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Profiling and Quantification of Phenolics in Stevia Rebaudiana Leaves Hande Karaköse, Anja Müller, and Nikolai Kuhnert J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.5b01944 • Publication Date (Web): 03 Sep 2015 Downloaded from http://pubs.acs.org on September 21, 2015
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Journal of Agricultural and Food Chemistry
Profiling and Quantification of Phenolics in Stevia Rebaudiana Leaves
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Hande Karaköse, Anja Müller and Nikolai Kuhnert*
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Department of Life Sciences and Chemistry, Jacobs University Bremen, 28759 Bremen,
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Germany
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*Author to whom correspondence should be addressed Tel: 49 421 200 3120; Fax: 49 421 200
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3229; E-mail:
[email protected] 1 ACS Paragon Plus Environment
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Abstract
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Stevia rebaudiana (Bertoni) is a plant from the Asteraceae family with significant economic
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value due to steviol glycoside sweeteners in its leaves. Chlorogenic acids and flavonoid
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glycosides of Stevia rebaudiana from seven different botanical varieties, cultivated over two
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years and harvested three times a year in eight European locations were profiled and quantified in
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a total of 166 samples. Compounds quantified include chlorogenic acids and flavonoid glycosides
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and aglycons. All phenolic concentration profiles show a perfect Gaussian distribution. Principal
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component analyses allow distinction between varieties of different geographical origin and
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distinction between different plant varieties. While concentrations of all chlorogenic acids
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showed a positive correlation, no correlation was observed for flavonoid glycosides. Conclusions
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from these findings with respect to the biosynthesis and functional role of phenolics in Stevia
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rebaudiana are discussed.
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Keywords: Stevia rebaudiana, statistical evaluation, anova, LC-MS quantification
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Introduction
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Polyphenols are ubiquitous plant secondary metabolites encountered in all dietary plants. They
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have been linked in numerous epidemiological studies and subsequent human intervention studies
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with a variety of health benefits including prevention of cancer and type 2 diabetes, and
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improvement of cardiovascular disease.1-4 Dietary plants produce typically a large variety of
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structurally diverse polyphenols - most plants an average of around twenty distinct compounds.
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Some exceptions exist such as coffea canephora, which produces in excess of hundred distinct
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phenolic metabolites.5 Next to a significant number of compounds dietary plants biosynthesize
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polyphenols in significant quantities, which range from 1% of their dry weight up to 15% of their
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dry weight in fruits and leaves.6, 7 While quantitative data exist for many polyphenols in small
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sample sets (between 3 and 10 samples), sparse data is available in the literature for large sample
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sets with more than 100 samples of a single dietary plant. Accordingly, we have little reliable
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knowledge on how quantities of polyphenols vary in large sample sets, neither on an individual
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compound basis nor on a level of the full phenolic metabolic profile of the plant. We have little
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information about minimum and maximum level of phenolic concentrations, the spread and
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distribution of phenolic concentrations or correlation of concentrations in plants. Consequently,
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no knowledge exists how agricultural parameters might be varied to increase plant polyphenol
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content to improve health benefits or to minimize polyphenol content to avoid excessive
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bitterness or astringency associated with plants rich in polyphenols. As a result, we lack
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knowledge on how the biosynthesis of individual compound classes or compounds is regulated
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within the plant and hence, how compound levels influence one another. Furthermore, the
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complete polyphenol metabolome might be useful in barcoding samples in order to obtain
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information on their origin, growth conditions or botanical varieties.
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In this contribution we present a unique data set on the full polyphenolic metabolite profile of
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Stevia rebaudiana leaves from a total of 166 samples varying in their geographical origin,
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botanical varieties, year of harvest, time of harvest and agricultural growth conditions. From the
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166 samples, six chlorogenic acids (CGA) and six flavonoids were quantified using LC-MS
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methods and the statistical variation of the compounds quantified analyzed within the full data set
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and selected data subsets. Statistical analyses of the correlation between the individual secondary
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metabolites were carried out.
