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- Prunella vulgaris L. seeds: a promising source of lipids, proteins, and original phenolic compounds presenting high antioxidant and anti-inflammatory activity
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Prunella vulgaris L. seeds: a promising source of lipids, proteins, and original phenolic compounds presenting high antioxidant and anti-inflammatory activity
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Les graines de Prunella vulgaris L. : une source prometteuse de lipides, protéines et composés phénoliques originaux présentant des activités antioxydante et anti-inflammatoire importantes
Description du sujet. Prunella vulgaris L. (Lamiaceae) est une plante herbacée comestible, utilisée depuis plusieurs siècles en Europe et en Asie comme tisane, aliment, complément alimentaire ou encore plante médicinale. Bien que la composition des parties aériennes ait été étudiée et soit déjà bien documentée, les graines de Prunella vulgaris n’ont jamais été étudiées.
Objectifs. L’objectif de ce travail était d’étudier la composition des graines de P. vulgaris afin d’en déterminer non seulement le potentiel nutritionnel (teneur en lipides, protéines, minéraux), mais aussi la présence de métabolites spéciaux et d’en déterminer les pouvoirs antioxydant et anti-inflammatoire.
Méthode. Les teneurs en protéines, lipides et minéraux des graines ont été déterminées. Les composés phénoliques ont été isolés, la détermination de leur structure a été réalisée par HR-MS et RMN à une et deux dimensions. Leurs activités biologiques ont ensuite été évaluées par différentes méthodes.
Résultats. L’huile contenue dans les graines de P. vulgaris est riche en omega-3 ; les graines possèdent un profil en acides aminés intéressant ainsi qu’une teneur élevée en polyphénols. Parmi ceux-ci, deux nouveaux composés ont pu être identifiés (dérivés de phénylpropane) et leur structure a été caractérisée. Ces deux composés, décrits pour la première fois dans la nature, ont été nommés acides amolsamic A&B. Ces deux acides amolsamic A&B, de même que les grains dans leur entièreté, ont un potentiel antioxydant et une activité anti-inflammatoire forte (modèles neutrophiles, MPO et HRP).
Conclusions. Ces résultats démontrent que les graines de P. vulgaris ont des effets santés prometteurs, faisant d’elles un candidat intéressant comme super aliment ou complément alimentaire.
Abstract
Description of the subject. Prunella vulgaris L. (Lamiaceae) is an edible herb used in Europe and Asia as herbal tea, food, dietary supplement or medicinal plant since several centuries. Although the composition and properties of the aerial parts are well documented in the literature, Prunella vulgaris seeds have never been investigated.
Objectives. The aim of this work was to characterize the composition of these seeds to assess not only their nutritional potential (protein, lipid and minerals content), but also their antioxidant and anti-inflammatory potential as well as their specialized metabolites composition.
Method. The protein, lipids and mineral content were determined. The phenolic compounds were isolated; elucidation of their structures was done by means of HR-MS and one- and two-dimensional NMR analysis. They were then evaluated for their biological activity, together with seed extracts.
Results. Omega-3 rich oil and an interesting amino acids profile were detected in the seeds as well as the presence of a high content of polyphenolic compounds, including two structurally new compounds (phenylpropane derivatives) which were isolated and structurally characterized. The two compounds described here for the first time, were named amolsamic acids A&B. The seeds and amolsamic acids showed an interesting antioxidant potential, and a strong anti-inflammatory activity on neutrophils, MPO and HRP models.
Conclusions. These findings highlight the real health promoting potential of P. vulgaris seeds and make them a good candidate as super-food or food supplement.
Table of content
Received 23 March 2021, accepted 14 December 2021, available online 23 December 2021
This article is distributed under the terms and conditions of the CC-BY License (http://creativecommons.org/licenses/by/4.0)
1. Introduction
1Prunella vulgaris L. (Lamiaceae) is a perennial herb from the Lamiaceae family originally distributed in temperate Europe and Asia which is now widespread in all temperate regions of the world, including Africa, America and Australia (Gu et al., 2013; Wang et al., 2019). Commonly named “self-heal” or “heal-all”, P. vulgaris is used in European traditional medicine since centuries. The whole plant, leaves or fruit spikes, are also commonly consumed as health-promoting food or herbal tea in China (Qu et al., 2017).
