vol.19, 101220
Publisher: Elsevier B.V.
Number of pages: 11
Identifiers: 991005852086907891
Murdoch Affiliation: Western Crop Genetics Alliance; Centre for Crop and Food Innovation
Language: English
Resource Type: Journal article

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