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Omics Technologies Applied to Agriculture and Food

The impact of six typical processing methods on the chemical composition of tea leaves using a single Camellia sinensis cultivar, Longjing 43 Yijun Wang, Zhipeng Kan, Henry J. Thompson, Tie-Jun Ling, Chi-Tang Ho, Daxiang Li, and Xiaochun Wan J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.8b05140 • Publication Date (Web): 07 Nov 2018 Downloaded from http://pubs.acs.org on November 7, 2018

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Journal of Agricultural and Food Chemistry

The impact of six typical processing methods on the chemical composition of tea leaves using a single Camellia sinensis cultivar, Longjing 43 Yijun Wang†,‡#, Zhipeng Kan†,‡#, Henry J. Thompson‡, §, Tiejun Ling†,‡, Chi-Tang Ho‡,≠, Daxiang Li†,‡* and Xiaochun Wan†,‡* †

State Key Laboratory of Tea Plant Biology and Utilization, School of Tea and Food

Science & Technology, Anhui Agricultural University, Hefei, Anhui 230036, PRC. ‡

International Joint Laboratory on Tea Chemistry and Health Effects, Anhui

Agricultural University, Hefei, Anhui 230036, PRC. §

Cancer Prevention Laboratory, Colorado State University, Fort Collins, CO 80523, USA. ≠

Department of Food Science, Rutgers University, New Brunswick, NJ 08901, USA

#

These authors contribute equally.

*

Corresponding author: Dr. Daxiang Li ([email protected]) and Dr. Xiaochun Wan

([email protected]), Tel/Fax: +86 551 6578 6765.

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ABSTRACT

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While Camellia sinensis cultivar and processing method are key factors that affect tea

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flavor and aroma, the chemical changes in nonvolatile components associated with tea

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processing method using a single cultivar of C. sinensis has not been reported. Fresh

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leaves from C. sinensis, Longjing 43 were subjected to six tea processing methods and

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evaluated by targeted and untargeted chromatographic procedures. Based on targeted

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assessment of total catechin content, three clusters were identified: yellow-green,

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oolong-white-dark, and black. However, principal component analysis of the total tea

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metabolome identified four chemical phenotypes: green-yellow, oolong, black-white,

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and dark. Differences in the non-catechin components included amino acids and

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gamma

12

dihydroxyphenylalanine, valine, betaine, theophylline which increased in dark tea.

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Overall, this study identified a wide range of chemicals that are affected by commonly

14

used tea processing methods and that potentially affect the bioactivity of various tea

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types.

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Key words: C. sinensis, tea, bioactives, post-harvest processing, chemical

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composition

aminobutyric

acid

which

were

increased

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INTRODUCTION

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Tea is a popular beverage, second only to water in terms of per capita consumption.1

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There are many types of tea that differ in aroma and flavor. They are produced via

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variations in the way harvested leaves are processed. In China, there are six postharvest

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processes to which leaves of Camellia sinensis are commonly subjected (Figure 1).

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Processing results in leaves that are used to produce: green, yellow, oolong, black,

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white, and dark tea. These processing techniques were developed over a span of

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thousands of years in different parts of China. When comparative analyses have been

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done, the six tea types are generally classified into five categories, the first four of

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which are clustered by the degree of endogenous enzymatic reaction: 1) non-fermented

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teas: green tea; 2) lightly fermented tea: yellow tea and white tea; 3) partially fermented

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tea: oolong tea; 4) fully-fermented tea: black tea; and 5) post-fermented tea: dark tea in

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which the exogenous microbial fermentation plays a vital role in processing.2,3

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The beverage referred to as tea is the hot water infusion of the leaves of C. sinensis that

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are subjected to a specific post-harvest processing technique. The aroma and taste

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characteristics of each tea type are based on the metabolite changes induced in the tea

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leaf, primarily the nonvolatile components, retained in the leaf until it is infused. As

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such, the tea science field has focused on processing-induced changes in the types of

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catechins present in the leaf since they compromise over 20% its dry weight.4 The tea

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catechins include: catechin (C), gallocatechin (GC), epicatechin (EC), epicatechin

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gallate (ECG), epigallocatechin (EGC), and epigallocatechin gallate (EGCG), the

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most abundant secondary metabolites in the fresh leaves of C. sinenesis. In most of tea 3

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research, the chemical changes induced by all six typical processing methods are

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viewed through the lens of how those processes either prevent or allow catechins to be

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oxidized by endogenous polyphenol oxidases.5-7 Although many other chemicals, e.g.,

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theanine and caffeine were successively discovered in tea leaves in the past decades,8,9

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the comprehensive chemical profiling of teas is still limited. Despite the fact that the

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fresh picked leaves of the large number of commercially important cultivars of differ

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significantly in phytochemical content,10,11 and that specific cultivars are generally used

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to make specific tea types,12 most work has ignored the potential contributions of the

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cultivar used to make a tea type in comparing the chemical differences that exist among

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tea types.

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Mass-based metabolomics is the use of high throughput analysis platforms to

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chromatographically separate complex mixtures of small molecules with their

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subsequent identification via mass spectrometry. When this approach is applied to a

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biological material such as the tea leaf, it enables the detection of hundreds of

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endogenous metabolites simultaneously, providing an ―unbiased‖ view of the global

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metabolome.13 Several recent studies applied either targeted or untargeted

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metabolomics approaches to investigate the seasonal, geographical or genetic impact

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on chemical composition of the tea plant leaf. Using this approach (LC-MS) coupled

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with multivariate statistical analysis, the complexity and variability of a broad range of

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metabolites in tea leaves has been unveiled.14-16

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As discussed above, the post-harvest processing method is a key factor that governs the

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chemical composition of the leaf which is ultimately extracted via hot water to make tea. 4

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Although several analytical studies have been done to investigate certain major

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metabolites in commercial teas or in intermediate steps during post-harvest processing,

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a comprehensive investigation using metabolomics approaches has yet to be

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conducted.17 In the work that has been reported, commercial teas were made from

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diverse tea plant sources, which is a limitation to developing an in-depth understanding

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of how specific processing techniques affect chemical composition, without

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confounding due to chemical differences in fresh picked leaves from different C.

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sinensis cultivars. Besides genetic factors, the environmental factors, plucking time and

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criteria might play a role as well. Longjing 43 is one of the most widely cultivated

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varieties in China, with the characteristics of strong drought resistance and high

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budding rate. The Xihulongjing tea (green tea), made from Longjing 43, is one of the

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top famous teas in China.18 In order to eliminate those confusing issue, the study

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reported herein used fresh plucked leaves from a single popular tea plant cultivar

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Longjing 43, followed by typical processing methods to make six tea types. The fresh

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leaves and six types of processed leaves were analyzed and compared by targeted

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methods using HPLC and global metabolomics approaches with validation of candidate

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compounds using authentic standards and/or advanced in silico procedures.

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MATERIALS AND METHODS

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Chemicals

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Deionized water was produced by a Milli-Q water purification system (Millipore,

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Billerica, MA, USA). Methanol and acetonitrile of LC–MS grade was purchased from

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Thermo Fisher (Thermo Scientific, Waltham, MA, USA). C, GC, EC, ECG, EGC, 5

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EGCG, gallic acid, caffeine, theophylline, theobromine and theanine were obtained

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from Yuanye Bio-Technology Co., Ltd. (Shanghai, China). DL-4-Chlorophenylalanine

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was obtained from MedChemExpress (Shanghai, China).

