茶树特异种质资源高EGCG3′′Me性状形成的分子机制解析

doi:10.13305/j.cnki.jts.2025.06.005

Abstract

Abstract: Methylated catechins exhibit significant physiological activities, such as anti-allergy effects, and demonstrate stronger stability and higher oral absorption rate than unmethylated catechins. However, tea germplasms rich in methylated catechins are relatively rare. This study measured the EGCG3′′Me content in 447 tea germplasms from different regions with extensive genetic backgrounds, and two unique tea germplasms with high EGCG3′′Me content, namely ‘Jinxiu 2-2’ (JX) and ‘Pinming Tea’ (PM), were found. The tea germplasms JX, PM, and ‘Hongfugui’ (BFK) with high EGCG3′′Me content, as well as ‘Shuchazao’ (SCZ) with EGCG3′′Me content below the detection limit, were used as research materials. Relative expression levels of flavonol and anthocyanin O-methyltransferase (CsFAOMT1) in JX, PM, and BFK were significantly higher than that in SCZ. Further analysis reveals that four types of CsFAOMT1 alleles were cloned from the four tea germplasms, and all of them contain CsFAOMT1.3. Enzyme activity analysis at the protein level reveals that the CsFAOMT1 protein activities in the three tea germplasms with high EGCG3′′Me content all exhibit high activity with minimal differences between them. These results indicate that JX and PM can enrich EGCG3′′Me due to their high expression levels of CsFAOMT1. This study identified tea germplasm with high EGCG3′′Me content and elucidated the molecular mechanisms underlying its unique traits, providing important materials and theoretical basis for breeding new tea cultivars with high methylated catechin content.

Key words: tea plant, methylated catechins, O-methyltransferase, allele

CLC Number:

S571.1
S324

LI Yuanyuan, YAO Mingzhe, JIN Jiqiang. Elucidation of the Molecular Mechanisms Underlying the Formation of the High EGCG3′′Me Content in Tea Germplasms[J]. Journal of Tea Science, 2025, 45(6): 909-919.