2In Europe, P. vulgaris is used for the treatment of sore throat, intestinal infections, diarrhea, as healing agent and anti-hemorrhagic (Huang et al., 2009; Chevallier, 2016) while in Asia, it is consumed as herbal tea for the treatment of health troubles such as migraine or fevers (Huang et al., 2009; Kalle & Sõukandal., 2012). In Europe, the plant is also sometimes eaten in its whole and it has been officially approved as dietary supplement in some countries like Belgium (Royal Decree from 29th of August, 1997, about plants in food supplements) and is evaluated at the European level (EFSA, 2011).
3Due to its numerous reported traditional medicinal uses and properties, the phytochemical composition and anti-oxidant activity of the aerial parts of P. vulgaris have been largely examined; rosmarinic acid, polysaccharides, pentacyclic triterpenes have been identified (Gu et al., 2013; Rasool & Ganai, 2013; Golembiovska, 2014; Wang et al., 2019). Although the composition and properties of the areal parts are well documented in the literature, to the best of our knowledge, P. vulgaris seeds have never been investigated for their proximate, phytochemical composition or potential bioactivities.
4Due to global interest for field border flowering strips in Europe (FBFS = portions of agricultural landscape reserved for herbaceous vegetation), the emergence of specialized farming practices dedicated towards the production of seeds from plants commonly grown in those strips has recently emerged (Uyttenbroeck et al., 2016). In Europe, P. vulgaris is one of the species commonly observed in those FBFS. In this context, considering the availability of P. vulgaris seeds in large amount, they potentially represent an interesting biomass for food supplements or the provision of bioactive molecules, that could be of great significance to the pharmaceutical market (Paul et al., 2015).
5Thus, the goal of this research was to characterize the lipid, protein and mineral contents, to identify the main phenolic metabolites, as well as the radical scavenging, cellular antioxidant and anti-inflammatory activities of P. vulgaris seeds, in order to assess the nutritional and health potential of these seeds.
2. Materials and methods
2.1. Plant material
6Two different batches of P. vulgaris seeds were purchased from ECOSEM, Belgium (batches 2014/089225 and 2018/089225). A third sample (plant and seeds) was collected in Couthuin, Belgium (3rd of July, 2018) by Thomas Braipson and botanically identified by Pr Michel Frédérich. A Voucher specimen was deposited and archived in the herbarium of the Pharmacognosy Department from the University of Liege with the number 2018-07-01.
2.2. Protein, lipids and mineral content determination
7Protein analysis. The nitrogen content was determined using the Dumas method (AOAC International, 2007); it was then multiplied by 6.25 to obtain the protein content. The amino acid profiles were established according to the method previously described by Paul et al. (2016).
8Lipid analysis. The total lipids were quantitatively extracted from the seeds according to Folch procedure, as described in Paul et al. (2016). The fatty acid profile was then determined by GC, as described by Paul et al. (2016). Gravimetric determination of lipid classes (neutral lipids [sterol ester, triacylglycerol, sterols, diacylglycerol and monoacylglycerols], free fatty acids and polar lipids) was performed after SPE fractionation using disposable aminopropyl cartridges (Mega Bond Elut [2 g], Agilent technologies, USA) according to Vaghela & Kilara (1995). The purity of all recovered fractions was confirmed using thin layer chromatography.
9Mineral analysis. The ash content was determined using the AOAC 942.05 method (2006) (AOAC International, 2007). The mineral composition was investigated by digesting the sample (500 mg) with aqua regia (5 ml). Calcium, Cu, Fe, Mg, Mn and Zn concentrations were analyzed using the Perkin Elmer AAS-800 atomic absorption spectrophotometer (Perkin Elmer, USA) while K and Na contents were analyzed on Perkin Elmer AAS-200 flame emission spectrophotometer (Perkin Elmer, USA) (Loukou et al., 2011).
10Cellulose, hemicellulose and lignin analysis. Cellulose, hemicellulose and lignin contents of the defatted biomass were investigated according to Goering & van Soest (1970).
2.3. Preparation of seed methanolic extract
11The seeds were ground using an analytical mill A-10 basic mill (IKA-Werke, Germany) to pass through a 1 mm mesh screen. Seed powders were then stored at - 20 °C, under vacuum to avoid degradation until analysis. To exclude the inference of lipids in further analyses, the seeds were defatted using n-hexane (10 ml n-hexane·g-1 seeds for 30 min under continuous stirring) before preparation of methanolic extract (3 x 10 ml methanol·g-1 defatted seeds for 30 min under continuous stirring). The methanolic extracts were then filtered and concentrated under reduced pressure to obtain defatted seed methanolic extract (DSME). DSME was kept at - 20 °C under vacuum until analysis.
