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LIczbiński P, Bukowska B. 2022. Tea and coffee polyphenols and their biological properties based on the latest in vitro investigations. Industrial Crops and Products 175:114265

You JM, Cao XZ. 2013. Analysis on the distribution of tea polyphenol in tea tree by Folin-Ciocalteaut Method. Hubei Agricultural Sciences 52(10):2417−19

Jiang X, Liu Y, Li W, Zhao L, Meng F, et al. 2013. Tissue-specific, development-dependent phenolic compounds accumulation profile and gene expression pattern in tea plant [ Camellia sinensis]. PLoS One 8:e62315

Li L, Wang M, Pokharel SS, Li C, Parajulee MN, et al. 2019. Effects of elevated CO₂ on foliar soluble nutrients and functional components of tea, and population dynamics of tea aphid, Toxoptera aurantii. Plant Physiology and Biochemistry 145:84−94

Deng WW, Ashihara H. 2015. Occurrence and de novo biosynthesis of caffeine and theanine in seedlings of tea ( Camellia sinensis). Natural Product Communications 10:703−6

Lu Z, Liu Y, Zhao L, Jiang X, Li M, et al. 2014. Effect of low-intensity white light mediated de-etiolation on the biosynthesis of polyphenols in tea seedlings. Plant Physiology and Biochemistry 80:328−36

Xiang P, Zhu Q, Tukhvatshin M, Cheng B, Tan M, et al. 2021. Light control of catechin accumulation is mediated by photosynthetic capacity in tea plant ( Camellia sinensis). BMC Plant Biology 21:478

Tan X, Li H, Zhang Z, Yang Y, Jin Z, et al. 2023. Characterization of the Difference between Day and Night Temperatures on the Growth, Photosynthesis, and Metabolite Accumulation of Tea Seedlings. International Journal of Molecular Sciences 24:6718

Rong ZY, Lei AQ, Wu QS, Srivastava AK, Hashem A, et al. 2023. Serendipita indica promotes P acquisition and growth in tea seedlings under P deficit conditions by increasing cytokinins and indoleacetic acid and phosphate transporter gene expression. Frontiers in Plant Science 14:1146182

Zhang H, Li C, Wei K, Liu M, Shi Y, et al. 2023. The reduction of tea quality caused by irrational phosphate application is associated with anthocyanin metabolism. Beverage Plant Research 3:10

Takeuchi A, Matsumoto S, Hayatsu M. 1994. Chalcone synthase from Camellia sinensis: isolation of the cDNAs and the organ-specific and sugar-responsive expression of the genes. Plant And Cell Physiology 35:1011−18

Rani A, Singh K, Ahuja PS, Kumar S. 2012. Molecular regulation of catechins biosynthesis in tea [ Camellia sinensis (L) O. Kuntze]. Gene 495:205−10

Singh K, Rani A, Kumar S, Sood P, Mahajan M, et al. 2008. An early gene of the flavonoid pathway, flavanone 3-hydroxylase, exhibits a positive relationship with the concentration of catechins in tea ( Camellia sinensis). Tree Physiology 28:1349−56

Liu M, Li X, Liu Y, Cao B. 2013. Regulation of flavanone 3-hydroxylase gene involved in the flavonoid biosynthesis pathway in response to UV-B radiation and drought stress in the desert plant, Reaumuria soongorica. Plant Physiology and Biochemistry 73:161−67

Liu Y, Qian J, Li J, Xing M, Grierson D, et al. 2022. Hydroxylation decoration patterns of flavonoids in horticultural crops: chemistry, bioactivity and biosynthesis. Horticulture Research 9:uhab068

Zhou TS, Yu YB, Xiao B, Bao L, Gao YF. 2017. Engineering of a flavonoid 3'-hydroxylase from tea plant ( Camellia sinensis) for biosynthesis of B-3',4'-dihydroxylated flavones. Acta Microbiologica Sinica 57:447−58

Zhou TS, Zhou R, Yu YB, Xiao Y, Li DH, et al. 2016. Cloning and characterization of a flavonoid 3'-hydroxylase gene from tea plant ( Camellia sinensis). International Journal of Molecular Sciences 17:261

Schwinn K, Miosic S, Davies K, Thill J, Gotame TP, et al. 2014. The B-ring hydroxylation pattern of anthocyanins can be determined through activity of the flavonoid 3'-hydroxylase on leucoanthocyanidins. Planta 240:1003−10

Wang W, Zhou Y, Wu Y, Dai X, Liu Y, et al. 2018. Insight into Catechins Metabolic Pathways of Camellia sinensis Based on Genome and Transcriptome Analysis. Journal of Agricultural and Food Chemistry 66:4281−93

Wang YS, Xu YJ, Gao LP, Yu O, Wang XZ, et al. 2014. Functional analysis of flavonoid 3',5'-hydroxylase from tea plant ( Camellia sinensis): critical role in the accumulation of catechins. BMC Plant Biology 14:347

Jin JQ, Ma JQ, Yao MZ, Ma CL, Chen L. 2017. Functional natural allelic variants of flavonoid 3', 5'-hydroxylase gene governing catechin traits in tea plant and its relatives. Planta 245:523−38