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Sample Preparation

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Fresh leaves of C. sinensis L., Longjing 43 were plucked from NO. 916 tea garden in

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Shucheng, Anhui, China. All the fresh leaves were divided into seven equal portions,

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six of them were processed into six types of teas by using typical manufacturing

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approaches (Figure 1). Briefly, three portions of the fresh leaves were first fixed at

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220 ℃ to terminate the endogenous enzymatic reaction then rolled for 30 min, then

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one of the three was directly dried into green tea. The second portion was yellowed at

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room temperature and 70% humidity till the color of the leaves turned yellow (～6-8

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hours), then dried into yellow tea. The third portion was post fermented at room

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temperature and 70% humidity for 48 h and then dried into dark tea. To make black tea

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and oolong tea, two portions of fresh leaves were withered at room temperature and 70%

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humidity for 5h, one of them was rolled for 30min, applied heat-moisture treatment at

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room temperature and 90% humidity for 3h and immediately dried into black tea. The

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other portion was shaken and bruised four times, after fixed at 220 ℃ and rolling for

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30 minutes, the leaves were dried into oolong tea. The sixth portion of fresh leaves

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was subjected to ventilation withering at room temperature for 48h before dried into

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white tea. The last portion of fresh leaves was lyophilized and all samples were stored

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at -80 ℃ prior until analysis.

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Sensory Evaluation 6

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Tea types were evaluated by eight professional tea taster from the State Key Laboratory

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of Tea Plant Biology and Utilization in accordance with Chinese National Standard

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methods. The samples were blind-coded with random numbers. Three g of tea leaves

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were infused with 150 mL of boiled purified water in separated white porcelain cups

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and maintained for 5 min. Then, the tea infusion was poured into a white porcelain bowl

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to evaluate the color, aroma, taste, and the residue (Figure 2). Post-infusion, extracted

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leaves were transferred to white porcelain plates to observe their integrity and

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appearance. Dried tea samples were also evaluated for color, shape, cleanliness and

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uniformity. The panel provided a report of their sensory evaluation.

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Sample Extraction

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HPLC

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Post-harvest processed leaves were ground into a powder. Then 2.5 mL of a 70%

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methanol solution (v/v) was added to 0.1 g of tea powder at 70 °C for 10 min to extract

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metabolites. The supernatants were collected after centrifuging at 3000 g for 10 min.

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The sediments were re-extracted twice using the same method. After treatment, all the

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extracts were brought to a constant volume (5 mL) and then filtered using a 0.22 μm

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filter for HPLC analysis.

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LC-MS

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The freeze-dried fresh leaves and the six tea products were ground into powder. 50mg

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sample and 0.8mL methanol were mixed with 60 Hz ultrasonication at 25 ℃ for 20

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min. The supernatants were collected after centrifuging at 12000 g, 4 ℃. The internal

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standard DL-4-chlorophenylalanine was added with final concentration of 5mg/L. Six 7

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replicates were prepared and stored at -80 ℃ until they were analyzed.

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HPLC Analysis of Major Secondary Metabolites

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The high performance liquid chromatography (HPLC) system consisted of a Waters

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2695 controller and a Waters 2489 UV Detector and a reverse phase C18 column

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(250×4.60 mm, granule diameter, 5 m, Phenomenex Inc., Torrance, CA, USA). Mobile

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phase A: water with 0.17% (v/v) acetic acid. Mobile phase B: 100% acetonitrile. Linear

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elution was as follows: B from 6% from 0 to 4 min, to 14% at 16 min, to 15% at 22 min,

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to 18% at 32 min, to 29% at 37 min, to 45% at 45 min, to 45% at 50 min, to 6% at 51

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min and to 6% at 60 min.19 Samples (10 μL) were eluted at 1 mL/min, the column

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heater was kept at 25 ℃. The detection wavelength was 278nm.The amounts of

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polyphenol compounds in tea samples were measured by comparing the peak area of

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each catechin in the tea samples with those of standards. Empower

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used for data collection, integration, and analysis.

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LC-MS Analysis

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UPLC (Ultimate 3000, Dionex, Sunnyvale, CA, USA) coupled with Orbitrap Elite™

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Hybrid Ion Trap-Orbitrap Mass Spectrometer (Thermo Fisher Scientific, USA) was

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employed. The separation of all samples was performed on an Ultimate 3000 with

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Hyper Gold column (1.9 μm, 2.1x100 mm). Water with 0.1% (v/v) formic acid and

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acetonitrile were used as mobile phase A and B, respectively, for chromatographic

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elution: from 0 to 7 min, phase B was linearly increased from 5 to 80%, then linearly

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increased to 95% at 11 min, and maintained for 4 min; phase B was adjusted to 8% at

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15.5 min for re-equilibration and maintained for 4 min. The total elapsed time required 8

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for a given chromatographic analysis was thus 20 min. The flow rate was set at 0.30

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mL/min. The injection volume was 4 μL. The mass spectrometer was operated in both

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positive and negative modes with HESI spray voltage of 3.8 kV and 3.2 kV respectively,

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sheath gas pressure of 35 arb, auxiliary gas pressure of 10 arb, capillary temperature of

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350 ℃, and full scan MS mode with resolution 60,000 and scan range 50-1000 (m/z).

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Data Processing

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The raw data acquired from the LC-MS was initially processed by the Thermo SIEVE

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2.1 Qualitative Analysis Software (Thermo Scientific, USA) to generate a peak table

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that included information on retention time, mass-to-charge ratio (m/z), and MS

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intensity of the features. The retention time tolerance and mass tolerance for the peak

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alignment was set to 0.2 min and 0.01 Da, respectively. In this table, the variables

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presenting in at least 80% of either group were extracted and the variables with less

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than 30% relative standard deviation (RSD) in quality control samples were then

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retained for further multivariate data analysis because they were considered stable

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enough for prolonged LC-Orbitrap- MS analysis. For each chromatogram, the intensity

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of each ion was normalized to the internal standard intensity, in order to partially

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compensate for the concentration bias of features between samples and to obtain the

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relative intensity of features.20 The acquired data set was subjected to statistical

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analyses.

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Candidate ions annotations

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Candidate chromatographic features accounting for separation among tea types were

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identified by orthogonal projections to latent structures discriminant analysis 9

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(OPLS-DA) modeling. The features of interest had variable importance project (VIP) >

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than 1.5. The tandem mass spectrometry (MS/MS) of these features were collected by

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Data Depend MS/MS model and subjected to in silico analysis that combined

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manually matching with MS2 fragments against online databases (Metlin, HMDB,

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Mass Bank, Mzcloud).21-24 The screened features were further filtered by database

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TMDB (http://pcsb.ahau.edu.cn:8080/TCDB/f),25 a specific tea database enrolled all

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the phytochemicals in tea that previously reported in literature, and the features were

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finally annotated. Authentic standards of C, GC, EC, ECG, EGC, EGCG, gallic acid,

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caffeine, theophylline, theobromine and theanine were used as validation.

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Statistical analyses

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Data were evaluated using: principal component analysis (PCA), OPLS-DA,

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hierarchical cluster analysis (HCA) using Simca-P 14.1 software (Umetrics AB, Umeå,

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Sweden) after Pare scaling to investigate the overall tea metabolome variations caused

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by

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(http://www.informationisbeautiful.net/2012/7-way-venn). Heatmap analysis was

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performed with Multi Experiment Viewer software (version 4.8.1). The significance

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level of the metabolite differences between groups was calculated by Analysis of

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Variance (ANOVA) with pairwise post hoc comparisons by the method of Bonferroni

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using the SPSS 21 software.

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RESULTS AND DISCUSSION

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Sensory evaluation of the teas

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The tea products from each tea type were evaluated for color, taste, fragrance and shape.

the

process.