2.4. Analysis of phenolic compounds: total phenolic content and phenolic profile determination
12The total phenolic content of the seeds was investigated using Folin Ciocalteu reagent, as described in European Pharmacopeia (EDQM, 2020). Defatted seed methanolic extract was analyzed using an Agilent 1,000 series chromatogram with UV-Diode array detector (Agilent Technologies, USA) fitted with a Hypersil ODS RP-18 column (Thermo Fisher Scientific, Belgium). Defatted seed methanolic extract solution (10 mg·ml-1 methanol) was filtered (0.45 µ membrane) and separated at 20 °C at a flow rate of 1 ml·min-1. The mobile phase consisted of solvent A (acetonitrile) and solvent B (0.05% trifluoroacetic acid) in gradient mode. Following gradient was used for the analysis: 0 min (0% A, 100% B), 1 min (3% A, 97% B), 45 min (40% A, 60% B), 55 min (40% A, 60% B), 56 min (60% A, 40% B), 66 min (60% A, 40% B), 67 min (0% A, 100% B) and 82 min (0% A, 100% B). The phenolic compounds were identified based on the comparison of retention times and UV spectra with internal spectral database and co-injection of references. Quantitative analysis of the identified compounds was performed with external calibration. The unidentified compounds were separated by preparative HPLC using Varian Prostar HPLC system with a UV-Diode Array Detector (Agilent Technologies, USA), and a 12 µm Lichrospher 100 RP-18 column (Merck Millipore, Belgium). Defatted seed methanolic extract (500 mg) was dissolved in 10 ml water/methanol solution (4:1 v/v) using ultrasound at 25 °C for 10 min. The raw extract was filtered (using 0.45 µ membrane) and injected into the preparative HPLC system. Mobile phase and gradient conditions were established according to upscaling equations. The separated fractions were evaporated under reduced pressure and identified using NMR and MS spectroscopy. The UV spectra were obtained on a methanol solution using a Kontron Uvikon Spectrophotometer. The IR spectra were recorded using a Spectrum 1,000 (Perkin Elmer, Waltham, MA, USA) FT-IR spectrometer with a DTGS 134 detector. NMR spectra were recorded in methanol-d4 with a Bruker Advance NEO 500 MHz spectrometer equipped with a cryoprobe and using standard Bruker experiments and TMS as the internal reference. Mass spectrometry (MS) was carried out using a micromass ESI-Q-TOF II instrument (Waters) using ESI-ionization in negative mode in the m/z range 100-1,500.
2.5. Radical scavenging, cellular antioxidant and anti-inflammatory activities
13Radical scavenging activity. The in vitro radical scavenging activity of the DSME was investigated using 2, 2-diphenyl-1-picryhydrazyl (DPPH) and 2,2-azino-bis (3-ethylbenzothiazoline)-6 sulphonic acid (ABTS) assays. The DPPH and ABTS assays were performed according to the method described respectively by Floegel et al. (2011) and Franck et al. (2013). These assays were performed at final concentrations: 1, 5, 15, 30 and 60 µg·ml-1 DSME. Gallic acid was used as the reference molecule, at final concentration of 1, 2.5 and 5 µg·ml-1 for DPPH; and 0.1, 0.5 and 1 µg·ml-1 for ABTS. Relative free radical scavenging activity of the sample, in comparison to DMSO control, was expressed as IC50 value.
14Cellular antioxidant activity on the oxidative response of activated neutrophils. The reactive oxygen species (ROS) produced by activated neutrophils were measured by lucigenin-enhanced chemiluminescence (CL) based on the method previously described by Benbarek et al. (1999) and slightly modified by Franck et al. (2005). The effect of DSME on the ROS production by activated neutrophils was investigated as previously described (Franck et al., 2013). DSME was prepared in DMSO and diluted at final concentrations of 0.1, 0.5, 1, 5 and 10 µg·ml-1. The control was performed with PMNs activated with PMA in the presence of PBS instead of the plant extract and was taken as 100% CL response compared to gallic acid, used as the reference molecule, at final concentrations of 0.175, 1.75 and 17.5 µg·ml-1). Relative inhibition of ROS production by tested sample versus DMSO control was expressed as IC50 value.