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We have previously reported on the presence of around 30 different chlorogenic acids (CGAs) in
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Stevia rebaudiana leaves.8 CGAs are a large family of esters formed between quinic acid and
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certain trans-hydroxycinnamic acids, most commonly caffeic, p-coumaric, and ferulic acid.6
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Flavonoids have as well been reported in Stevia rebaudiana leaves and quantified as total
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flavonoids, however, little detailed structural information on the compounds was reported.9,
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The current state of the art of Stevia rebaudiana`s phytochemical profile has recently been
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reviewed by Wülwer-Rieck.11 Similar to chlorogenic acids the presence of flavonoid compounds
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would add a health benefit to the usage of Stevia rebaudiana leaves in food products, in contrast
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to purified steviol glycosides currently approved by most legislative authorities. Flavonoids are a
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class of secondary metabolites that are produced ubiquitously in fruits and vegetables. By
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definition, flavonoids are compounds with a C6-C3-C6 structure comprising two aromatic rings,
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one fused as a benzopyran. Flavonoids include several subgroups which vary in the oxidation of
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the C3 carbon of the C-ring, and in their hydroxylation, methylation and glycosylation, all these
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classes collectively described by the term flavonoids. Within different subclasses of flavonoids,
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further differentiation is based on the number, position and nature of substituent groups attached
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on the rings. Most flavonoids appear in plants as their glycosides with sugars such as glucose,
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galactose, rhamnose, arabinose, xylose and rutinose conjugated to one or several phenolic OH 4 ACS Paragon Plus Environment
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groups. Flavonoid glycosides have many isomers with the same molecular weight but different
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aglycone and sugar components at different positions attaching on the aglycone ring.7
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Stevia rebaudiana belongs to the Asteraceae family of plants, and it is native to Paraguay. The
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high content of natural sweeteners, the steviol glycosides of the ent-kaurene class of compounds,
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contained in its leaves makes Stevia rebaudiana of a significant economic value in food industry
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in many applications as a “zero calorie sweetener”. Purified steviol glycosides have only recently
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been approved as food additives by European and US legislating authorities, leading to a
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dramatic increase in its global use and scientific interest in the crop.
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Materials and Methods
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Chemicals
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The IUPAC numbering has been used for chlorogenic acids and the chlorogenic acids of 3-
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caffeoylquinic acid (3-CQA), 4-caffeoylquinic acid (4-CQA), 5-caffeoylquinic acid (chlorogenic
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acid), 3,4-dicaffeoylquinic acid (3,4-diCQA), 3,5-dicaffeoylquinic acid (3,5-diCQA), and 4,5-
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dicaffeoylquinic acid (4,5-diCQA), were purchased from PhytoLab (Vestenbergsgreuth,
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Germany). Flavonoid glycoside standards were obtained from Sigma Aldrich, HPLC grade
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acetonitrile, methanol and chloroform was obtained from Carl-Roth GmbH, Karlsruhe.
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Stevia rebaudiana leaves were obtained from Universität Hohenheim who led the trial cultivation
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in eight different EU regions.
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Sample Preparation
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Two grams of Stevia rebaudiana leaves were immersed in liquid nitrogen, ground in a hammer
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mill, and extracted first with 150 mL of chloroform in a Soxhlet apparatus (Buchi B-811
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extraction system) for 2 h and then with 150 mL of methanol for another 2 h. Solvents were
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removed from the methanolic extract in vacuo, and extracts were stored at - 20 oC until required.
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LC-TOF MS
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The LC equipment (Agilent 1100 series, Bremen, Germany) comprised a binary pump, an
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autosampler with a 100 μL loop, and a diode array detector with a light-pipe flow cell (recording
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at 254 nm and scanning from 200 to 600 nm). This was interfaced with a MicroTOF Focus mass
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spectrometer (Bruker Daltonics) fitted with an ESI source. The MS parameters were: nebulizer
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1.6 bar, dry gas 12.0 L/min, dry temperature 220 °C. The MicroTOF was operated in negative ion
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mode and the mass range was 150 – 1200 m/z. Internal calibration was achieved with 10 mL of
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0.1 mol/L sodium formate solution injected through a six-port valve prior to each
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chromatographic run. Calibration was carried out using the enhanced quadratic calibration mode.