References

[1] Pan S Y, Nie Q, Tai H C, et al.Tea and tea drinking: China's outstanding contributions to the mankind[J]. Chinese Medicine, 2022, 17(1): 27. doi: 10.1186/s13020-022-00571-1.
[2] 张梁, 陈琪, 宛晓春, 等. 中国茶叶生物化学研究40年[J]. 中国茶叶, 2019, 41(9): 1-10.
Zhang L, Chen Q, Wan X C, et al.Forty years of research on the biochemistry of Chinese tea[J]. China Tea, 2019, 41(9): 1-10.
[3] Sazuka M, Imazawa H, Shoji Y, et al.Inhibition of collagenases from mouse lung carcinoma cells by green tea catechins and black tea theaflavins[J]. Bioscience, Biotechnology, and Biochemistry, 1997, 61(9): 1504-1506.
[4] Lee S R, Im K J, Suh S I, et al.Protective effect of green tea polyphenol (-)-epigallocatechin gallate and other antioxidants on lipid peroxidation in gerbil brain homogenates[J]. Phytotherapy Research, 2003, 17(3): 206-209.
[5] Dai W Z, Ruan C C, Zhang Y M, et al.Bioavailability enhancement of EGCG by structural modification and nano-delivery: a review[J]. Journal of Functional Foods, 2020, 65: 103732. doi: 10.1016/j.jff.2019.103732.
[6] Saijo R.Isolation and chemical structures of two new catechins from fresh tea leaf[J]. Agricultural and Biological Chemistry, 1982, 46(7): 1969-1970.
[7] Chiu F L, Lin J K.HPLC analysis of naturally occurring methylated catechins, 3′′-and 4′′-methyl-epigallocatechin gallate, in various fresh tea leaves and commercial teas and their potent inhibitory effects on inducible nitric oxide synthase in macrophages[J]. Journal of Agricultural and Food Chemistry, 2005, 53(18): 7035-7042.
[8] Zhang M, Zhang X, Ho C T, et al.Chemistry and health effect of tea polyphenol (-)-epigallocatechin 3-O-(3-O-methyl) gallate[J]. Journal of Agricultural and Food Chemistry, 2019, 67(19): 5374-5378.
[9] Yang G Z, Meng Q, Shi J, et al.Special tea products featuring functional components: health benefits and processing strategies[J]. Comprehensive Reviews in Food Science and Food Safety, 2023, 22(3): 1686-1721.
[10] 山本万里, 佐野満昭, 立花宏文. 緑茶の抗アレルギー・がん転移抑制因子[J]. 化学と生物, 2003, 41(7): 442-447.
[11] Oritani Y, Setoguchi Y, Ito R, et al.Comparison of (-)-epigallocatechin-3-O-gallate (EGCG) and O-methyl EGCG bioavailability in rats[J]. Biological & Pharmaceutical Bulletin, 2013, 36(10): 1577-1582.
[12] Maeda-Yamamoto M, Ema K, Monobe M, et al.The efficacy of early treatment of seasonal allergic rhinitis with benifuuki green tea containing O-methylated catechin before pollen exposure: an open randomized study[J]. Allergology International, 2009, 58(3): 437-444.
[13] Kurita I, Maeda-Yamamoto M, Tachibana H, et al.Antihypertensive effect of Benifuuki tea containing O-methylated EGCG[J]. Journal of Agricultural and Food Chemistry, 2010, 58(3): 1903-1908.
[14] Maeda-Yamamoto M, Sano M, Matsuda N, et al.The change of epigallocatechin-3-O-(3-O-methyl) gallate content in tea of different varieties, tea seasons of crop and processing method[J]. Nippon Shokuhin Kagaku Kogaku Kaishi, 2001, 48(1): 64-68.
[15] 汪毅. 茶叶中甲基化EGCG的调查研究[D]. 重庆: 西南大学, 2006.
Wang Y.Studies on O-methylated epigallocatechin-3-O-gallate in tea [D]. Chongqing: Southwest University, 2006.
[16] 罗正飞, 龚正礼, 汪毅, 等. 茶叶中甲基化EGCG的研究[J]. 西南大学学报(自然科学版), 2008(3): 56-59.
Luo Z F, Gong Z L, Wang Y, et al.Research on methylated EGCG in tea[J]. Journal of Southwest University (Natural Science Edition), 2008(3): 56-59.