Venn

plots

were

drawn

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The results showed all samples had the expected sensory characteristics associated with

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each tea types (Figure 2 and Table S1). This indicates that the six tea types were

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successfully prepared from the same batch of fresh leaf. To our knowledge, this is the

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first attempt to make all six tea types from the leaves of a single C. sinensis cultivar

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when the leaves were harvested and processed at the same time. This required the

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experience of a ―skilled tea processing master‖ who had the ability to thoroughly

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manipulate all steps involved in the six typical processing methods.

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HPLC analysis of catechins and caffeine concentrations among teas types

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Processing methods could alter the content of catechins, which are considered the

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major phytochemical component in tea. As shown in Table 1, total catechin levels

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from high to low were green tea, yellow tea, oolong tea, white tea, dark tea and black

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tea, respectively. While this result is consistent with the endogenous enzymatic

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oxidative degradation of catechins attributed to polyphenol oxidase that is expected

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during processing, the results of statistical analysis support the existence of three

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distinct categories of catechin content: minimally affected (yellow or green which were

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equivalent to unprocessed leaves), moderately affected (oolong, white, and dark), and

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maximally affected (black). Of interest is the observation that gallic acid increased in

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white tea, black tea and dark tea; this likely due to the ―crack reaction‖ products

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which accumulate during fermentation and post-fermentation processing.26,27

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Meanwhile, due to its stable chemical characteristics, the concentration of caffeine

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was unaffected by all post-harvest processing methods.

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Our findings are also of interest to the field of tea bioactives. Considerable attention 11

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has been given to the role of tea catechins in accounting for the bioactivity of tea

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infusions. These data support the notion that higher biological activity would be

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expected using green or yellow activity if it were catechin dependent. On the other

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hand, black tea would represent a useful negative control relative to the testing of

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catechin specific mediation of biological effects in a matrix background of the other

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chemistry present in tea leaves. Reciprocally, these data argue that bioactivity of black

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tea is not catechin dependent, if it were made from the same C. sinensis cultivar as

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green or yellow tea. Thus the comparative evaluation of green, yellow and black tea

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prepared from the same C. sinensis cultivar could provide a gateway into uncharted

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chemistry that are important to human health. Another observation of interest is that

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previous reports have suggested that white tea would be classified into the minimal

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effect catechin category. Our findings are inconsistent with that expectation. This

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discrepancy is likely due to difference in chemistry of the fresh leaves attributable to

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C. sinensis cultivar, highlighting the value of the approach reported herein in efforts to

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better understand the chemistry of fermentation and the origins of the bioactivity of

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various types of tea.

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Global analysis of the metabolome by tea type

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Metabolomics analysis was used to provide a global profile of chemical differences

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among tea types prepared from a single C sinensis cultivar in recognition of one of the

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guiding principles in the application of metabolomics to a new problem, i.e., ―we don’t

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know what we don’t know‖. Accordingly, the chemical profile of the tea types was

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analyzed using an untargeted approach. A typical total ion current chromatogram for 12

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each tea type is shown in Figure 3A. A total of 2489 ion features were detected after

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peak alignment. A Venn plot was constructed using these data and indicated that 2059

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out of 2489 ion features were detected in all samples. Of the remaining 430 ion features,

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no feature was specific to only one type of tea (Figure 3B). This indicates that the

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chemical changes occurring during post-harvest processing (Figure 1) are primarily

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quantitative in nature. Nonetheless, it should be noted that because of the strong signal

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intensity due to catechins, signal suppression of ions present in smaller amounts is

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known to occur. For those ions, newer deep analysis metabolomics procedures are

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required and have been recently introduced into metabolomics data acquisition and

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analysis work flows. Thus the analyses reported herein, while exceedingly useful for

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the tea science field, are limited by this constraint, which may be of value in

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understanding changes in sensory characteristics of tea cultivars and tea types,

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especially those associated with degradation of quality over time following leaf

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processing. Moreover, for the field of tea bioactives, there is growing recognition that

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small molecules with striking biological activities exert meaningful effects at

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nanomolar exposure concentrations.28 Thus, our approach can be of great value as the

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tea field advances into the arena of deep analysis of the metabolome using tools such

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as Metabox.29

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Multivariate analyses

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The mass spectra data set and the HPLC catechins data in Table 1 were analyzed by

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PCA separately (Figure 4A and B). The chemical phenotypes of the six tea types were

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well discriminated, all replicates from each tea type clustered together and were 13

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separated from other types as shown in Figure 4A (PC1 = 38.2% and PC2 = 24.3%).

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Figure 4B shows similar grouping except white tea and black tea are more distant. In

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addition, the HCA analysis of these same data (Figure 4C and D) provided further

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insight, displaying the interrelationships among tea types based on the entire profile of

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catechins assessed, clear separation between tea types, and the order of closeness of tea

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types were generally similar. While the position of the fresh leaves changed in the two

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sets of HCA, the black tea and white tea reversed their positions, indicating that

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non-catechin components play a role in distinguishing among tea types.

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Feature annotation and Heatmap analysis of the relative variation among tea

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types

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OPLS-DA identified ions that distinguished among tea types. The nature of these

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differences was summarized using several tools given the wide range of differences that

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were observed. A total of 168 features overlapped among tea types and were excluded.

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Compared with fresh leaves, the candidate features (VIP>1.5) that distinguished green

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tea (43), yellow tea (48), black tea (49), dark tea (54), oolong tea (43) and white tea (51)

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were subjected to vigorous in silico analysis. Overall 111 features were annotated and

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98 of them were identified based on authentic standards or tandem mass spectrometry

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(Table 2).

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Heatmap analysis was applied to visualize the relative variation of the annotated

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chemicals in all six tea types (Figure 5), and the relative fold change of annotated

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features were listed in Table 3. Color coding was graded from green to red with the

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relative intensity shift from low to high, respectively. All annotated compounds were 14

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classified into six categories including amino acids, catechins, flavonoids and flavone

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glycosides, phenolic acids, alkaloids, and others. As reflected in the heatmap,

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manufacturing procedures either significantly decreased or increased certain

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distinctive chemicals in a given tea type. The following sections identify several

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notable changes in each chemical category.

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Amino acids

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Dark tea

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significantly increased, 231.9- and 10.4-folds increase, respectively, after dark tea

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processing. This finding is consistent with the possibility that these amino acids are

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microbial formation products derived from tyrosine and aspartic acid.30

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White tea

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aminobutyric acid were significantly increased 4.9, 2.4，3.6，8.2，2.0，6.1 and 2.0 fold,

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respectively, after white tea processing. This finding is consistent with previous reports

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that proteolysis and transformation among amino acids occurs during withering and

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that these amino acid alterations contribute to the ―umami taste‖ of white tea.17,31

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Flavanols

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Black tea Flavan-3-ol and polymeric catechin content changed marked during the

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fermentation process resulting in black tea. EGCG, EGC, EC dramatically decreased

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by 21% to 68% with concomitant increases in polymeric catechins such as theaflavin,

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theaflavin-3-gallate, theacitrin A, theasinensin A and theasinensin B ranging from 1.6

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to 29.6 times. This finding is consistent with other reports.32-34

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White tea

Amino acids, such as dihydroxyphenylalanine and valine were found to be

Alanine, tyrosine, phenylalanine, proline, tryptophan, leucine and gamma

White tea is classified as a slightly fermented tea type since the 15

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processing method was considered very gentle and preserved most characteristics

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including the catechins composition of the fresh leaves.35,36 However, our result

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showed marked decreases in catechins (19% to 75%) with a concomitant increase in

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the polymeric catechin theasinensin B (2.3 fold). Although there was no hygrothermal

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action in white tea processing, catechins are known to be slowly oxidized with the

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withering. Thus it appears that the conditions of room temperature, 70% humidity, and

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48 hours withering time was sufficient to allow the endogenous polyphenol oxidase to

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significantly decrease catechin content.