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LC-MSn
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The LC equipment (Agilent 1100 series, Bremen, Germany) comprised of a binary pump, an
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autosampler with a 100 μL loop, and a diode array detector with a light-pipe flow cell (recording
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at 254 nm and scanning from 200 to 600 nm). This was interfaced with an ion-trap mass
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spectrometer fitted with an ESI source (Bruker Daltonics HCT Ultra, Bremen, Germany)
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operating in Auto-MSn mode to obtain fragment ions m/z. Tandem mass spectra were acquired in
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Auto-MSn mode (smart fragmentation) using a ramping of the collision energy. Maximum
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fragmentation amplitude was set to 1 V, starting at 30% and ending at 200%. MS operating
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conditions (negative mode) were capillary temperature of 365 °C, a dry gas flow rate of 10
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L/min, and a nebulizer pressure of 50 psi.
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HPLC
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Separation was achieved on a 250 x 3 mm C18 column (Varian Pursuit XRS) with 5 μm particle
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size. Solvent A was water/formic acid (1000+0.005% v/v), and solvent B was acetonitrile (ACN). 6 ACS Paragon Plus Environment
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Solvents were delivered at a total flow rate of 0.5 mL/min and the column temperature was set to
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25 oC. 5 μL of samples were injected in to LC-MS system, unless stated otherwise. The gradient
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profile was 10 to 80% B in 60 min and a return to 10% B at 65 min and 5 min isocratic to re-
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equilibrate.
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Calibration Curve of Standard Compounds
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Most abundant chlorogenic acid derivatives (3-CQA, 4-CQA, 5-CQA, 3,5-diCQA, 4,5 diCQA)
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and two flavonoid glycosides (quercetin-3-glycoside and kaempferol-7-glycoside) were chosen
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for calibration curves.
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Stock solutions of the standard compounds were prepared in 80% ACN/water. A series of
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standard solutions was injected (5 μL) into the LC-MS system. The areas of the peaks of each
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standard from extracted ion chromatograms (EIC) were used to make the respective standard
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curves.
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Statistical Analyses
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Statistical analyses of the data were performed using IBM SPSS 20. The distributions of the
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variables were tested for normality using the Kolmogorov-Smirnov test. Associations between
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the variables were investigated using both parametric (Pearson’s correlation) and non-parametric
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(Spearman’s correlation) techniques. Results were interpreted using the widely accepted 5% level
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of significance.
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To test whether there were differences on each chlorogenic acid with respect to its origin or
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variety, separate one-way ANOVA analyses was employed, followed by two post-hoc tests:
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Fisher’s Least Significant Difference (LSD) as the least conservative test where equal variances
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are assumed and Games-Howell test where non-equal variances are assumed for the multiple pair
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wise comparison tests. All empirical results were interpreted using the widely accepted 5% level
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of significance (p < 0.05). 7 ACS Paragon Plus Environment
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A principle component analyses (PCA) based on the LC-MS dataset of stevia phenols was carried
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out using Profile Analysis 1.1 (Bruker Daltonics) with kernelizing prior to bucketing and
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normalization to sum of peaks to allow differentiation between different stevia varieties and
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geographic origins.
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Results and Discussion
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Within a large agricultural trial, Stevia rebaudiana was cultivated in nine Southern European
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locations from 2010 to 2011. Up to three times a year leaves were harvested from July to
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September. In total seven different botanical varieties of Stevia rebaudiana were cultivated.
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Following harvesting, leaves were dried and analyzed at the latest three months after harvesting.
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The European Stevia rebaudiana samples were complemented by commercial Stevia rebaudiana
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samples cultivated in South America and Asia resulting in a total of 166 samples.
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Compound identification
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Methanolic Stevia rebaudiana extracts were analyzed by LC-MSn in the negative ion mode using
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an ESI ion-trap mass spectrometer, allowing assignments of compounds to region-isomeric level,
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and additionally by high-resolution mass spectrometry using LC-ESI-TOF MS in negative ion
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mode allowing determination of molecular formulae based on the accurate mass measurements
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(see Supplementary Information). Molecular formulae were, in general, accepted if an error
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below 5 ppm was experimentally observed. The Stevia rebaudiana samples under investigation
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contained up to 29 chlorogenic acid derivatives, published by our group previously.8
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Furthermore, the samples contained a series of flavonoid glycosides. No new additional
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compounds were identified in any of the samples. Structures are presented in Figure 1.
