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Functional study of NtWRKY6 in response to ABA expression and regulation of polyphenol synthesis

Zhan Ge-Rui1,2,Yu Wen3,Li Feng1,Wu Ming-Zhu1,Xu Xin1,Luo Zhao-Peng1,Wu Sheng-Xin3,Yang Jun1,Zhang Zhi-Qiang2,*,Wang Zhong1,*   

  1. 1 Zhengzhou Tobacco Research Institute of China National Tobacco Corporation, Zhengzhou 450001, Henan, China; 2 College of Tobacco Science, Henan Agricultural University, Zhengzhou 450046, Henan, China; 3 Tobacco Science Research Institute of Fujian Tobacco Monopoly Bureau, Fuzhou 350003, Fujian, China
  • Published:2025-11-12
  • Contact: 张智强, E-mail: xiao_qiang8866@163.com; 王中, E-mail: zhongwang1123@126.com E-mail:zhandamei2023@163.com
  • Supported by:
    This study was supported by the Project of Fujian Tobacco Monopoly Bureau of China National Tobacco Corporation (2025350000240087).

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Abstract: The transcription factor WRKY6 is known to regulate seed germination and seedling growth in plants; . However, its role in polyphenol biosynthesis has not yet been reported. To investigate the biological function of tobacco WRKY6, the NtWRKY6 gene was identified from the Nicotiana tabacum genome. Sequence alignment and phylogenetic analysis revealed that NtWRKY6 contains a typical WRKY domain and belongs to the Group II subfamily. NtWRKY6 was highly expressed in tobacco flowers and capsules, and its transcription was significantly induced by several plant hormones, including ABA, BL, and JA. Overexpression of NtWRKY6 significantly enhanced the resistance of tobacco seedlings to ABA treatment. In three independent NtWRKY6-overexpressing (OE) lines, polyphenol content in leaves and roots increased by 18.54%–77.15% and 39.72%–64.07%, respectively, compared to wild-type (WT) plants. In contrast, ntwrky6 mutants were more sensitive to ABA treatment, and polyphenol content in their leaves and roots decreased by 25.05%–30.67% and 19.85%–25.06%, respectively, relative to WT plants. Furthermore, the expression levels of multiple genes involved in polyphenol synthesis were significantly upregulated in NtWRKY6-OE seedlings, while they were significantly downregulated in ntwrky6 mutants. These results indicate that NtWRKY6 plays a role in regulating ABA signal transduction and polyphenol biosynthesis, providing a potential target gene for improving tobacco quality.

Key words: tobacco, NtWRKY6, abscisic acid, polyphenol, gene expression

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