[17] Lee S C, Yan R H, Cheng H Y, et al.Screen and genetic assessment of tea germplasms with elevated methylated catechin, (-)-epigallocatechin-3-O-(3-O-methyl) gallate[J]. Journal of Agricultural and Food Chemistry, 2009, 57(19): 8906-8912.
[18] Ibrahim R K, Bruneau A, Bantignies B.Plant O-methyltransferases: molecular analysis, common signature and classification[J]. Plant Molecular Biology, 1998, 36(1): 1-10.
[19] Jin J Q, Qu F R, Huang H, et al.Characterization of two O-methyltransferases involved in the biosynthesis of O-methylated catechins in tea plant[J]. Nature Communications, 2023, 14(1): 5075. doi: 10.1038/s41467-023-40868-9.
[20] 刘庆帅, 璩馥榕, 魏梦园, 等. 基于UPLC技术解析金萱×紫娟F₁分离群体代谢物的遗传变异[J]. 茶叶科学, 2022, 42(1): 29-40.
Liu Q S, Qu F R, Wei M Y, et al.The genetic variation of the chemical components of the ‘Jinxuan’ × ‘Zijuan’ F₁ segregating population based on UPLC[J]. Journal of Tea Science, 2022, 42(1): 29-40.
[21] 璩馥榕. 茶树高甲基化儿茶素性状形成的遗传基础初探及分子标记开发[D]. 北京: 中国农业科学院, 2023.
Qu F R.A preliminary investigation of the genetic basis for the formation of hypermethylated catechin traits in tea plants and the development of molecular markers [D]. Beijing: Chinese Academy of Agricultural Sciences, 2023.
[22] 刘庆帅. 茶树富含EGCG3′′Me的分子机制解析[D]. 北京: 中国农业科学院, 2022.
Liu Q S.Molecular mechanism analysis for tea plant rich in EGCG3′′Me [D]. Beijing: Chinese Academy of Agricultural Sciences, 2022.
[23] Lü H P, Yang T, Ma C Y, et al.Analysis of naturally occurring 3′′-methyl-epigallocatechin gallate in 71 major tea cultivars grown in China and its processing characteristics[J]. Journal of Functional Foods, 2014, 7: 727-736. doi: 10.1016/j.jff.2013.12.009.
[24] 唐娜, 刘仲华, 李银花. 湖南地区高含量甲基化EGCG茶树资源的调查[J]. 农产品加工(创新版), 2010(5): 36-38.
Tang N, Liu Z H, Li Y H.Survey of tea plant resources with high content of methylated EGCG in Hunan area[J]. Agricultural Product Processing (Innovation Edition), 2010(5): 36-38.
[25] 李建华, 齐桂年, 陈盛相, 等. 四川茶树品种资源中EGCG3′′Me研究[J]. 食品工业科技, 2015, 36(16): 108-113.
Li J H, Qi G N, Chen S X, et al.Analysis of 3′′-methly-epigallocatechin gallate in Sichuan tea varieties resources[J]. Science and Technology of Food Industry, 2015, 36(16): 108-113.
[26] 卢嘉丽, 王冬梅, 苗爱清, 等. 白叶单枞和黄观音茶树芽叶中茶多酚的HPLC-DAD/MS/MS分析[J]. 中国药学杂志, 2007(19): 1456-1459.
Lu J L, Wang D M, Miao A Q, et al.HPLC-DAD/MS/MS analysis of tea polyphenols in leaves of Baiyedancong and Huangguanyin[J]. Chinese Pharmaceutical Journal, 2007(19): 1456-1459.
[27] 卢秋华, 陈志雄, 彭建肯, 等. 高甲基化儿茶素乌龙茶品种的筛选初探[J]. 厦门科技, 2018(6): 46-48.
Lu Q H, Chen Z X, Peng J K, et al.Initial exploration of screening for oolong tea varieties with high levels of methylated catechins[J]. Xiamen Science and Technology, 2018(6): 46-48.
[28] Jin J Q, Jiang C K, Yao M Z, et al.Baiyacha, a wild tea plant naturally occurring high contents of theacrine and 3′′-methyl-epigallocatechin gallate from Fujian, China[J]. Scientific Reports, 2020, 10: 9715. doi: 10.1038/s41598-020-66808-x.
[29] Jin J Q, Dai W D, Zhang C Y, et al.Genetic, morphological, and chemical discrepancies between Camellia sinensis (L.) O. Kuntze and its close relatives[J]. Journal of Food Composition and Analysis, 2022, 108: 104417. doi: 10.1016/j.jfca.2022.104417.

