Bioactive Compound Profiling and Nutritional Composition of Three Species from the Amaranthaceae Family †
by
, , , , , , , , , and
Bernabe Nuñez-Estevez
1,2, 
Tiane C. Finimundy
2
,
Maria Carpena
1,
Marta Barral-Martinez
1
,
Ricardo Calhelha
2,
Tânia C. S. P. Pires
2,
Paz Otero
1,
Pascual Garcia-Perez
1,
Jesus Simal-Gandara
1
,
Isabel C. F. R. Ferreira
2
,
Miguel A. Prieto
1,2,*
and
Lillian Barros
2,* 1
Nutrition and Bromatology Group, Faculty of Food Science and Technology, Ourense Campus, University of Vigo, E32004 Ourense, Spain
2
Centro de Investigação de Montanha (CIMO), Instituto Politécnico de Bragança, Campus de Santa Apolónia, 5300-253 Bragança, Portugal
*
Authors to whom correspondence should be addressed.
†
Presented at the 1st International Electronic Conference on Chemical Sensors and Analytical Chemistry, 1–15 July 2021; Available online: https://csac2021.sciforum.net/ .
Chem. Proc. 2021, 5(1), 20; https://doi.org/10.3390/CSAC2021-10563
Published: 1 July 2021
(This article belongs to the Proceedings of The 1st International Electronic Conference on Chemical Sensors and Analytical Chemistry)
Abstract
:In this work, the chemical and nutritional composition of three Amaranthaceae species (Alternanthera sessilis, Dicliptera chinensis, and Dysphania ambrosioides) was studied. The results showed a differential flavonoid content in the three species: A. sessilis and D. ambrosioides showed similar flavonoid contents (15.1 ± 0.6 and 15.1 ± 0.1 mg/g extract, respectively), followed by D. chinensis (11.4 ± 0.1 mg/g extract). On the other hand, the nutritional results showed a high protein content in all species (16.9–13.9 ± 0.1 g/100 g dw) and revealed the presence of organic acids, such as oxalic and succinic acid. Therefore, bioactive compounds, together with protein and organic acids, could be of great value to the food industry.
1. Introduction
Several plant species have played an important role in traditional medicine worldwide, as humans have been using plants as a natural remedy for a multitude of diseases for 60,000 years [1]. In particular, the plants from Amaranthaceae family biosynthesize several bioactive compounds with beneficial biological activities, including essential oils, betalains, terpenoids, and phenolic compounds [2]. Different phytochemical studies have verified the different biological activities associated with the plant extracts belonging to this family, such as antioxidant, antidiabetic, antitumor, antibacterial, anti-inflammatory, among others [3].
Specially, three Amaranthaceae species, namely: Alternanthera sessilis (L.) R.Br. ex Dc, Dicliptera chinensis (L.) Juss. and Dysphania ambrosioides (L.) Mosyakin and Clemants. These species have been little explored in terms of their phytochemical valorization. A. sessillis has been used in traditional Malaysian medicine, both as an infusion and as food, while in China, its leaves have even been used for the treatment of eye and skin diseases, snake bites, and wound healing [4]. D. chinensis has a major distribution in southern China, Bangladesh, northern India, and Vietnam [5], where it was traditionally used with detoxifying and diuretic purposes, thanks to the production of organic acids, flavonoids, terpenoids, steroids, and polysaccharides [6]. Finally, D. ambrosioides, distributed throughout South America, is known to be used in traditional medicine as a remedy for parasitic diseases, and it is still currently used to treat parasitosis because of the presence of ascaridol [7].
Due to the health-enhancing potential attributed to Amaranthaceae species, in this work the nutritional characterization and chemical composition, in terms of phenolic compounds, will be carried out. As a result, this research could be considered as the starting point for a more targeted search for bioactive compounds [8] biosynthesized by these underexplored plant species.
