CsGDH2.1 Negatively Regulates Theanine Accumulation in Late-spring Tea Plants ( Var. )

Overview

Journal Hortic Res

Publisher Oxford University Press

Date 2023 Jan 16

PMID 36643747

Authors

Tingting Chen

Jingzhen Ma

Huiping Li

Shijia Lin

Chunxia Dong

Yunxia Xie

Xiaomei Yan

Shupei Zhang

Tianyuan Yang

Xiaochun Wan

Zhaoliang Zhang

Affiliations

Soon will be listed here.

Abstract

Theanine, a unique and the most abundant non-proteinogenic amino acid in tea plants, endows tea infusion with the umami taste and anti-stress effects. Its content in tea correlates highly with green tea quality. Theanine content in new shoots of tea plants is high in mid-spring and greatly decreases in late spring. However, how the decrease is regulated is largely unknown. In a genetic screening, we observed that a yeast mutant, (), was hypersensitive to 40 mM theanine and accumulated more theanine. This result implied a role of CsGDH2s in theanine accumulation in tea plants. Therefore, we identified the two homologs of GDH2, CsGDH2.1 and CsGDH2.2, in tea plants. Yeast complementation assay showed that the expression of in yeast mutant rescued the theanine hypersensitivity and hyperaccumulation of this mutant. Subcellular localization and tissue-specific expression showed CsGDH2.1 localized in the mitochondria and highly expressed in young tissues. Importantly, expression was low in early spring, and increased significantly in late spring, in the new shoots of tea plants. These results all support the idea that CsGDH2.1 regulates theanine accumulation in the new shoots. Moreover, the enzyme assay showed that CsGDH2.1 had glutamate catabolic activity, and knockdown of expression increased glutamate and theanine accumulation in the new shoots of tea plants. These findings suggested that CsGDH2.1-mediated glutamate catabolism negatively regulates theanine accumulation in the new shoots in late spring, and provides a functional gene for improving late-spring green tea quality.

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