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All analytes showed baseline separation with exception of the pair 3,4- and 4,5 dicaffeoylquinic
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acid. Peak assignments of CGAs have been made on the basis of structure diagnostic hierarchical 8 ACS Paragon Plus Environment
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keys previously developed,12-15 supported by means of their parent-ion high-resolution mass, UV
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spectra, and retention times relative to 5-CQA using validated methods in our laboratory.5 The
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base peak chromatogram of Stevia rebaudiana extract is shown in Figure 2. Within the
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chromatogram, CGAs and flavonoid glycosides elute between 8 and 25 minutes, whereas steviol
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glycosides elute at later retention times between 28 and 40 minutes.
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Four peaks were detected at m/z 353.1 and assigned using the hierarchial keys previously
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developed as well-known 3-CQA, 5-CQA, and 4-CQA and cis-5CQA.12 Three dicaffeoylquinic
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acid isomers were identified by their parent ion m/z 515.2 and were assigned as 3,5-diCQA, 3,4-
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diCQA, and 4,5-diCQA using the hierarchial key.13 Two further peaks present as minor
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components showed fragmentation patterns, similar to that of 4,5-diCQA, which are identified as
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cis-isomers of 4,5-diCQA.16 Tri-caffeoylquinic acids and caffeoylshikimates were present as
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minor compounds and their regiochemistry assigned using published tandem MS methods.14, 15
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A total of fifteen peaks in the chromatogram correspond to flavonoid glycosides with their
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characteristic fragmentation patterns in tandem MS showing neutral losses of sugar moieties of
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162 Da (- C6H10O5) followed by characteristic fragment spectra of the aglycones quercetin (m/z
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300), kaempferol (m/z 285), luteolin (m/z 285) and apigenin (m/z 269) in MS3 (see Table 1)
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(Figure 3). For example, three peaks were located with an m/z value of 447.1 (Figure 4)
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showing, after a neutral loss of 162 Da a base peak at m/z 285 in MS2. Further fragmentation in
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MS3 with the ion at 285.1 as a precursor ion revealed two fragment ions characteristic for
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kaempferol and one fragment ion characteristic for luteolin. Additional hydrolysis experiments
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followed by LC-MS analyses confirmed the presence of aglycones of kaempferol, quercetin,
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luteolin and apigenin by comparison of retention times, high resolution MS data and tandem MS
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data compared to reference substances in Stevia rebaudiana leaves. Therefore, we tentatively
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assigned the flavonoid glycosides as hexose conjugates of kaempferol, quercetin, luteolin and
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apigenin.
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Comparison of the fifteen flavonoid glycosides present in Stevia rebaudiana leaves with
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reference standards, either commercial or obtained through preparative HPLC purification in
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previous work, showed that all compounds, with the exception of rutin and naringenin, were not
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identical to the reference compounds available (all eight glucosides reported in dietary plants and
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two galactosides) as judged by their retention times and fragment spectra. We suggest that the
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flavonoids present in Stevia rebaudiana are presumably based on fructose, galactose or mannose.
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For other plants of the Asteraceae family it was shown by Harrison et al17 that poly-fructans are
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present and by the group of Goffner18 that additionally, galactomannans form the most abundant
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polymeric carbohydrate structures in this plant family.18 Hence it can be speculated that these C6-
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sugars are present in Stevia rebaudiana leaf flavonoids, for which no reference materials are
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available.
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Quantification of Chlorogenic acids and Flavonoids
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Quantitation was carried out using eight point calibration curves. Chlorogenic acids were
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quantified by LC-UV at 320 nm and by LC-MS using extracted ion chromatograms of the
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pseudomolecular ions at m/z 353.1 and 515.2 in negative ion mode using an ESI-TOF MS
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spectrometer. Additionally, flavonoids were quantified by LC-UV using kaempferol-7-glucoside
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and quercetin-3-glucoside as reference standards, resulting in relative values rather than absolute
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values for flavonoids. All values obtained are quoted in g/100g dried leaf material.