2. Materials and Methods
2.1. Plant Material and Nutritional and Chemical Characterization
The samples proceeding from the Amaranthaceae species involved in this work, A. sessilis, D. chinensis, and D. ambrosioides, were thoroughly washed, air-dried, crushed, and sieved to obtain plant homogenates, which were stored at −80 °C until use.
The nutritional characterization (ashes, proteins, lipids, and carbohydrates, as well as energy) of the three plants was carried out following the methodology adapted previously [9]. The determinations were carried out by duplicate, and results were expressed in terms of percentage of composition for ashes, proteins, lipids, and carbohydrates, whereas energy was expressed as the mean ± standard deviation (SD) in kcal/100 g dry weight (dw).
The chemical composition (total sugars, fatty acids, and organic acids) was evaluated following the methodology also described by Barros et al. (2013) [9]. The determinations were performed in duplicate, and the results were expressed as the mean ± SD in g/100 g dw for total sugars and organic acids composition, whereas fatty acids were expressed as the relative percentage of saturated fatty acids (SFAs), monounsaturated fatty acids (MUFAs), and polyunsaturated fatty acids (PUFAs).
2.2. Sample Extraction and the Determination of Phenolic Compounds
For the determination of phenolic compounds, 1 g of each sample was macerated using 50 mL of ethanol/water (80:20 v/v) as solvent. This mixture was stirred at room temperature for 1 h and then filtered. This process was repeated twice, and extracts were collected and concentrated at 40 °C in a rotary evaporator, to remove the alcoholic fraction. The aqueous phase was frozen and freeze-dried. For the identification of phenolic compounds, a Dionex Ultimate 3000 UPLC system (Thermo Scientific, San Jose, CA, USA) was used, following a previous methodology [10]. The determination was performed by a diode array detector (DAD) and mass spectrometry (MS) (LTQ XL mass spectrometer, Thermo Finnigan, San Jose, CA, USA) working in negative mode. Once identified and quantified, compounds were grouped by their parental skeleton, being expressed as luteolin derivatives (LD), apigenin derivatives (AD), kaempferol derivatives (KD), quercetin derivatives (QD), and isorhamnetin derivatives (ID), in mg/g dw.
3. Results and Discussion
3.1. Nutritional Characterization
The results for the nutritional composition of Amaranthaceae plants are shown in Figure 1. The inorganic content of all plants, represented by the ashes, showed similar values, being higher than those of other plants of the same family from the genus Amaranthum [11] For proteins, D. chinensis (16.8 g/100 g dw) and A. sessilis (16.1 g/100 g dw) show similar values, higher than those of D. ambrosioides (13.9 g/100 g dw). These values are comparable to other species such as Chenopodium quinoa (quinoa), and they were also higher than other cereals, such as wheat, maize, or rice [12] With respect to lipids, the values for A. sessilis (0.74 g/100 g dw) were very low compared with the other species, which ranged between 1.1–1.8 g/100 g dw, being comparable to the lipid content of fruits and vegetables [12]. Regarding the carbohydrate content, the results were also very similar between the three species: 68.8 g/100 g dw for D. chinensis, 73.2 g/100 g dw for A. sessilis, and 71.5 g/100 g dw for D. ambrosioides, being in accordance with the carbohydrate contents of C. quinoa and other cereals, as well as other foods, such as chocolate, flour or bread. [12] Finally, the energy value did not vary much either, ranging from 350–365 kcal/100 g dw with A. sessilis being the species with the highest energy intake.
3.2. Chemical Characterization
The results for the chemical characterization of Amarathaceae species, in terms of total sugars, organic acids, and fatty acids contents are shown in Figure 2. The results for free sugars were, in decreasing order, 6.33 g/100 g dw for D. chinensis, 4.13 g/100 g dw for A. sessilis, and 0.34 g/100 g dw for D. ambrosioides. In this case, A. sessilis has the most similar content to that estimated for C. quinoa (2–3 g/100 g dw) [12].