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Dark tea

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times after dark tea processing compared with the other tea types. Meanwhile, the

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catechins were also significantly decreased during dark tea processing, which may be

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due to microbial degradation during the post fermentation step.37

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Other notable changes

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by processing methods. Compared with other tea types, herbacetin, malvidin and

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quercetin 3-O-glucoside were higher levels after black tea processing (6.4, 4.5 and 3.2

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folds higher compared with the fresh leaves, respectively). On the other hand,

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eriodictyol, myricetin, naringenin, tiliroside and myricetin 3-glucoside were markedly

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decreased in black tea (89%, 82%, 59 %, 94% and 36%, respectively). The same type

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of phenomenon was observed after white tea processing. Kaempferol-3-glucoside was

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8.9 times higher than fresh leaves. The noted changes in black and white tea are

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consistent with the possibility that flavonoids with hydroxyls in B ring are altered

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during the fermentation step in black tea processing or the withering step in white tea

Theaflagallin and epiafzelechin significantly increased by 27.7 and 1.5

Other flavonoids and flavonoid glycosides were also altered

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processing.

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Phenolic acids

328

contribute to the color and taste of a tea infusion.14,38

329

Black tea

330

by black tea processing: caffeic acid was undetectable39,40 and chlorogenic acid and

331

salicylic acid were decreased by 80.0% and 83.0%, respectively.

332

Dark tea Gallic acid and 2,5-dihydroxyphenylacetic acid sharply increased (10.3 and

333

3.8 times, respectively) due to dark tea processing compared with other teas. Whereas

334

the dark tea processing also led to marked decrease of shikimic acid, quinic acid and

335

malic acid (56%, 92% and 94%, respectively).

336

Alkaloids

337

the dry weight of the leaf.41 After processing, the caffeine level remained relatively

338

stable among the six types of tea while theophylline and theobromine markedly

339

increased to 69.4 and 1.5 times, respectively, after dark tea processing, perhaps due to

340

microbial fermentation. Aspergillus niger van Tieghem have been reported to produce

341

theobromine and theophylline.3,42,43

342

Synthesis

343

Endogenous enzymes play a very important role in tea processing methods. A

344

dominant feature of black tea processing was the formation of catechin polymers such

345

as theaflavins while the monomers of catechins and other flavonoids decreased

346

sharply. This also occurred during oolong tea except the magnitude of the changes

347

was smaller than observed after black tea processing; however, this is controversial in

Phenolic acids are another important chemical group in tea that

Caffeic acid, chlorogenic acid and salicylic acid were markedly reduced

Caffeine is the dominant alkaloid in tea and it can constitute 1.2-5.1% of

17

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348

the tea quality arena, possibly because most studies to not consider potential

349

contributions of difference in tea variety, which was control in our study. To this point,

350

oolong tea had few distinguishing characteristic in our heatmap. We speculate that this

351

is due to our focus on nonvolatile chemical constituents; whereas, oolong tea’s most

352

distinctive characteristic is its flower aroma. We suspect oolong tea is more likely to

353

be different in its volatile components relative to other tea types. As noted above,

354

white tea processing is considered a very gentle method which results in no obvious

355

chemical changes. However, in this study we demonstrated the chemical reaction was

356

indeed comparatively strong during the long withering step, and that the chemical

357

profiling was dramatically changed compared to the fresh leaves, including an

358

increase in several amino acids, with concomitant decreases in catechins monomers

359

and phenolic acids. Such changes are likely to account for the umami or sweet but less

360

astringent taste characteristics of white tea. Dark tea was distinguished by large shifts

361

in amino acid content with concomitant increases phenolic acids, alkaloids, and some

362

pigments. Green tea and yellow tea look alike in the heatmap; this is consistent with

363

the fact that the only difference in processing is the yellowing step which apparently

364

has little effect on the chemical profiles that were detected. Nonetheless, given the

365

sensory evaluation results, distinct chemistries must underlie the sensory differences

366

that are detected and this topic merits further investigations. Finally, green tea is

367

generally considered synonymous with fresh leaves within the tea science field.

368

However, our comparison of processed green tea leaves with lyophilized fresh leaves

369

of the same Camellia cultivar showed they are not equal. Some amino acids 18

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370

significantly increased and this may enhance the umami taste and some lipids

371

decreased which may impact aroma since they are transformed into aroma compounds.

372

This serves as an important reminder that leaf withering begins when they are plucked

373

from the plant, and that enzymatic reaction occurs even during the short time from the

374

field to the factory. The drying method of heating might also contribute to the flavor

375

and aroma of the green tea compared with the fresh leaves.

376

In summary, by using only one Camellia cultivar to exclude confounding factors due to

377

difference in chemical composition that exist among tea varieties, distinct changes in

378

chemical composition were found to be associated with each tea processing method

379

that extend beyond those traditionally associated with each process. Our findings

380

contribute new insights to the chemotaxonomy of teas and the identification of the

381

effects of processing specific techniques on tea chemistry. This work has the potential

382

to provide a foundation for continuing efforts to improve tea quality via the

383

optimization of processing methods. There exists the potential to develop new niche

384

markets through chemistry directed tailoring of processing methods to take advantage

385

of unique composition of newly identified and developed varieties of Camellia and

386

other family members of the family Theaceae.

387

ACKNOWLEDGMENT

388

We thank Shihui Fang and Jingming Ning for their technical support on the

389

processing of six tea types.

390

SUPPORTING INFORMATION

391

The result of sensory evaluation (Table S1) 19

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FUNDING This study was supported by the Key research and development projects of Anhui province (1804b06020367), the Earmarked Fund for Anhui Featured Agricultural Development Project (Anhui Provincial Agriculture Commission, 2016-188), the Earmarked fund for China Agriculture Research System (CARS-19), Funds of Anhui Provincial Science and Technology Department (1408085MKL39), the High-End Foreign

Experts

Recruitment

Program

(GDT20143400024),

Anhui

Major

Demonstration Project for Leading Talent Team on Tea Chemistry and Health (1306c083018). 22

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FIGURE CAPTIONS Figure 1. Flow diagram depicting the manufacture processes used to produce the six tea types investigated. Figure 2. The pictures of processed six tea types that used for sensory evaluation (upper: dry leaves, lower: tea infusion). (A) Green tea (B) Yellow tea (C) White tea (D) Oolong tea (E) Black tea (F) Dark tea Figure 3. LC-Orbitrap-MS analysis of six tea types (A) Typical total ion current (TIC) chromatogram (B) Venn plot. Numbers represent the detected features in relative teas. Figure 4. Multivariate statistical analysis of six tea types. (A and B) The PCA score plot of the LC-MS data set and the HPLC data set, respectively. (C and D) the HCA plot of the LC-MS data set and the HPLC data set, respectively. Figure 5. The heatmap analysis of annotated chemicals in fresh leaves and six tea types by chemical categories. The compounds were identified either by MS2 spectra* or by authentic standards#.