Jiang X, Shi Y, Fu Z, Li WW, Lai S, et al. 2020. Functional characterization of three flavonol synthase genes from Camellia sinensis: Roles in flavonol accumulation. Plant Science 300:110632

Owens DK, Alerding AB, Crosby KC, Bandara AB, Westwood JH, et al. 2008. Functional analysis of a predicted flavonol synthase gene family in Arabidopsis. Plant Physiology 147:1046−61

Wang P, Zhang L, Zhao L, Zhang X, Zhang H, et al. 2020. Comprehensive analysis of metabolic fluxes from leucoanthocyanins to anthocyanins and proanthocyanidins (PAs). Journal of Agricultural and Food Chemistry 68:15142−53

Wang X, Guo L, Gao L, Shi X, Zhao X, et al. 2018. Molecular evidence for catechin synthesis and accumulation in tea buds ( Camellia sinensis). Journal of Agricultural and Food Chemistry 66:63−69

Luo P, Ning G, Wang Z, Shen Y, Jin H, et al. 2016. Disequilibrium of flavonol synthase and dihydroflavonol-4-reductase expression associated tightly to white vs red color flower formation in plants. Frontiers in Plant Sciences 6:1257

Li H, Tian J, Yao YY, Zhang J, Song TT, et al. 2019. Identification of leucoanthocyanidin reductase and anthocyanidin reductase genes involved in proanthocyanidin biosynthesis in Malus crabapple plants. Plant Physiology and Biochemistry 139:141−51

Wang P, Liu Y, Zhang L, Wang W, Hou H, et al. 2020. Functional demonstration of plant flavonoid carbocations proposed to be involved in the biosynthesis of proanthocyanidins. The Plant Journal 101:18−36

Jun JH, Lu N, Docampo-Palacios M, Wang X, Dixon RA. 2021. Dual activity of anthocyanidin reductase supports the dominant plant proanthocyanidin extension unit pathway. Science Advances 7:eabg4682

Yao S, Liu Y, Zhuang J, Zhao Y, Dai X, et al. 2022. Insights into acylation mechanisms: co-expression of serine carboxypeptidase-like acyltransferases and their non-catalytic companion paralogs. The Plant Journal 111:117−33

Ying C, Chen J, Chen J, Zheng P, Zhou C, et al. 2023. Differential accumulation mechanisms of purine alkaloids and catechins in Camellia ptilophylla, a natural theobromine-rich tea. Beverage Plant Research 3:15

Fu Z, Jiang X, Kong D, Chen Y, Zhuang J, et al. 2022. Flavonol-aluminum complex formation: enhancing aluminum accumulation in tea plants. Journal of Agricultural and Food Chemistry 70:14096−108

Jiang X, Shi Y, Dai X, Zhuang J, Fu Z, et al. 2018. Four flavonoid glycosyltransferases present in tea overexpressed in model plants Arabidopsis thaliana and Nicotiana tabacum for functional identification. Journal of Chromatography B: Analytical Technologies in the Biomedical and Life Sciences 1100-1101:148−57

Shan Y, Li W, Wang Y, Liu Y, Wang H, et al. 2011. Study on the changes of catechin synthesis and accumulation during the development of tea seedlings. Journal of Anhui Agricultural University 38:600−05

Jiang X, Liu Y, Wu Y, Tan H, Meng F, et al. 2015. Analysis of accumulation patterns and preliminary study on the condensation mechanism of proanthocyanidins in the tea plant [ Camellia sinensis]. Scientific Reports 5:8742

Qian Y, Zhang S, Yao S, Xia J, Li Y, et al. 2018. Effects of vitro sucrose on quality components of tea plants ( Camellia sinensis) based on transcriptomic and metabolic analysis. BMC Plant Biology 18:121

Wu Y, Jiang X, Zhang S, Dai X, Liu Y, et al. 2016. Quantification of flavonol glycosides in Camellia sinensis by MRM mode of UPLC-QQQ-MS/MS. Journal of Chromatography B 1017−1018:10−17

Guo L, Gao L, Ma X, Guo F, Ruan H, et al. 2019. Functional analysis of flavonoid 3'-hydroxylase and flavonoid 3',5'-hydroxylases from tea plant ( Camellia sinensis), involved in the B-ring hydroxylation of flavonoids. Gene 717:144046

Tanner GJ, Francki KT, Abrahams S, Watson JM, Larkin PJ, Ashton AR. 2003. Proanthocyanidin biosynthesis in plants: purification of legume leucoanthocyanidin reductase and molecular cloning of its cDNA. Journal of Biological Chemistry 278:31647−56

Xie DY, Sharma SB, Dixon RA. 2004. Anthocyanidin reductases from Medicago truncatula and Arabidopsis thaliana. Archives of Biochemistry and Biophysics 422:91−102

Wang P, Zhang L, Jiang X, Dai X, Xu L, et al. 2018. Evolutionary and functional characterization of leucoanthocyanidin reductases from Camellia sinensis. Planta 247:139−54

Zhao Y, Yao S, Zhang X, Wang Z, Jiang C, et al. 2023. Flavan-3-ol galloylation-related functional gene cluster and the functional diversification of SCPL paralogs in Camellia sp. Journal of Agricultural and Food Chemistry 71:488−98