Organic acids were detected in all three plant species studied, with a total content of ~9.13 g/100 g dw for D. chinensis, 8.43 g/100 g dw for A. sessilis, and 5.43 g/100 g dw for D. ambrosioides. Oxalic acid stood out as the organic acid present in the highest concentrations in all species, especially in the case of A. sessilis (data not shown). This acid is associated with reduced dietary Ca2+ availability and various kidney diseases [13]. Succinic acid and fumaric acid were also detected in D. chinensis, although in lower proportions. Both acids are in high demand by the food, cosmetic and pharmaceutical industries [14]. In addition, in the case of C. quinoa, previous data showed the presence of oxalic, citric and fumaric acid [15], revealing a similar profile for this functional food in terms of organic acids content.
Concerning the relative abundance of fatty acids in Amaranthaceae plants (pie charts in Figure 2), SFAs, MUFAs, and PUFAs were detected in these species. According to the data obtained, the plant with the highest amount of SFA was D. ambrosioides with 73.1% of the total fatty acids (Figure 2A), followed by A. sessilis with 70.2% and D. chinensis with 47.4%. As for the MUFA, all plants exhibited very similar values between them, ranging 8.23–11.8%. Finally, the results for PUFAs showed that D. chinensis had the highest abundance with 44.4% (Figure 2B), while D. ambrosioides and A. sessilis presented a similar abundance (19.8% and 15.1%, respectively). According to the data, the most abundant fatty acid in the three species was hexadecanoic acid, with the range of abundance in the percentage of total fatty acids in the three plants being 32–40%. A previous study identified the fatty acids of A. sessilis, in which the second most abundant fatty acid was hexadecanoic acid [16]. Regarding the high content in PUFAs for D. chinensis, and due to the beneficial properties associated with these bioactive compounds as antioxidant and cardioprotective agents, it is suggested that this species presents the healthiest chemical profile.
3.3. The Determination of Phenolic Compounds
The phenolic profiling of hydroethanolic extracts of Amaranthaceae plants was performed by UPLC-DAD-ESI/MS, revealing that flavonoids were the most abundant family of phenolic compounds in these species. The results for the determination of phenolic compounds are shown in Figure 3. In the case of A. sessilis extracts, luteolin derivatives (LD) were the most abundant compounds, with concentrations of 9.7 mg/g extract, with luteolin-8-C-(rhamnosyl)ketodeoxyhexoside as the most prevalent derivative (Figure 3A). To a lesser extent, apigenin derivatives (AD), kaempferol derivatives (KD), and quercetin derivatives (QD) were also reported (<1.8 mg/g extract) (Figure 3A). This plant has two varieties distinguished by their colors, red and green, and previous studies have shown that the red variety has a better nutritional composition, a higher content of phenolic compounds, and a greater antioxidant capacity [12]. Thus, the phenolic composition of A. sessilis has been seen to be affected by the variety employed.
With respect to D. chinensis, the extracts essentially contained different ADs, accounting for 10.82 mg/g extract (Figure 3B), being apigenin 6-C-glucoside-8-C-arabinoside the most prevalent compound. This is the first time, to the best of our knowledge, that the phenolic profiling of D. chinensis is determined, being spotted as a potential natural source of apigenin, largely characterized as a bioactive compound [17].
Finally, the results for D. ambrosioides (Figure 3C) showed that this was the only species presenting isorhamnetin derivatives (ID), which were the most abundant compounds in the hydroethanolic extracts (7.58 mg/g extract), and isorhamnetin-3-O-rutinoside were quantified as the main phenolic compound. Additionally, IDs, LDs, KDs, and QDs were also identified in this species in lower concentrations, as well as a lack of ADs (Figure 3C). In previous studies on D. ambrosioides, the highest concentration of phenolic compounds extracted was obtained by methanolic extracts, with 87.7 ± 1.4 µg of gallic acid equivalents/mg extract and 57 ± 1.4 µg quercetin equivalents/mg extract. Moreover, the same authors identified quercetin as the most abundant phenolic compound on D. ambrosioides [18], which is in accordance with our results, since quercetin-O-rhamnosyl-pentoside was the second most abundant compound in the hydroethanolic extracts. This suggests a critical role of solvent on the extraction of phenolic compounds from Amaranthaceae plants.