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TABLES Table 1 The Absolute Content of Catechins and Caffeine in Six Tea Types (mean±sem, n=3, mg/g) Fresh leaves

Green tea

Yellow tea

Oolong tea

d

c

0.38±0.004

C

0.97±0.07a

0.98±0.11a

GC

2.15±0.03b

EGC CAF

29.80±0.15

EC

7.12±0.17b

8.41±0.05a

7.94±0.30ab

5.03±0.05c

EGCG

69.53±0.63a

75.04±0.94a

71.65±2.57a

GCG

2.12±0.05a

2.69±0.06a

ECG

13.67±0.37ab 114.9±1.80b

Catechins

0.23±0.02

d

GA

Total

a-e

d

0.33±0.01

White tea

Black tea

cd

Dark tea b

4.54±0.25a

0.98±0.02

0.82±0.15

1.94±0.09

0.90±0.02a

0.76±0.02ab

0.51±0.03b

0.23±0.04b

0.82±0.04a

2.78±0.04ab

2.67±0.13ab

1.69±0.03b

0.94±0.07c

0.55±0.01c

3.20±0.32a

19.37±0.55b

25.92±1.34a

23.25±0.60ab

13.09±0.52c

6.37±0.06d

0.88±0.09e

22.14±0.56b

b

ab

ab

ab

ab

33.71±0.53a

3.40±0.07d

Not detected

7.64±0.24ab

42.98±0.21c

49.05±0.68b

5.46±0.43e

21.47±0.06d

2.85±0.69a

1.41±0.08a

2.84±0.12a

2.04±0.62a

3.07±0.38a

14.98±0.27a

14.55±0.65a

8.55±0.05c

12.13±0.38b

2.68±0.17e

6.00±0.15d

130.8±2.51a

123.8±3.98ab

73.50±0.9c

75.24±0.81c

11.84±0.57d

64.32±0.61c

30.96±0.31

31.51±1.33

30.74±0.17

33.43±0.42

a

31.16±0.75

: Values in the same row that are labeled with different superscript letters differ significantly (P < 0.05). Statistical analysis was

ANOVA with pairwise post hoc comparisons by the method of Bonferroni.

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Table 2 Tentative Features Annotation through Tandem Mass Spectrometry and /or Authentic Standards Order 1

Accurate MZ 307.0801

Theoretical MZ 307.0812

Delta ppm 3

Adduct ion

RT

Formula

Name

Fragments

[M+H]

+

2.11

C15H14O7

Gallocatechin*

+

#

139

169

289

137

2

443.0965

443.0973

1

[M+H]

2.44

C22H18O10

Catechin gallate*

123

139

153

291

3

611.1384

611.1395

1

[M+H]+

2.46

C30H26O14

Theasinensin C*

139

611

593

307

247

2

[M+H]

+

3.14

C30H26O13

Epigallocatechin-(4beta->8)-catechin

[M+H]

+

3.24

C15H14O7

Epigallocatechin*#

127

169

141

139

181

[M+H]

+

3.25

C37H30O18

Theasinensin B*

593

611

425

443

[M+H]

+

139

121

247

273

261

[M+H]

+

3.49

C15H14O6

Epicatechin*

139

123

147

207

179

[M+H]

+

3.59

C37H30O17

Epicatechin-(4beta->8)-epigallocatechin 3-O-gallate

[M+H]

+

3.62

C22H18O11

Epigallocatechin Gallate*#

289

127

307

139

151

[M+H]

+

3.66

C22H18O11

Gallocatechin 3-O-gallate*

138

153

307

289

+

4 5 6 7 8 9 10 11

595.1429 307.0804 763.1491 291.0855 291.0854 747.1553 459.091 459.091

595.1446 307.0812 763.1505 291.0863 291.0863 747.1556 459.0922 459.0922

2 1 2 2 0 2 2

3.46

#

C15H14O6

Catechin*

#

12

275.0904

275.0914

3

[M+H]

3.79

C15H14O5

Epiafzelechin*

139

137

257

121

13

443.096

443.0973

2

[M+H]+

3.84

C22H18O10

Epicatechin 3-O-gallate*#

139

153

123

425

291

3

[M+H]

+

4.05

C22H18O9

Epiafzelechin 3-O-gallate*

139

153

107

121

409

[M+H]

+

4.06

C29H24O12

Theaflavin*

427

139

259

163

271

[M+H]

+

4.1

C36H28O16

Theaflavin-3-gallate*

139

397

699

127

-

4.14

C36H28O16

Theaflavin Monogallates*

577

407

169

241

+

4.18

C43H32O20

Theaflavin Digallate*

731

333

561

277

[M-H]

-

3.38

C37H28O18

Theacitrin A*

741

169

137

151

[M-H]

-

3.73

C44H34O22

Theasinensin A*

761

743

283

423

[M-H]

-

3.8

C23H20O11

Epigallocatechin 3-(3-methylgallate)*

125

161

307

183

-

14 15 16 17 18 19 20 21

427.1010 565.1323 717.1431 715.1305 869.1545 759.1207 913.1473 471.0938

427.1024 565.1341 717.145 715.1306 869.156 759.1203 913.1469 471.0933

3 2 1 1 0 0 0

[M-H]

[M+H]

621

22

609.0886

609.0886

0

[M-H]

3.89

C29H22O15

Epigallocatechin 3,5,-di-O-gallate

23

399.0729

399.0722

1

[M-H]-

3.97

C20H16O9

Theaflagallin*

137

261

339

381

219

24

911.1318

911.1313

0

[M-H]-

4.02

C44H32O22

Theacitrin C*

169

455

855

125

773

25

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1

[M-H]-

4.07

C27H20O13

Epitheaflagallin 3-O-gallate*

169

125

413

491

533

381

0

[M-H]

-

4.12

C36H28O15

Theaflavate B*

137

427

561

681

383

289

-

169

289

535

125

27

851.1470

851.1465

0

[M-H]

4.2

C43H32O19

Theaflavate A*

713

579

28

90.05455

90.05496

4

[M+H]+

0.88

C3H7NO2

Alanine*

90

72

29

116.0702

116.0706

3

[M+H]+

0.9

C5H9NO2

Proline*

70

68

5

[M+H]

+

0.91

C5H11NO2

Valine*

72

55

57

[M+H]

+

0.92

C11H20N2O3

Pro-Leucine*

114

166

86

[M+H]

+

0.92

C5H9NO4

Glutamate*

84

102

56

[M+H]

+

0.94

C6H13NO2

Leucine*

86

69

[M+H]

+

1.23

C13H24N2O8

1-deoxy-1-L-theanino-D-fructopyranose*

158

208

253

[M+H]

+

0.96

C7H14N2O3

Theanine*

158

129

84

[M+H]

+

1.23

C6H13N3O3

Argininic acid*

158

60

71

140

+

30 31 32 33 34 35 36

118.0856 229.1540 148.0601 132.1014 337.1605 175.1071 176.1045

118.0863 229.1547 148.0604 132.1019 337.1598 175.1077 176.103

3 2 4 2 3 5

#

183

301

114

37

182.0805

182.0812

3

[M+H]

1.24

C9H11NO3

Tyrosine*

165

136

91

119

38

198.0754

198.0761

3

[M+H]+

1.41

C9H11NO4

Dihydroxyphenylalanine*

152

107

135

139

3

[M+H]

+

2.03

C9H11NO2

Phenylalanine*

120

103

93

[M+H]

+

3.44

C11H12N2O2

Tryptophan*

118

146

188

159

-

0.86

C4H7NO4

Aspartic Acid*

72

104

[M+H]

+

0.91

C4H9NO2

γ-Aminobutryic acid*

87

69

[M+H]

+

3.26

C15H12O6

Eriodictyol*

271

289

137

153

261

121

[M+H]

+

3.36

C30H26O13

Tiliroside*

287

577

147

105

269

431

[M+H]

+

3.5

C27H30O15

Vicenin Ⅱ*

577

559

445

427

[M+H]