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Chlorogenic acid standard solutions were analyzed by LC-MS using the same chromatographic
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method as used for Stevia rebaudiana leaf extracts. Calibration curves for mono-caffeoyl
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derivatives, 3-CQA, 4-CQA and 5-CQA and for dicaffeoyl derivatives 3,4-diCQA, 3,5-diCQA
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and 4,5 diCQA, were obtained using extracted ion chromatograms (see Table 2). Pearson 10 ACS Paragon Plus Environment
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correlation coefficients of the calibration curves using LC-MS quantifications are given in Table
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2. All calibration curves were linear within the quantification range. Values obtained from LC-
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UV and LC-MS quantification gave the same absolute concentration values with an error of less
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than +/- 5% showing validation of the method. All quantitative CGA values for all 166 samples
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are given in the Supplementary Information. The quantitative values obtained for all chlorogenic
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acid derivatives were found to be a factor of three-to-five higher than values previously reported
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by our group.8 On occasions, the data showed a ten-fold increase of CGA concentrations. It must
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be concluded that the material previously investigated, obtained from commercial sources was of
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unknown age and origin. Fresh leaves of Stevia rebaudiana contain significant quantities of
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CGAs, much higher than previously determined. In terms of absolute quantities, Stevia
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rebaudiana shows, following green coffee beans and mate leaves the third highest concentration
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of CGAs amongst all dietary materials.
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The four flavonoid aglycones quercetin, kaempferol, luteolin and apigenin were quantified using
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a LC-UV method monitoring absorption at 280 nm for selected Stevia rebaudiana samples
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following hydrolysis of the sugar moiety in dilute acid. It is well established that the molar
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extinction coefficient of flavonoid glycosides varies only to a small degree if structural variation
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of the sugar moiety occurs.19,
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Supplementary Information. All flavonoid glycosides were quantified using a LC-MS method
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with quercetin-3-glucoside and kaempferol-7-glucoside as reference compounds, complementing
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the aglycone structure of the flavonoid glycosides.
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Analyses of data
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With the quantitation carried out we have obtained a unique data set of the phenolic metabolome
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of Stevia rebaudiana. This data set requires statistical evaluation allowing interesting
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observations and conclusions. We decided to address the following questions in this contribution.
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Quantitative values for the four glycones are given in the
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What is the statistical distribution of quantitative data? Little data is available in the literature that allows for a definite answer to this question.
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How do phenolic quantities vary with variation of origin, harvest and plant variety?
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Does the data set allow distinction between varieties or origin in a predictive manner by using quantitative phenol concentrations?
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Do quantities of a set of distinct secondary metabolites correlate with one another?
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Further questions addressing the influence of the phenolic metabolome on sensory
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properties or the influence of agricultural parameters on the phenolic metabolome are
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outside the scope of this contribution and will be commented on at a later stage.
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Statistical Spread of Data
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The distribution of the dataset is an essential step for examination of data in statistical analyses.
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The most frequent distribution of data is the Gaussian or normal distribution. A normal
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distribution can be easily characterized by observing its symmetrical bell shaped curve on a
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histogram (see Supp. Info., Figure S1). Skewness and Kurtosis values below one show also that
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the data is normally distributed. The Kolmogorov-Smirnov (KS) test was used for the analyses of
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data distribution. The significance value above 0.05 means the data is normally distributed.
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Each mono- and di-CQAs as well as total mono- and di-CQAs quantities obtained from 166
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Stevia rebaudiana samples showed normal distribution. The KS test result, mean values, standard
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deviations, skewness and kurtosis of the curve for each CGA is represented in Table 3. A
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histogram of 5-CQA is presented as an example in supplementary information. The observation
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of an almost perfect Gaussian distribution in all quantitative data came as a surprise. Normally,
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phenolic metabolites are assumed to act as plant defense compounds produced by the plant in
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various stress situations, in particular, stress induced by pathogens. Hence, a bimodial shaped
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distribution of CGA concentrations could be expected with two maxima, whereby the higher 12 ACS Paragon Plus Environment
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concentration maximum corresponds to compound production under stress. The experimental
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data clearly show this is not the case. It can be speculated that none of the 166 Stevia rebaudiana
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samples were under stress. A more reasonable scenario would suggest that CGA quantities right
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of the maximum of the Gaussian curve shifted to higher concentrations constitute a situation of a
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plant under stress, and hence, CGA concentrations are only gradually increased by the plant.