4. Conclusions
In this work, the determination of nutritional and chemical characterization, as well as the phenolic profiling of three Amaranthaceae species largely used in traditional medicine was developed. In this regard, similar chemical profiles were obtained for all species, with comparable inorganic, protein, lipid, and carbohydrate contents. The results on fatty acid composition revealed that D. chinensis showed the healthier profile with a high proportion of PUFAs. Finally, the determination of phenolic compounds suggested a species-dependent biosynthesis of these compounds, with luteolin derivatives, apigenin derivatives, and isorhamnetin derivatives presenting as the most prevalent phytoconstituents on A. sessilis, D. chinensis, and D. ambrosioides, respectively. Overall, our results shed light on the characterization of these species from a nutritional point of view and suggested that Amaranthaceae species can be considered as sources of bioactive compounds to be applied in the food, cosmetic, and pharmacological industries.
Supplementary Materials
The following are available online at https://www.mdpi.com/article/10.3390/CSAC2021-10563/s1.
Author Contributions
Conceptualization, methodology, software validation, formal analysis, investigation, resources, data curation, writing—original draft preparation, writing—review and editing, visualization, supervision B.N.-E., T.C.F., M.C., M.B.-M., R.C., T.C.S.P.P., P.O., P.G.-P., J.S.-G., I.C.F.R.F., M.A.P. and L.B. All authors have read and agreed to the published version of the manuscript.
Funding
By EcoChestnut Project (Erasmus+ KA202) that supports the work of B.N.-E.; the program Grupos de Referencia Competitiva (GRUPO AA1-GRC 2018) that supports the work of M.B.-M.; Authors are grateful to the Ibero-American Program on Science and Technology (CYTED—AQUA-CIBUS, P317RT0003), to the Bio-Based Industries Joint Undertaking (JU) under grant agreement No 888003, and to the UP4HEALTH Project (H2020-BBI-JTI-2019) that supports the work of Paz Otero. and P. Garcia-Perez. The research leading to these results was funded by Xunta de Galicia supporting the program EXCELENCIA-ED431F 2020/12; to the Ibero-American Program on Science and Technology (CYTED—AQUA-CIBUS, P317RT0003). The JU receives support from the European Union’s Horizon 2020 research and innovation program and the Bio-Based Industries Consortium. The project SYSTEMIC Knowledge Hub on Nutrition and Food Security has received funding from national research funding parties in Belgium (FWO), France (INRA), Germany (BLE), Italy (MIPAAF), Latvia (IZM), Norway (RCN), Portugal (FCT), and Spain (AEI) in a joint action of JPI HDHL, JPI-OCEANS and FACCE-JPI launched in 2019 under the ERA-NET ERA-HDHL (No. 696295). The authors are also grateful to FCT, Portugal, for financial support through national funds FCT/MCTES to the CIMO (UIDB/00690/2020); and L.B. and R.C. thank the national funding by FCT, P.I., through the institutional and individual scientific employment program-contract for their contracts.
Institutional Review Board Statement
Not applicable.
Informed Consent Statement
Not applicable.
Data Availability Statement
Not applicable.
Acknowledgments
We would like to thank MICINN for supporting the Ramón y Cajal grant for M.A.P. (RYC-2017-22891) and University of Vigo for supporting the predoctoral grant of M.C. (Uvigo-00VI 131H 6410211).
Conflicts of Interest
The authors declare no conflict of interest.
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Figure 1.