+

3.55

C30H26O12

Procyanidin B2*

127

409

291

427

301

287

+

147

329

39 40 41 42 43 44 45 46

166.0857 205.0964 132.0309 104.0703 289.0700 595.1437 595.1642 579.1476

166.0863 205.0972 132.0302 104.0706 289.0707 595.1446 595.1658 579.1497

3 5 2 2 1 2 3

[M-H]

47

595.1641

595.1658

2

[M+H]

3.57

C27H30O15

Kaempferol 3-rungioside

48

433.1109

433.1129

4

[M+H]+

3.6

C21H20O10

Kaempferol 3-rhamnoside*

287

269

257

147

4

[M+H]

+

3.6

C27H30O14

Kaempferitrin*

287

285

415

433

[M+H]

+

3.63

C26H28O14

Kaempferol 3-rhamnoside-7-arabionopyranoside

49 50

579.1683 565.1539

579.1708 565.1552

2

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Journal of Agricultural and Food Chemistry

51 52

433.1118 433.1107

433.1129 433.1129

2

[M+H]+

3.48

C21H20O10

Isovitexin*

283

281

339

415

313

403

2

[M+H]

+

3.69

C21H20O10

Vitexin*

415

397

283

367

337

323

+

153

165

273

290

274

53

319.0437

319.0448

3

[M+H]

3.7

C15H10O8

Myricetin*

54

449.1061

449.1078

3

[M+H]+

3.72

C21H20O11

Quercetin 3-O-rhamnoside

55

611.1596

611.1607

1

[M+H]+

3.74

C27H30O16

Rutin*

303

465

129

3

[M+H]

+

3.74

C15H10O6

Cyanidin*

137

213

109

241

[M+H]

+

3.78

C15H10O7

Delphinidin*

229

257

201

125

[M+H]

+

3.8

C15H10O7

Quercetin*

153

137

229

257

285

[M+H]

+

3.84

C15H10O7

Morin*

153

219

205

137

165

[M+H]

+

3.84

C15H12O5

Naringenin*

153

147

119

[M+H]

+

4.7

C15H10O6

Kaempferol*

258

153

121

165

213

[M+H]

+

3.88

C20H18O11

Quercetin 3-arabinopyranoside

+

274

56 57 58 59 60 61 62

287.0541 303.0487 303.0489 303.0487 273.075 287.0539 435.0909

287.055 303.0499 303.0499 303.0499 273.0758 287.055 435.0922

4 3 4 2 4 2

63

579.1486

579.1497

1

[M+H]

4.21

C30H26O12

Procyanidin B5

64

303.0485

303.0499

4

[M+H]+

4.35

C15H10O7

Herbacetin*

169

121

181

2

[M+H]

+

4.66

C17H14O7

Malvidin*

242

287

213

[M+H]

+

3.87

C15H10O6

Luteolin*

153

135

241

[M+H]

+

5.96

C21H20O11

Kamepferol 3-glucoside*

287

259

153

[M-H]

-

1.76

C30H26O14

Prodelphinidin B

[M-H]

-

3.44

C28H24O17

Myricetin 3-(6''-galloylglucoside)

[M-H]

-

3.49

C22H22O11

Kaempferide 3-glucoside*

301

283

427

163

445

[M-H]

-

3.71

C21H20O13

Myricetin 3-glucoside*

316

317

287

271

178

[M-H]

-

3.75

C33H40O20

Kaempferol 3-rutinoside-7-galactoside

-

153

301

65 66 67 68 69 70 71 72

331.0804 287.0538 449.1061 609.1256 631.0949 461.1097 479.0838 755.2038

331.0812 287.055 449.1078 609.125 631.0941 461.1089 479.0831 755.204

4 3 0 1 1 1 0

73

463.0891

463.0882

1

[M-H]

3.8

C21H20O12

Quercetin 3-O-glucoside*

300

137

229

74

154.0494

154.0499

3

[M+H]+

1.22

C7H7NO3

4-Aminosalicylic acid*

108

107

78

75

139.0385

139.039

3

[M+H]+

2.1

C7H6O3

2,5-Dihydroxybenzaldehyde*

111

93

3

-

3.35

C8H8O4

2,5-Dihydroxyphenylacetic acid*

149

123

76

167.0356

167.035

[M-H]

27

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Journal of Agricultural and Food Chemistry

77 78

139.0385 165.0541

139.039 165.0546

Page 28 of 38

3

[M+H]+

3.23

C7H6O3

4-Hydroxybenzoic acid*

95

121

109

3

[M+H]

+

4.84

C9H8O3

4-Hydroxycinnamic acid*

119

105

147

+

79

163.0386

163.039

2

[M+H]

3.16

C9H6O3

4-Hydroxycoumarin*

121

91

80

175.0255

175.0248

4

[M-H]-

1.25

C6H8O6

Ascorbic acid*

87

115

127

71

1

+

2.17

C9H8O4

Caffeic acid*

135

117

145

163

[M-H]

-

2.61

C22H18O12

Chicoric acid*

179

161

291

311

427

[M-H]

-

2.84

C16H18O9

Chlorogenic acid*

191

161

[M-H]

-

3.41

C9H8O2

Cinnamic acid*

129

103

[M+H]

+

3.6

C9H8O3

Coumaric acid*

91

119

147

[M+H]

+

3.52

C9H6O2

Coumarin*

91

103

77

-

3.47

C14H10O9

Digallate*

125

293

151

169

107

153

127

125

109

69

113

81 82 83 84 85 86 87 88

181.0492 473.0737 353.0886 147.0458 165.054 147.0435 321.026 171.0283

181.0495 473.0726 353.0878 147.0452 165.0546 147.0441 321.0252 171.0288

2 2 4 3 3 2 2

[M+H]

[M-H]

+

1.38

C7H6O5

Gallic acid*

-

[M+H]

#

89

131.0356

131.035

4

[M-H]

2.33

C5H8O4

Glutaric acid*

87

90

118.0647

118.0651

3

[M+H]+

3.36

C8H7N

Indole*

91

91

188.0701

188.0706

2

[M+H]+

3.36

C11H9NO2

Indoleacrylic acid*

170

142

115

6

-

1.05

C4H6O5

Malic acid*

115

71

89

[M+H]

+

2.17

C9H17NO5

Pantothenic acid*

90

184

202

[M+H]

+

1.32

C10H16O

Piperitone*

135

111

109

-

1.04

C7H12O6

Quinic acid*

85

93

127

[M+H]

+

3.79

C7H6O2

Salicylaldehyde*

77

95

[M+H]

+

3.84

C7H6O3

Salicylic acid*

121

95

[M-H]

-

3.57

C7H10O5

Shikimic acid*

93

67

59

137

-

92 93 94 95 96 97 98

133.0151 220.1172 153.1274 191.0566 123.0436 139.0384 173.0461

133.0143 220.118 153.1274 191.0561 123.0441 139.039 173.0456

3 0 2 4 4 2

[M-H]

[M-H]

57

99

427.0682

427.0671

2

[M-H]

3.99

C21H16O10

Theaflavic acid*

137

289

383

409

100

345.0808

345.0816

2

[M+H]+

1.42

C14H16O10

Theogallin*

193

299

153

237

3

-

1.24

C13H16O10

β-Glucogallin*

169

125

179

313

+

0.93

C5H13NO

Choline*

60

58

101 102

331.0681 104.1064

331.0671 104.107

5

[M-H]

[M+H]

28

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Journal of Agricultural and Food Chemistry

103 104

118.0857 181.0717

118.0863 181.072

4

[M+H]+

1

[M+H]

+ +

1.14

C5H11NO2

1.93

Betain*

C7H8N4O2

58

59

#

138

153

#

Theobromin*

110

105

181.0714

181.072

1

[M+H]

3.3

C7H8N4O2

Theophylline*

124

96

106

195.0864

195.0877

5

[M+H]+

3.6

C8H10N4O2

Caffeine*#

138

110

123

4

[M+H]

+

7.6

C26H50NO7P

PC(18:2/0:0)*

263

221

337

417

[M+H]

+

8.1

C24H50NO7P

PC(16:0/0:0)*

184

104

[M+H]

+

8.88

C35H34N4O6

Phaeophorbide B*

589

561

571

547

[M+H]

+

10.13

C35H36N4O5

Pheophorbide A

[M+H]

+

10.54

C33H34N4O3

Pyropheophorbide A

107 108 109 110 111

520.3375 496.3373 607.2528 593.2724 535.2675

520.3398 496.3398

5

607.2551

3

593.2759

5

535.2704

5 2

*

#

The compounds were identified either by MS spectra or by authentic standards .