15In order to verify whether the antioxidant activity observed for DSME towards ROS produced by PMA-activated neutrophils was not due to their toxicity, cell viability (on 106 neutrophils; final concentration of DSME 5 and 10 µg·ml-1) was analyzed using classical Trypan blue exclusion assay.
16Anti-inflammatory activity on the oxidative response of myeloperoxidase enzyme. The equine myeloperoxidase (MPO) was isolated and purified using the method described by Franck et al. (2005). The anti-inflammatory effect of DSME on the MPO activity was measured using two techniques: Direct response & Indirect response using Specific Immuno-Extraction Followed by Enzyme Detection (SIEFED) (Franck et al., 2005). In both assays production of resorufin from Amplex red was analyzed at 37 °C for 30 min using a Fluoroskan Ascent 96 plate reader. These assays were performed at final concentrations of 1, 5, 10 and 25 µg·ml-1 DSME. Gallic acid was used as reference compound (at final concentrations of 0.175, 1.75 and 17.5 µg·ml-1). Relative activity of sample in comparison to DMSO control was expressed as IC50 value.
17Horseradish peroxidase (HRP) catalyzed oxidation. The modulatory activity of DSME on the horseradish peroxidase (HRP)/H2O2 oxidation response was measured using L012 probe (luminol analogue) (Wako Chemicals, Neuss, Germany). Briefly, 2 µl of DSME in DMSO solution was suspended with 153 µl PBS (pH 7.4), 5 µl HRP solution (25 µg·ml-1), 20 µl L012 solution (1 µM) and 20 µl H202 (1 mM). This was immediately followed by measurement of fluorescence using Fluoroskan Ascent 96 plate reader for 30 min at 37 °C. The assay was performed at final concentrations: 1, 10, 20, 40 and 80 µg·ml-1 DSME. Gallic acid was used as the reference molecule (at final concentrations of 0.1, 1 and 10 µg·ml-1). Relative activity of sample in comparison to DMSO control was expressed as IC50 value.
2.6. Statistical analysis
18Results are expressed as mean ± standard deviation. All the investigations realized in this study were performed in triplicate (besides total phenolic content and amino acid profile, which were performed in duplicate). The IC50 values of DPPH radical scavenging activity were calculated using GraphPad Prism 6 software. Statistical difference between IC50 values were analyzed by one-way ANOVA with Fischer Least Significance Difference method on Minitab 17 software (at 95% confidence level).
3. Results
3.1. Proximate composition of P. vulgaris seeds
19The protein content of P. vulgaris seeds was 16.92 ± 1.23% on dry basis. The total lipid content of P. vulgaris seeds is 16.12 ± 0.17% on dry basis. The main lipid constituents (classes) and fatty acid composition and the amino acids profile are reported in table 1.
20The chemical score according to FAO/WHO (WHO, 2007) reference pattern is shown in table 2.
21Ash content of P. vulgaris seeds is 4.89 ± 0.05% on dry weight and concentration of the main individual minerals are reported in table 3, as well as the lignocellulosic components content.
3.2. Phenolic composition
22The seeds yielded 2.31 ± 0.04% DSME on dry basis. The total phenolic content of P. vulgaris seeds is 8.38 ± 0.50 mg·g-1 pyrogallol equivalents (dry basis). The phenolic profile obtained by HPLC is presented in figure 1.
Figure 1. HPLC profile of Prunella vulgaris defatted seeds methanolic extract — Profil HPLC de l’extrait méthanolique des graines dégraissées de Prunella vulgaris.
23Two compounds: caffeic acid (20.99 min) and rosmarinic acid (33.1 min) were unambiguously identified and their proportions were of 1.85 ± 0.05 and 0.03 ± 0.00% respectively. The three other major compounds were separated using preparative HPLC to give salviaflaside (rosmarinic acid O-glycoside) (RT = 29.2 min). Two new compounds (corresponding to peaks at 40.2 and 41.6 min) were then isolated. They were named amolsamic acid A (1) and B (2), respectively. The structures of these compounds (Figure 2) were established according to their UV, IR, ESI-MS and NMR spectral data. 1H and 13C NMR data are presented in table 4 and in figure 3a-d.