Nutritional characterization (ashes, proteins, lipids, and carbohydrates), and energy determination of three Amaranthaceae plants: (A) A. sessilis, (B) D. chinensis and (C) D. ambrosioides. The results for nutrient content were expressed as relative content in percentage, whereas energy was expressed as mean ± SD, in kcal/100 g dw.
Figure 1.
Nutritional characterization (ashes, proteins, lipids, and carbohydrates), and energy determination of three Amaranthaceae plants: (A) A. sessilis, (B) D. chinensis and (C) D. ambrosioides. The results for nutrient content were expressed as relative content in percentage, whereas energy was expressed as mean ± SD, in kcal/100 g dw.
Figure 2.
Chemical characterization (total free sugar, organic acids, and fatty acids contents) of three Amaranthaceae plants: (A) A. sessilis, (B) D. chinensis, and (C) D. ambrosioides. Results for total sugars and organic acids were expressed as g/100 g dw, vertical bars indicate standard deviation. The results for fatty acids content were expressed as relative abundance, in percentage. SFA: saturated fatty acids, MUFA: monounsaturated fatty acids, PUFA: polyunsaturated fatty acids.
Figure 2.
Chemical characterization (total free sugar, organic acids, and fatty acids contents) of three Amaranthaceae plants: (A) A. sessilis, (B) D. chinensis, and (C) D. ambrosioides. Results for total sugars and organic acids were expressed as g/100 g dw, vertical bars indicate standard deviation. The results for fatty acids content were expressed as relative abundance, in percentage. SFA: saturated fatty acids, MUFA: monounsaturated fatty acids, PUFA: polyunsaturated fatty acids.
Figure 3.
Identification of phenolic compounds (fatty acids, organic acids and tocopherols) of three plants belonging to the Amantharaceae family: (A) A. sessilis, (B) D. chinensis and (C) D. ambrosioides. LD: luteolin derivatives, AD: apigenin derivatives, KD: kaempferol derivatives, QD: quercetin derivatives, and ID: isorhamnetin derivatives.
Figure 3.
Identification of phenolic compounds (fatty acids, organic acids and tocopherols) of three plants belonging to the Amantharaceae family: (A) A. sessilis, (B) D. chinensis and (C) D. ambrosioides. LD: luteolin derivatives, AD: apigenin derivatives, KD: kaempferol derivatives, QD: quercetin derivatives, and ID: isorhamnetin derivatives.
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Nuñez-Estevez, B.; Finimundy, T.C.; Carpena, M.; Barral-Martinez, M.; Calhelha, R.; Pires, T.C.S.P.; Otero, P.; Garcia-Perez, P.; Simal-Gandara, J.; Ferreira, I.C.F.R.; et al. Bioactive Compound Profiling and Nutritional Composition of Three Species from the Amaranthaceae Family. Chem. Proc. 2021, 5, 20. https://doi.org/10.3390/CSAC2021-10563
AMA Style
Nuñez-Estevez B, Finimundy TC, Carpena M, Barral-Martinez M, Calhelha R, Pires TCSP, Otero P, Garcia-Perez P, Simal-Gandara J, Ferreira ICFR, et al. Bioactive Compound Profiling and Nutritional Composition of Three Species from the Amaranthaceae Family. Chemistry Proceedings. 2021; 5(1):20. https://doi.org/10.3390/CSAC2021-10563
Chicago/Turabian StyleNuñez-Estevez, Bernabe, Tiane C. Finimundy, Maria Carpena, Marta Barral-Martinez, Ricardo Calhelha, Tânia C. S. P. Pires, Paz Otero, Pascual Garcia-Perez, Jesus Simal-Gandara, Isabel C. F. R. Ferreira, and et al. 2021. "Bioactive Compound Profiling and Nutritional Composition of Three Species from the Amaranthaceae Family" Chemistry Proceedings 5, no. 1: 20. https://doi.org/10.3390/CSAC2021-10563