29

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Page 30 of 38

Table 3 Relative Fold Change of Annotated Chemicals in Six Tea Types Fold change (Tea vs. Fresh leaves) ID

Name

#

Fresh

Green

Yellow

Oolong

White

Black

Dark

leaves

tea

tea

tea

tea

tea

tea

a

a

b

0.5

d

0.25

e

0.72c

1

Gallocatechin*

1.00

0.96

0.87

2

Catechin gallate*

1.00a

0.86b

0.84b

0.58d

0.81bc

0.01e

0.73c

3

Theasinensin C*

1.00a

0.84b

0.79b

0.56d

0.68c

0.02f

0.47e

4

EGC-(4β-8)-C

1.00b

0.89c

0.88c

0.64d

0.53e

0.02f

1.15a

5

Epigallocatechin*#

1.00a

1.01a

1.05a

0.75b

0.38c

0.05d

0.70b

6

Theasinensin B*

1.00d

0.82e

0.82e

1.60c

2.29b

3.28a

0.57f

7

Catechin*#

1.00c

1.11b

1.18a

0.85d

0.31e

0.11f

1.00c

8

Epicatechin*#

1.00c

1.12b

1.19a

0.86d

0.32e

0.11f

0.98c

a

a

a

b

b

c

0.47c

9

EC-(4β-8)-EGCG

1.00

1.06

1.09

0.77

10

Epigallocatechin Gallate*#

1.00b

1.19a

1.28a

0.98b

0.79c

0.18e

0.61d

11

Gallocatechin 3-O-gallate*

1.00b

1.21a

1.31a

1.01b

0.81c

0.19e

0.63d

12

Epiafzelechin*

1.00bc

1.03b

0.98c

0.78d

0.39e

0.78d

1.53a

13

Epicatechin 3-O-gallate*#

1.00c

1.24b

1.38a

1.03c

0.81d

0.37f

0.70e

14

Epiafzelechin 3-O-gallate*

1.00b

0.83d

0.88c

1.08a

0.70e

1.11a

0.23f

15

Theaflavin*

1.00c

0.12f

0.12f

1.24b

0.70d

1.56a

0.24e

16

Theaflavin 3-gallate*

1.00c

0.21e

0.2e

4.15b

0.87d

7.31a

0.13e

17

Theaflavin Monogallates*

1.00c

0.21e

0.2e

4.13b

0.87d

7.20a

0.13e

18

Theaflavin Digallate*

1.00c

0.27d

0.17d

17.05b

1.40c

30.74a

0.06d

bc

c

c

b

a

1.00c

1.00

Theacitrin A*

1.00

20

Theasinensin A*

1.00d

1.49d

1.62d

5.49c

7.36b

29.57a

1.39d

21

EGC-3-(3-methylgallate)*

1.00c

1.11bc

1.12b

1.25a

1.14b

0.79d

1.03c

22

Epigallocatechin 3,5,-di-O-gallate

1.00b

0.91c

0.91c

0.80d

1.10a

0.81d

0.30e

23

Theaflagallin*

1.00e

0.31f

0.59ef

7.50c

2.91d

16.15b

27.67a

24

Theacitrin C*

1.00d

0.39d

0.45d

10.07b

3.39c

38.84a

0.24d

25

Epitheaflagallin 3-O-gallate

1.00e

0.53e

0.54e

29.2b

8.54c

97.18a

6.90d

26

Theaflavate B*

1.00d

0.003e

0.003e

4.95c

4.01c

34.27a

6.49b

27

Theaflavate A*

1.00c

1.00c

1.00c

5421.64b

1094.21c

50085.89a

1.00c

28

Alanine*

1.00d

1.11c

1.04cd

1.07cd

4.97a

2.20b

0.27e

29

Proline*

1.00

e

d

d

c

a

b

0.39f

30

Valine*

1.00f

1.58de

1.54e

31

Pro-Leucine*

1.00f

2.27c

32

Glutamate*

1.00d

33

Leucine*

34

1-deoxy-1-L-theanino-

1.64

1.11

2.24

1.83

0.45

19

1.75

1.00

b

0.82

0.03

f

25.26

8.15

3.91

1.72d

4.55b

2.61c

10.44a

2.40b

1.46e

1.42e

1.88d

3.43a

2.54b

2.73a

1.08d

1.46c

2.62ab

0.82e

1.00e

1.67cd

1.22de

1.77c

6.08a

3.00b

0.85e

1.00c

1.36b

1.02c

1.01c

0.93c

1.59a

0.72d

D-fructopyranose * 35

Theanine*#

1.00a

0.95b

0.97ab

0.84c

0.63d

0.82c

0.20e

36

Argininic acid*

1.00a

0.96b

0.97ab

0.84c

0.62d

0.83c

0.20e

37

Tyrosine*

1.00c

0.73d

0.72d

1.35b

2.45a

1.38b

0.39e

b

b

b

b

b

1.39

b

3.56a

2.6b

38

Dihydroxyphenylalanine*

1.00

39

Phenylalanine*

1.00e

0.98

1.06

2.21c

1.96d

1.12

2.26c

30

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231.91a 0.43f

Page 31 of 38

Journal of Agricultural and Food Chemistry

40

Tryptophan*

1.00d

0.99d

0.88e

1.08c

2.08a

1.55b

0.26f

41

Aspartic Acid*

1.00d

2.08b

2.07b

1.86c

1.82c

2.55a

0.17e

42

γ-Aminobutryic acid*

1.00b

0.43d

0.32e

1.01b

2.03a

0.95c

0.09f

43

Eriodictyol*

1.00a

1.02a

1.05a

0.77b

0.54c

0.11d

0.6c

44

Tiliroside*

1.00b

0.89c

0.88c

0.63d

0.6d

0.06e

1.17a

45

Vicenin Ⅱ*

1.00c

1.24a

1.08b

0.94d

1.10b

1.02c

0.85e

46

Procyanidin B2*

1.00b

1.06b

1.22a

0.96b

0.53c

0.12d

0.60c

47

Kaempferol 3-rungioside

1.00cd

1.20a

1.05bc

0.92e

1.09b

0.98d

0.79f

48

Kaempferol 3-rhamnoside*

1.00d

1.33b

1.19c

0.86e

0.87e

0.72f

2.11a

c

a

a

b

b

c

1.03c

49

Kaempferitrin*

1.00

1.32

1.28

1.09

50

Kaempferol-3-rha-7-ara

51

1.00d

1.17b

0.98d

1.09c

1.08c

1.27a

0.97d

Isovitexin*

1.00d

1.21b

1.06c

0.81e

0.84e

0.67f

1.63a

52

Vitexin*

1.00d

1.32b

1.18c

0.85e

0.87e

0.72f

2.07a

53

Myricetin*

1.00a

0.97a

0.99a

0.75b

0.97a

0.18d

0.61c

54

Quercetin 3-O-rhamnoside

1.00b

1.05a

1.06a

0.67e

0.91c

0.90c

0.77d

55

Rutin*

1.00c

1.20b

1.28a

0.95c

1.15b

1.31a

1.17b

56

Cyanidin*

1.00c

1.00c

1.02c

0.90d

1.08b

1.34a

0.71e

57

Delphinidin*

1.00a

0.95b

0.94b

0.70c

1.03a

1.03a

0.56d

58

Quercetin*

1.00b

0.95c

0.94c

0.70d

1.03ab

1.04a

0.56e

59

Morin*

1.00a

0.96b

0.94b

0.70c

1.03a

1.03a

0.56d

c

b

a

