Identification and distribution of a single nucleotide polymorphism responsible for the catechin content in tea plants

Jiang, Chenkai; Ma, Jianqiang; Liu, Yu-Fei; Chen, Jie-Dan; Ni, Dejiang; Chen, Liang

doi:10.1038/s41438-020-0247-y

Cited by 31 publications

(14 citation statements)

References 42 publications

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“…Zhang et al combined RNA sequencing results for 176 resources and data regarding the levels of catechin components in a correlation analysis, which revealed that CsANR, CsF3′5′H, and CsMYB5 may influence catechin levels 12 . These studies involving natural populations examined the linkage disequilibrium between marker genes to correlate phenotypic traits with genotypes and detect marker gene loci closely related to the phenotype of interest 13 , 14 . Unlike QTL mapping, this method does not require the construction of a genetic map, there are no significant differences in the parental genotypes when QTLs are mapped, and multiple allelic variations in the same locus can be detected simultaneously.…”

Section: Introductionmentioning

confidence: 99%

Genome-wide association analysis identified molecular markers associated with important tea flavor-related metabolites

Fang

Xia

et al. 2021

Hortic Res

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The characteristic secondary metabolites in tea (theanine, caffeine, and catechins) are important factors contributing to unique tea flavors. However, there has been relatively little research on molecular markers related to these metabolites. Thus, we conducted a genome-wide association analysis of the levels of these tea flavor-related metabolites in three seasons. The theanine, caffeine, and catechin levels in Population 1 comprising 191 tea plant germplasms were examined, which revealed that their heritability exceeded 0.5 in the analyzed seasons, with the following rank order (highest to lowest heritabilities): (+)-catechin > (−)-gallocatechin gallate > caffeine = (−)-epicatechin > (−)-epigallocatechin-3-gallate > theanine > (−)-epigallocatechin > (−)-epicatechin-3-gallate > catechin gallate > (+)-gallocatechin. The SNPs detected by amplified-fragment SNP and methylation sequencing divided Population 1 into three groups and seven subgroups. An association analysis yielded 307 SNP markers related to theanine, caffeine, and catechins that were common to all three seasons. Some of the markers were pleiotropic. The functional annotation of 180 key genes at the SNP loci revealed that FLS, UGT, MYB, and WD40 domain-containing proteins, as well as ATP-binding cassette transporters, may be important for catechin synthesis. KEGG and GO analyses indicated that these genes are associated with metabolic pathways and secondary metabolite biosynthesis. Moreover, in Population 2 (98 tea plant germplasm resources), 30 candidate SNPs were verified, including 17 SNPs that were significantly or extremely significantly associated with specific metabolite levels. These results will provide a foundation for future research on important flavor-related metabolites and may help accelerate the breeding of new tea varieties.

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Section: Introductionmentioning

confidence: 99%

Genome-wide association analysis identified molecular markers associated with important tea flavor-related metabolites

Fang

Xia

et al. 2021

Hortic Res

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“…The molecular mechanisms underlying tea flavor have been widely explored 11 , 12 . The metabolic pathways and accumulation mechanisms of catechins, caffeine, and theanine, the main secondary metabolites in tea, have been studied thoroughly 11 .…”

Section: Introductionmentioning

confidence: 99%

An ancient whole-genome duplication event and its contribution to flavor compounds in the tea plant (Camellia sinensis)

Wang

Chen

et al. 2021

Hortic Res

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Tea, coffee, and cocoa are the three most popular nonalcoholic beverages in the world and have extremely high economic and cultural value. The genomes of four tea plant varieties have recently been sequenced, but there is some debate regarding the characterization of a whole-genome duplication (WGD) event in tea plants. Whether the WGD in the tea plant is shared with other plants in order Ericales and how it contributed to tea plant evolution remained unanswered. Here we re-analyzed the tea plant genome and provided evidence that tea experienced only WGD event after the core-eudicot whole-genome triplication (WGT) event. This WGD was shared by the Polemonioids-Primuloids-Core Ericales (PPC) sections, encompassing at least 17 families in the order Ericales. In addition, our study identified eight pairs of duplicated genes in the catechins biosynthesis pathway, four pairs of duplicated genes in the theanine biosynthesis pathway, and one pair of genes in the caffeine biosynthesis pathway, which were expanded and retained following this WGD. Nearly all these gene pairs were expressed in tea plants, implying the contribution of the WGD. This study shows that in addition to the role of the recent tandem gene duplication in the accumulation of tea flavor-related genes, the WGD may have been another main factor driving the evolution of tea flavor.

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“…Following its domestication, the tea plant underwent intensive cycles of further breeding and selection in order to improve its capacity to withstand biotic and abiotic stresses, as well as to enhance its organoleptic attributes such as aroma, taste, color, and texture (32,54). For instance, recent transcriptomic and genomic analyses suggest that metabolic pathways in tea plants (particularly flavonoid biosynthetic pathways) underwent strong selection during the domestication process (50,55,56). Similarly, flavor and stress (biotic and abiotic) tolerance are among the main traits that were selected for during tea domestication or improvement processes (57).…”

Section: Domestication History Of Teamentioning

confidence: 99%

“…We argue that as CSA spread northwards within China, and later to Korea and Japan, cold tolerance became a necessary trait for survival, thus persistent selection for this attribute eventually produced CSS. This idea is reinforced by the fact that CSA has a relatively higher catechin content (56,59), a phenotype that was recently associated with a primitive genotype predominantly found at the center of tea origin in Yunnan (55). Further insights on the precise genetic mechanism underlying tea domestication can be obtained using genome-wide association studies (GWAS) on a world-wide collection of tea accessions alongside Camellia wild species, as recently applied in clarifying the domestication history of castor bean (60).…”

Section: Domestication History Of Teamentioning

confidence: 99%

From the Wild to the Cup: Tracking Footprints of the Tea Species in Time and Space

et al. 2021

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Tea is one of the world's most popular beverages, known for its cultural significance and numerous health benefits. A clear understanding of the origin and history of domestication of the tea species is a fundamental pre-requisite for effective germplasm conservation and improvement. Though there is a general consensus about the center of origin of the tea plant, the evolutionary origin and expansion history of the species remain shrouded in controversy, with studies often reporting conflicting findings. This mini review provides a concise summary of the current state of knowledge regarding the origin, domestication, and dissemination of the species around the world. We note that tea was domesticated around 3000 B.C. either from non-tea wild relatives (probably Camellia grandibracteata and/or C. leptophylla) or intra-specifically from the wild Camellia sinensis var. assamica trees, and that the genetic origins of the various tea varieties may need further inquiry. Moreover, we found that lineage divergence within the tea family was apparently largely driven by a combination of orogenic, climatic, and human-related forces, a fact that could have important implications for conservation of the contemporary tea germplasm. Finally, we demonstrate the robustness of an integrative approach involving linguistics, historical records, and genetics to identify the center of origin of the tea species, and to infer its history of expansion. Throughout the review, we identify areas of debate, and highlight potential research gaps, which lay a foundation for future explorations of the topic.

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Identification and distribution of a single nucleotide polymorphism responsible for the catechin content in tea plants

Cited by 31 publications

References 42 publications

Genome-wide association analysis identified molecular markers associated with important tea flavor-related metabolites

Genome-wide association analysis identified molecular markers associated with important tea flavor-related metabolites

An ancient whole-genome duplication event and its contribution to flavor compounds in the tea plant (Camellia sinensis)

From the Wild to the Cup: Tracking Footprints of the Tea Species in Time and Space

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