Elucidation of the Molecular Mechanisms Underlying the Formation of the High EGCG3′′Me Content in Tea Germplasms

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Metrics

Comments

Recommended 0

[1]	SHEN Yingzi, LI Duojiao, HU Xingrong, JIANG Li, ZHENG Zhaisheng, LIU Huikang, YUAN Ming′an. Cloning of the CsPDAT1 Gene from Camellia sinensis and Its Role in Drought Tolerance [J]. Journal of Tea Science, 2025, 45(6): 920-930.
[2]	LU Li, SHI Yin, WANG Yanxia, HUANG Xiaozhen. Comparative Analysis of Seed Biological Characteristics and Endophytic Bacterial Diversity among Different Individual Plants of Ancient Tea Plants (Camellia sinensis) in Tongzi, Guizhou [J]. Journal of Tea Science, 2025, 45(6): 943-956.
[3]	CHEN Jiaming, GUO Yang, GU Dachuan, LI Jianlong, CHEN Yiyong, HUANG Yanfeng, TANG Jinchi, YANG Ziyin. Screening of Mechanical Harvestable Traits of Tea Cultivars [J]. Journal of Tea Science, 2025, 45(6): 1006-1020.
[4]	JIANG Li, LI Duojiao, HU Xinrong, SHEN Yingzi, ZHENG Zhaisheng, WENG Xiaoxing, LIU Shujing, BIAN Xiaodong, YUAN Ming'an, CHEN Xuan. Effects of Different Cultivation Patterns on Physiological and Biochemcial Characteristics of New Shoots in Seed-Leaf Dual-Purpose Tea Plants [J]. Journal of Tea Science, 2025, 45(5): 783-794.
[5]	WANG Kairong, ZHANG Longjie, LIANG Yuerong, LI Xiaoxiang, ZHENG Xinqiang. Identification and Classification of Tea Leaf Color and Establishment of A Tea Leaf Color System [J]. Journal of Tea Science, 2025, 45(5): 795-807.
[6]	ZHOU Yide, CHEN Jialin, WU Junmei, ZHAO Hongbo, SUN Binmei, LIU Shaoqun, ZHENG Peng. Nitrogen Metabolism Genes in Tea Plant: Research Progress on the Environmental Stress Adaptation Mechanism and Breeding Application [J]. Journal of Tea Science, 2025, 45(4): 545-558.
[7]	SUN Mengzhen, HU Zhihang, YANG Kaixin, ZHANG Jiaqi, ZHANG Nan, XIONG Aisheng, LIU Hui, ZHUANG Jing. Identification of Circadian Clock CsLUX Gene and Its Effects on Photosynthetic Characteristics in Tea Plants [J]. Journal of Tea Science, 2025, 45(4): 559-570.
[8]	ZHAI Xiuming, LI Jie, XIAO Fuliang, TANG Min, ZENG Lewu, HOU Yujia, TANG Yi. WGCNA Analysis of Differentially Expressed Genes between Parallel Variation and Normal Tea Stems and Leaves [J]. Journal of Tea Science, 2025, 45(3): 402-414.
[9]	ZHANG Hui, LIU Fengjing, LI Huiling, LI Liangde, WANG Qingsen, WANG Dingfeng. Metabolomics Analysis of Different Resistant Tea Cultivars Infected by Acaphylla theae in The Early Stage [J]. Journal of Tea Science, 2025, 45(3): 415-426.
[10]	GUO Jialu, QU Furong, CAI Tianchen, ZHAO Yang, YANG Peidi, LIU Yong, ZHOU Yuebin, LIU Zhen. Study on the Genetic Diversity of 78 Tea Germplasm Resources in Hunan Based on Agronomic Traits and SNP Molecular Markers [J]. Journal of Tea Science, 2025, 45(2): 219-233.
[11]	HUANG Fuyin, ZHANG Shaobo, HU Qiang, LUO Ying, DONG Yajie, ZHANG Jie, LI Xin, FU Jianyu, WANG Huasen, YAN Peng. The Impacts and Regulatory Mechanisms of Forest Conversion to Tea Plantations and Their Management on Soil Carbon and Nitrogen Pools [J]. Journal of Tea Science, 2025, 45(2): 234-252.
[12]	LI Yuexin, YAN Donghai, ZHANG Jinfeng, PU Yundan, LI Shuai, MENG Zehong. Identification of the L-type Lectin Receptor Kinase Gene Family in Camellia sinensis and Its Response to Tea Brown Blight and Tea Anthracnose [J]. Journal of Tea Science, 2025, 45(2): 253-265.
[13]	DONG Yuan, ZHANG Yongheng, XIAO Yezi, YU Youben. Cloning of BZR1 Gene Family in Tea Plants and Molecular Mechanism Study of CsBZR1-5 Response to Drought Stress [J]. Journal of Tea Science, 2025, 45(1): 15-28.
[14]	YANG Nan, LI Zhuan, LIU Meichen, MA Junjie, SHI Yuntao, WEI Xiangning, LIN Yangshun, MAO Yuyuan, GAO Shuilian. Studies on the Regulation of EGCG Biosynthesis in Tea Plants by Potassium Nutrition [J]. Journal of Tea Science, 2024, 44(6): 887-900.
[15]	ZHAO Qian, LIU Qian, CAI-HE Jiayi, HE Jieqi, FANG Yunya, LIU Yuxin, CHEN Chao, ZHENG Yaodong, ZHANG Tianjing, YU Wenjuan, YANG Guang. Effects of Combined Drought and Low-temperature Stress on Photosynthetic Physiological Characteristics of Tea Plants and Simulation Prediction [J]. Journal of Tea Science, 2024, 44(6): 901-916.