d

e

g

0.67f

60

Naringenin*

1.00

61

Kaempferol*

1.00d

62

Quercetin 3-arabinopyranoside

63

1.18

1.12

1.28

0.93

1.06bc

1.06b

0.81e

1.02cd

1.10a

0.70f

1.00bc

0.97cd

0.94d

0.83e

1.03ab

1.08a

0.73f

Procyanidin B5

1.00c

1.24a

1.06b

0.97cd

0.96d

0.80e

1.00c

64

Herbacetin*

1.00g

3.07e

3.38d

4.04c

1.51f

6.38b

7.99a

65

Malvidin*

1.00e

1.05e

0.84f

2.59c

1.83d

4.52a

2.97b

66

Luteolin*

1.00g

2.29f

3.33d

3.82c

2.69e

6.80b

7.50a

67

Kamepferol 3-glucoside*

1.00e

0.56f

0.28g

3.22d

8.94a

3.66c

4.13b

68

Prodelphinidin B

1.00ab

0.74c

0.72c

0.75c

0.93b

0.47d

1.03a

69

Myricetin 3-(6''-galloylglucoside)

1.00f

1.40e

3.21c

4.28b

5.93a

1.93d

0.09g

cd

bc

d

b

b

a

1.96

0.07e

1.11

Kaempferide 3-glucoside*

1.00

71

Myricetin 3-glucoside*

1.00d

1.15b

1.10bc

1.06cd

1.35a

0.64f

0.88e

72

Kaempferol-3-rut-7-gal

1.00d

1.44bc

1.43bc

1.52b

1.35c

3.79a

0.78e

73

Quercetin 3-O-glucoside*

1.00e

1.51b

1.56b

1.34c

1.11d

3.16a

1.24c

74

4-Aminosalicylic acid*

1.00b

6.40b

7.06b

3.43b

10.38b

6.13b

569.12a

75

2,5-Dihydroxybenzaldehyde*

1.00a

0.92b

0.82c

0.49e

0.27f

0.04g

0.74d

76

2,5-Dihydroxyphenylacetic acid*

1.00b

1.06b

1.01b

0.88c

0.72d

0.44e

3.45a

77

4-Hydroxybenzoic acid*

1.00b

1.01ab

1.03a

0.74d

0.45e

0.08f

0.86c

78

4-Hydroxycinnamic acid*

1.00a

0.98ab

0.98ab

0.68d

0.88c

0.7d

0.95b

79

4-Hydroxycoumarin*

1.00a

1.00a

0.98a

0.58c

0.97a

0.18d

0.76b

c

d

d

cd

19.15

a

3.46

1.28

1.07

1.30

0.41

70

d

0.83

0.79

1.05

Ascorbic acid*

1.00

81

Caffeic acid*

1.00ab

1.14a

0.89b

0.43c

0.26d

-e

0.92b

82

Chicoric acid*

1.00a

0.35c

0.32d

0.18e

0.58b

0.10f

0.17e

83

Chlorogenic acid*

1.00a

0.98a

0.97a

0.59b

0.99a

0.20d

0.33c

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1.52

15.89b

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84

Cinnamic acid*

1.00b

1.12a

1.09a

0.94b

0.56c

0.17d

1.14a

85

Coumaric acid*

1.00b

0.89c

0.93c

0.78d

1.05b

1.17a

0.62e

86

Coumarin*

1.00cd

1.32b

1.36b

1.06c

0.99cd

1.68a

0.91d

87

Digallate*

1.00c

1.02bc

1.00c

0.94d

1.51a

1.07b

0.05e

88

Gallic acid*#

1.00d

0.96d

1.21c

1.35c

0.87d

2.93b

10.32a

89

Glutaric acid*

1.00e

0.92e

1.00e

1.26d

1.50c

2.99b

3.81a

90

Indole*

1.00c

1.00c

0.91d

1.02c

1.77a

1.27b

0.42e

91

Indoleacrylic acid*

1.00d

0.96d

0.86e

1.05c

2.03a

1.39b

0.26f

92

Malic acid*

1.00c

1.02c

1.08b

0.95d

0.69e

1.35a

0.06f

b

c

d

e

c

e

1.12a

93

Pantothenic acid*

1.00

94

Piperitone*

1.00b

1.02b

1.35a

0.75c

0.56d

0.33e

0.58d

95

Quinic acid*

1.00b

0.84e

0.90d

0.95c

0.81f

1.18a

0.08g

96

Salicylaldehyde*

1.00c

1.15b

1.22a

0.89d

0.75e

0.29f

0.71e

97

Salicylic acid*

1.00d

1.07c

1.12b

0.83e

0.53f

0.17g

1.35a

98

Shikimic acid*

1.00b

0.83cd

0.86c

0.80d

0.63e

1.77a

0.44f

99

Theaflavic acid*

1.00d

0.39e

0.37e

4.09c

3.92c

20.65a

5.75b

100

Theogallin*

1.00b

1.05b

1.45a

0.79c

0.52d

0.30e

0.50d

101

β-Glucogallin*

1.00a

0.97b

0.87c

0.68e

0.83d

0.46f

0.23g

102

Choline*

1.00a

0.44e

0.46e

0.68d

0.89b

0.78c

0.23f

103

Betain*

1.00f

1.63d

1.58e

1.81d

5.10b

2.81c

11.98a

b

c

c

e

f

d

#

0.82

0.60

0.77

0.60

0.66

0.47

0.85

0.35

0.67

0.52

1.54a

104

Theobromin*

1.00

105

Theophylline*#

1.00b

0.76b

0.93b

0.94b

0.88b

1.87b

69.38a

106

Caffeine*#

1.00d

0.96e

0.97e

0.96e

1.03c

1.13b

1.20a

107

PC(18:2/0:0)*

1.00b

0.59e

0.57e

0.87c

0.50f

0.69d

1.65a

108

PC(16:0/0:0)*

1.00a

0.25f

0.19g

0.76b

0.58d

0.66c

0.49e

109

Pheophorbide B*

1.00c

21.93b

22.81b

50.77a

9.19c

21.93b

48.28a

110

Pheophorbide A

1.00g

3.35e

4.3d

6.73b

2.37f

5.12c

11.62a

111

Pyropheophorbide A

1.00d

107.43c

102.79c

192.93b

7.32d

117.76c

1134.77a

The compounds were identified either by MS2 spectra* or by authentic standards#. a-g

: Values in the same row that are labeled with different superscript letters differ significantly (P < 0.05). Statistical analysis was

ANOVA with pairwise post hoc comparisons by the method of Bonferroni. rha: rhamnoside. ara: arabionopyranoside. rut: rutinoside. gal: galactoside

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Journal of Agricultural and Food Chemistry

FIGURE GRAPHICS Figure 1

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Figure 3

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Figure 5

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GRAPHIC FOR TABLE OF CONTENTS

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