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Sample Variation
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Variation between varieties
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Seven defined botanical varieties of Stevia rebaudiana were cultivated and their phenolic profile
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was determined. Average values determined for the seven botanical varieties are presented in a
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radar plot in Figure 5. From the data, it can be seen that the average concentration of all
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monocaffeoylquinic acids remains rather constant over all seven varieties (2.123 - 2.686 g/100g),
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whereas a larger spread of data is observed for dicaffeoylquinic acids (1.484 – 2.432 g/100g).
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Varieties 5, 6, 7 and 3 show on average increased levels of chlorogenic acids compared to
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varieties 2 (Figure 5).
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Variation between origins
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Stevia rebaudiana cultivated in nine different locations within the EU and additionally samples
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from outside the EU (see Supplementary Information) were available for comparison. According
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to the literature, polyphenol concentrations are due to their physiological function as UV
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protection agents, which are a direct function of growth altitude and climatic conditions,
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particularly in sunshine hours. Accordingly, variations of chlorogenic acid concentrations
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between different origins should be expected. Indeed, the data reveal significant variations in
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average CGA concentrations varying from 3.090 -1.637 g/100g for total monocaffeoylquinic
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acids and 2.890 - 1.144 g/100g for dicaffeoylquinic acids (see Supplementary Information for
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average values of all origins). EU cultivated Stevia rebaudiana shows concentrations of CGAs 13 ACS Paragon Plus Environment
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sandwiched between extreme values at both ends observed in samples from outside the EU (e.g.
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highest for origin G samples with an average value of 2.890 g/100g dicaffeoylquinic acids and
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trial location L and E samples with a lowest average value of 1.448 g/100g and 1.144 g/100g
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respectively). A radar plot shown in Figure 6 was used to display variations between different
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origins.
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The data allow insight into variations between minimum values and maximum values of
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phenolics. Our data show that between minimum and maximum values encountered in plants
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from an individual harvest, an average factor of five to eight, depending on the compound in
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question is observed, indicating a large statistical spread of phenol concentrations..
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Principal component analyses (PCA)
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To allow differentiation between different Stevia rebaudiana varieties and geographic origins a
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principal component analyses (PCA) based on the LC-MS dataset of Stevia rebaudiana phenols
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was carried out. PCA analyses were carried out with an aim to distinguish EU cultivated samples
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from non-EU cultivated samples. For this purpose 20 EU and 20 non-EU samples were subjected
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to a PCA analyses. Score and loading plots are shown in Figure 7. From the score plot it can be
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seen that the samples fall in three groupings. Group A from South American samples can clearly
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be distinguished from all other samples based on their high diCQA content (from loading plot).
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A second group B contains exclusively European samples from the Uconor cooperative. The final
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group C contains both EU and non-EU samples e.g. from Turkey, Ukraine and India, which
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group together. The sample distinction information from the loading plot suggests that a
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combination of rebaudioside A concentrations and diCQA concentrations allows distinction here.
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A second PCA analyses was carried out to compare variations between different botanical
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varieties. For this purpose data from four different botanical varieties were chosen and a PCA
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analyses on the full LC-MS data set carried out. Score plot of PC1 versus PC2 shows little 14 ACS Paragon Plus Environment
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differentiation between sample varieties (Figure S2). However, when looking at higher order
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principle components, e.g., PC2 versus PC4, three of the varieties group in the score plot with
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two varieties grouping together in the same area of the plot. The loading plot reveals that the
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compounds responsible for the variations include dicaffeoylquinic acids along with rutin.
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Statistical evaluation of data
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From the obtained data, a series of statistical analyses was carried out. For each variety, origin or
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harvest, average values and standard deviations were determined. Additionally, the statistical
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pattern and type of statistical distribution of the data was analyzed for each subgroup. The
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correlation studies were performed by Pearson's correlation, with the significance value of p