Figure 2. Structures of amolsamic acid A and amolsamic acid B — Structures de l’acide amolsamique A et de l’acide amolsamique B.
Figure 3a. Proton NMR spectrum of Amolsamic acid A (1) (500 MHz) — Spectre de RMN des protons de l’acide amolsamique A (1) (500 MHz).
Figure 3b. Carbon NMR spectrum of Amolsamic acid A (1) (125 MHz) — Spectre de RMN du carbone de l’acide amolsamique A (1) (125 MHz).
Figure 3c. 1H-NMR spectrum of Amolsamic acid B (2) — Spectre 1H-RMN de l’acide amolsamique B (2).
Figure 3d. 13C NMR spectrum of Amolsamic acid B (2) — Spectre RMN 13C de l’acide amolsamique B (2).
24Compound 1 was obtained as a white amorphous powder. ESI-MS spectra in the negative ion mode showed a [M-H]- peak at m/z 715.1306 (corresponding to C36H28O16) and indicating 23 degrees of insaturation. 13C-NMR data showed the occurrence of 36 carbons, 2 CH2, 15 CH and 19 C. Compound 2 was also obtained as a white amorphous powder. ESI-MS spectra in the negative ion mode showed a [M-H]- peak at m/z 1071.1840 (corresponding to C54H40O24) and indicating 35 degrees of insaturation. 13C-NMR data showed the presence of 54 carbons, 3 CH2, 21 CH and 30 C.
3.3. Free radical scavenging activity
25The results obtained for DPPH and ABTS antioxidant activities for the P. vulgaris DSME and gallic acid are presented in table 5 (radical scavenging activities).
3.4. Cellular anti-oxidant activity on the oxidative response of activated neutrophils
26Cellular antioxidant activities as a function of concentration for the P. vulgaris DSME and gallic acid are presented in figure 4a-c.
Figure 4. Anti-inflammatory activity of Prunella vulgaris seed extract and gallic acid — Activité anti-inflammatoire de l’extrait de graines de Prunella vulgaris et de l’acide gallique.
a. effect of P. vulgaris seed extract and reference gallic acid in modulating ROS production — effet de l’extrait de graines de P. vulgaris et de l’acide gallique de référence dans la modulation de la production de ROS; b. effect of P. vulgaris seed extract and reference molecule (gallic acid) in modulating MPO activity using direct and SIEFED assay — effet de l’extrait de graines de P. vulgaris et de la molécule de référence (acide gallique) dans la modulation de l’activité MPO à l’aide de l’essai direct et de l’essai SIEFED; c. effect of P. vulgaris seed extract and reference molecule (gallic acid) in modulating Horseradish peroxide activity — effet d’un extrait de graines de P. vulgaris et d’une molécule de référence (acide gallique) sur la modulation de l’activité du peroxyde de raifort.
3.5. Anti-inflammatory activity on the oxidative response of myeloperoxidase enzyme
27The activity obtained using the direct and SIEFED assays is shown in figure 4b. Similar concentrations were used in both the assays to estimate the comparative activity. In both direct and SIEFED assays, a dose dependent increase in MPO inhibition activity was observed.
3.6. Horseradish peroxidase (HRP)‐catalyzed oxidation
28As for neutrophil and MPO models, a dose-dependent inhibitory activity of L012 oxidation catalyzed by HRP/H2O2 was observed in the presence of increasing concentrations of DSME (Figure 4c). An IC50 of 10.7 and 0.9 µg·ml-1 was obtained for P. vulgaris DSME and gallic acid respectively.
4. Discussion
29The aim of this work was to characterize the composition of P. vulgaris seeds to assess not only their nutritional potential (protein, lipid and minerals content), but also their antioxidant and anti-inflammatory properties as well as their specialized metabolites composition.
