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Ethylene increases the <scp>NaHCO<sub>3</sub></scp> stress tolerance of grapevines partially via the <scp>VvERF1B</scp>‐<scp>VvMYC2</scp>‐<scp>VvPMA10</scp> pathway

Guangqing Xiang, Zongbao Fan, Shuxia Lan, Dezheng Wei, Yazhe Gao, Hui Kang, Yuxin Yao

2025Plant Biotechnology Journal15 citationsDOIOpen Access PDF

Abstract

Summary Here, we evaluated the role of ethylene in regulating the NaHCO 3 stress tolerance of grapevines and clarified the mechanism by which VvERF1B regulates the response to NaHCO 3 stress. The exogenous application of ACC and VvACS3 overexpression in grapevines and grape calli revealed that ethylene increased NaHCO 3 stress tolerance, and this was accompanied by increased plasma membrane H + ‐ATPase (PMA) activity. The expression of VvERF1B was strongly induced by ACC, and overexpression of this gene in grapevines conferred increased NaHCO 3 stress tolerance and enhanced PMA activity and H + and oxalate secretion. Additionally, the function of VvERF1B was also verified using mutant transgenic grape calli and overexpression in Arabidopsis plants. The expression of VvPMA10 was strongly induced following the overexpression of VvERF1B in grapevine roots, and VvPMA10 was shown to regulate PMA activity, oxalate and H + secretion, and NaHCO 3 stress tolerance via its overexpression and mutation in grapevine roots, calli, and/or Arabidopsis . However, VvPMA10 was not a direct target gene of VvERF1B but was directly transactivated by VvMYC2. The function of VvMYC2 was shown to be similar to that of VvPMA10 via its overexpression and mutation in grape calli. Additional experiments revealed that the interaction of VvERF1B with VvMYC2 increased its ability to activate VvPMA10 expression and that VvMYC2 played a role in the VvERF1B‐mediated pathway. Overall, the VvERF1B‐VvMYC2‐VvPMA pathway played a role in regulating ethylene‐induced NaHCO 3 stress tolerance in grapevines, and this process contributed to increases in PMA activity and H + and oxalate secretion.

Topics & Concepts

MutantArabidopsisEthyleneBiologySecretionCell biologyOxalateGene expressionTransgeneGeneFunction (biology)BiochemistryChemistryCatalysisOrganic chemistryPostharvest Quality and Shelf Life ManagementPlant Stress Responses and TolerancePlant responses to water stress
Ethylene increases the <scp>NaHCO<sub>3</sub></scp> stress tolerance of grapevines partially via the <scp>VvERF1B</scp>‐<scp>VvMYC2</scp>‐<scp>VvPMA10</scp> pathway | Litcius