30Regarding the gross composition, P. vulgaris has an interesting protein content, which resembles the protein content of flaxseed (18%, non-dried basis) or chia seeds (16-26%, non-dried basis) (Melo et al., 2019), seeds which are used as super food for human consumption in Europe. The total protein content of a material is important; however, from a nutritional point of view the nutritional quality of proteins is mainly dependent on their amino acid composition. Prunella vulgaris amino acids profile is obviously interesting from a nutritional point of view as P. vulgaris seeds contain high amount of essential amino acids (EAA). According to the recommendations made by the Belgian CSS (Conseil Supérieur de la Santé – Health High Council) in 2016, 100 g of P. vulgaris seeds are enough to cover around 50% of the daily recommended intake of EAA for an adult of 70 kg (SPF Santé Publique, 2016). The lipid content of P. vulgaris seeds resembles the lipid content of some commercially used lipid sources such as soy bean (18-20%) or rice bran (18-24%) (Gunstone et al., 1994). Prunella vulgaris seed oil contain comparable level (72-73%) of PUFA to chia seeds (80%) or Cannabis sativa seeds (71%) (Montserrat-de-la-Paz et al., 2014). Interestingly, two important essential FA, α-linolenic acid (ALA) (> 55%) and linoleic acid (LNA) (> 17%), as well as oleic acid (OA) (> 13%) are the major constituents of P. vulgaris lipids. The FA profile of P. vulgaris oil is better than the one of rapeseed oil which is now recommended in food nutrition to optimize the omega 6/3 ratio. According to the recommendations made by the Belgian CSS in 2016, MUFA+PUFA should represent at least two third of the total daily ingested lipids. Consuming P. vulgaris seeds in the diet could help to reach this target. Prunella vulgaris seed oil contains α-linolenic acid levels similar to the oil from chia seeds and flaxseeds, which are two commercially used omega-3 fatty acid food supplements. Linolenic acid content of chia seeds and flaxseeds is 52-63% and 35-60%, respectively (Gunstone, 2011).
31Regarding the total phenolic content, a comparison with data reported by Sárosi et al. (2011) indicates that P. vulgaris seeds offer a highly better source of phenolics when compared to the aerial parts that possess a total phenolic content ranging between 0.28 and 0.70 mg·g-1 gallic acid equivalents (dry basis).
32The identification of the phenolic compounds revealed the presence of caffeic acid, rosmarinic acid and salviaflaside (rosmarinic acid O-glycoside) (RT = 29.2 min), this compound was also reported as present in aerial parts, it was identified thanks to the comparison of MS and NMR data with literature (Tezuka et al., 1998). Besides those known compounds, the presence of two unknown compounds was also detected. The molecular formula of the new Compound 1, named amolsamic acid A, corresponded to two rosmarinic acid moieties. The NMR data of compound 1 were very similar to those of schizotenuin A (Matsuta et al., 1996), but presented differences in the NMR spectra at the junction point between the two rosmarinic moieties. Schizotenuin A presented a junction between the two caffeic acid moieties, when compound 1 presented a junction between one caffeoyl moiety and one dihydrocaffeoyl moiety. The junctions C-9 – O – C-18 and C-8’ – C-15 were confirmed by HMBC correlations between H-18 and C-9; H-16 and C-8’, C17. Compared to compound 1, MS data for compound 2 (amolsamic acid B) indicated three rosmarinic acid moieties. NMR data of compound 2 were relatively similar to compound 1, but 13C-NMR data showed the presence of 54 carbons, 3 CH2, 21 CH and 30 C. Comparing compounds 1 and 2, most of the 1H and 13C signals of 1 were also present in the spectra of 2, at the exception of the signal for H-15, this lacking signal indicating the junction of the third rosmarinic moiety at this position. The junction C-8’ – C-15’ and the presence of a furane ring at C-14’ – C-15’ was confirmed by HMBC correlations between H-16’ and C-8’’.
33These amolsamic acids are neolignan-type compounds, found for the first time in the nature. Amolsamic acid A is then a structural isomer of schizotenuin A, a benzofuran lignan, which was isolated from Schizonepeta tenuifolia, a species close to P. vulgaris, also belonging to Lamiaceae family (Matsuta et al., 1996). Amolsamic acid B is a trimeric derivative of rosmarinic acid. It is only the second time that a trimeric derivative of rosmarinic acid is evidenced, after two trimers isolated from Celastrus hindsii, that does not present double bonds at C-7 – C-8 position on the benzofuran rings (Ly et al., 2006).
34Phenolic compounds with multiple phenolic groups and catechol moieties are well-known to possess a high anti-oxidant activity (Bhatt et al., 2013). Rosmarinic acid contain four phenolic hydrogens and two catechol moieties; amolsamic acid A (1) contain seven phenolic hydrogens and three catechol moieties; and amolsamic acid B (2) contain 10 phenolic hydrogens and four catechol moieties. With the presence of all these compounds, P. vulgaris DSME can potentially exhibit high antioxidant activity. In order to confirm this hypothesis, we investigated the antioxidant activity of P. vulgaris DSME using a wide range of techniques.
35Phenolic compounds in food scavenge free radicals using three methods: hydrogen atom transfer, electron-proton transfer and/or sequential proton loss-electron transfer (Chen et al., 2015). DPPH radical scavenging activity denotes the ability of the sample to donate hydrogen atoms and stabilize DPPH free radical, while ABTS radical scavenging activity represents the ability of sample to donate electrons.
36A dose dependent increase in DPPH and ABTS antioxidant activities with increasing concentration was observed for the P. vulgaris DSME and gallic acid. Prunella vulgaris DSME exhibited high DPPH (IC50: 21.1 µg·ml-1) and ABTS (IC50: 13.7 µg·ml-1) radical scavenging activities. Previous experimentations in the literature on the methanolic extract of flowering stalks from P. vulgaris revealed a DPPH inhibition activity of 35.4% and a ABTS inhibition activity of 61.7% at the concentration of 100 µg·ml-1 (Seo et al., 2010). Outcomes of the present study show that P. vulgaris DSME is much more active than the extract obtained from flowering stalks. Rosmarinic acid and rutin form the major components of P. vulgaris aerial parts (Golembiovska, 2014). Rutin exhibits a relatively weak radical scavenging activity (Sroka, 2005). On the other hand, P. vulgaris seeds contain amolsamic acid A, amolsamic acid B, salviaflaside and rosmarinic acid as the major phenolic components. As pure compounds, compared to the crude extract, rosmarinic acid and amolsamic acid A presented the strongest antioxidant activity (Table 5). The presence of the benzofuran neolignans (amolsamic acids A and B) with multiple phenolic hydrogens and catechol moieties could be one of the reasons for this high free radical scavenging activity. In order to establish a better understanding of the PV- DSME antioxidant behavior and exploring the possibilities of using it as functional food, we evaluated its cellular antioxidant and anti-inflammatory activities.
37Neutrophils are white blood cells, which are primarily involved in the defense mechanism of the human body. They kill pathogenic microorganisms by phagocytosis and production of reactive oxygen species (ROS). In the present study we used PMA to activate NADPH oxidase (by activation of protein kinase C) in neutrophils which results in ROS production. This ROS production is coupled with lucigenin chemiluminescence (lucigenin cation radical reacts with superoxide anion to emit light). A dose dependent increase in cellular antioxidant activities with increasing concentration was observed for the P. vulgaris DSME and gallic acid (see figure 4a). At very low concentrations (below 1 µg·ml-1) DSME shows a pro-oxidant effect. However, by increasing the concentration (above 1 µg·ml-1) a very strong superoxide anion quenching activity can be observed. Surprisingly, P. vulgaris DSME exhibit a lower IC50 (3.7 µg·ml-1) even when compared with gallic acid (6.9 µg·ml-1) which is considered to be a very strong antioxidant. The strong activity of P. vulgaris DSME possibly arises from to the presence of amolsamic acid A and B. These phenolic acids contain multiple phenolic hydrogens, which react with the superoxide anion radical resulting in its deactivation. It could be possible that cytotoxicity of seed extracts towards neutrophils is responsible for this cellular activity. To infirm this, we performed a cytotoxicity assay, and found cell viability > 98% for DMSO control, DSME 5 µg·ml-1 and DSME 10 µg·ml-1 in the test conditions. This confirms that the DSME is not toxic towards neutrophils. This indicates that consumption of P. vulgaris DSME (or whole seeds) could reduce the oxidative damage resulting from the neutrophil activity.
38The anti-inflammatory behavior of the P. vulgaris seed extract was also characterized by its ability to modulate the activity of MPO enzyme. MPO is a peroxidase enzyme, which is secreted by neutrophils as a part of the host defense mechanism. The ability of seed extract to modulate the activity of MPO was investigated using two assays: a direct assay and SIEFED assay (Figure 4b). Similar concentrations were used in both the assays to estimate the comparative activity. In both direct and SIEFED assays, a dose dependent increase in MPO inhibition activity was observed. In direct assay, at 1 µg·ml-1 (lowest concentration used), P. vulgaris DSME showed a pro-oxidant effect, however with increasing concentration, a strong MPO deactivation activity was observed. Higher activity of P. vulgaris DSME was observed in SIEFED assay (IC50 1.1 µg·ml-1) when compared with direct assay (IC50 5.1 µg·ml-1). During the SIEFED assay, MPO enzyme (active or deactivated by phenolic compounds) is captured by the polyclonal antibodies and the rest solution is washed away. In this way the side reaction of free polyphenols and other compounds with the MPO substrate can be excluded and a true activity is obtained (Franck et al., 2005). The possible role of amolsamic acids A and B as electron donor for reduction of MPO or scavenging of ROS produced by MPO could explain the high activity of P. vulgaris DSME. This data show that components of P. vulgaris DSME can effectively bind with MPO or scavenge the harmful products resulting from their activity.
39To complement the results obtained using neutrophil and MPO models, we also tested the ability of DSME to modify the oxidative response of the HRP/H2O2 system. As for neutrophil and MPO models, a similar dose-dependent inhibitory activity of L012 oxidation catalyzed by HRP/H2O2 was observed in the presence of increasing concentrations of DSME (Figure 4c). The strong HRP enzyme modulation activity of the seed extract could be attributed to the presence of a strong hydrogen donor such as amolsamic acids A or B. The antioxidant and anti-inflammatory activity results obtained using all the three models (neutrophils, MPO and HRP), indicate that consumption of P. vulgaris DSME (or whole seeds) can potentially prevent/reduce the inflammatory damage of body tissues resulting from some oxidative reactions.
5. Conclusions
40In an attempt to assess the nutritional potential of P. vulgaris seeds, their protein, lipid and minerals contents were determined. An omega-3 rich oil was detected, an interesting amino acids profile, as well as the presence of two new polyphenolic compounds - amolsamic A&B - described herein for the first time. The polar extract of the seed as well as the two new compounds exhibited strong antioxidant and peroxidase inhibition activities, both on different biochemical and cellular models. Concerning the nutritional aspects, with 17% proteins (on dry weight) and an interesting amino acid profile, P. vulgaris seeds could be used in food formulations. Moreover, P. vulgaris seeds are an excellent source of fat, particularly rich in polyunsaturated fatty acids such as α-linolenic (55%) and linoleic (16%) acids. Due to this interesting FA profile, P. vulgaris seeds could be used for omega-3 fatty acid supplementation in diet. Furthermore, the seeds showed an interesting antioxidant potential with a better activity in some models than the reference compound gallic acid, and a strong anti-inflammatory activity on neutrophils, MPO and HRP models. All these findings highlight the real health promoting potential of P. vulgaris seeds, if used as food or food supplement.
List of abbreviations
41ABTS : 2,2-azinobis (3-ethylbenzothiazoline)-6 sulphonic acid
42CL : chemiluminescence
43DAG : diacylglycerol
44DMSO : imethyl Sulfoxide
45DSME : Defatted Seed Methanolic Extract
46DPPH : 2,2-diphenyl-1-picryhydrazyl
47EAA : Essential Amino Acids
48ESI : Electrospray Ionisation
49FA : Fatty Acid
50FBFS : Field Border Flowering Strips
51FFA : Free Fatty Acid
52GA : Gallic Acid
53GC : Gas Chromatography
54HPLC : High Performance Liquid Chromatography
55HR-MS : High-Resolution Mass Spectrometry
56HRP : Horseradish Peroxidase
57IC50 : Half Maximal Inhibitory Concentration
58MAG : Monoacylglycerol
59MPO : Myeloperoxidase
60MS : Mass Spectrometry
61MUFA : Monounsaturated Fatty Acids
62NADPH : Nicotinamide Adenine Dinucleotide Phosphate
63NEA : Non-Essential Amino Acids
64NMR : Nuclear Magnetic Resonance Spectroscopy
65PBS : Phosphate-Buffered Saline
66PMA : Phorbol Myristate Acetate
67PMN : Polymorphonuclear cells
68PUFA : Polyunsaturated Fatty Acids
69PV : Prunella vulgaris seed extract
70ROS : Reactive Oxygen Species
71SIEFED : Specific Immuno-Extraction Followed by Enzyme Detection
72SPE : Solid Phase Extraction
73TAG : Triacylglycerol
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