Indian Journal of Experimental Biology Vol. 56, January 2018, pp. 48-53

Nutritional analysis of selected species of Forsskal ()

TS Preetha1*, Anju S1, Anilkumar S2 & I Mini1 1Department of Botany, University College, Thiruvananthapuram-695034, Kerala, India 2Department of Botany, Sree Narayana College, Varkala, Thiruvananthapuram, Kerala, India

Received 29 July 2015; revised 22 June 2017

Alternanthera Forsskal (Amaranthaceae) is an underexploited genus with potent medicinal activities exhibiting biotic and abiotic tolerance, survival with basic minimal requirements, with a palatable taste and free of insecticides or pesticides. Here, we analyzed selected species of these under-utilized for various nutrients to enable identification of unconventional food resources. Among the species investigated, Alternanthera sessilis showed high amount of energy rich nutritional factors, such as carbohydrates, proteins and lipids. High content of aminoacids and flavanoids have been observed in A. sessilis and A. philoxeroides. Alternanthera versicolor recorded higher amount of vitamin A while A. tenella showed the least. Vitamin C content was predominantly high in all the species investigated. Regarding pigment composition, highest chlorophyll content was noticed in A. philoxeroides followed by A. sessilis; the least amount in A. tenella. The concentration of carotene was high in A. sessilis. With regard to antinutritional assays, A. sessilis and A. philoxeroides exhibited only low level of phytic acid and majority of them had low tannic acid content. These two species possess high nutritional and low level of antinutritional factors. All the species studied revealed comparatively high amount of phenol. With their demonstrated nutritional qualities with low level of anti-nutritional factors, it can be suggested that A. sessilis and A. philoxeroides be included in the dietary menu along with other conventional leafy vegetables. Further, these nutritive herbs can be advocated for domestication and thereby effective utilization.

Keywords: Antinutritional factors, β-Carotene, Chlorophyll, Dietary supplement, Herbal nutrition, Leafy vegetable, Nutraceuticals, Phenols, Phytic acid, Tannic acid, Vitamin A and C

Conventionally, food and health are strongly inter- regarded as ‘nature’s antiaging wonders’ due to its related and traditionally, people have been using medicinal properties beyond essential sustenance3. plants and extracts as food and also to cure Specially, leafy vegetable are cooked, boiled, eaten various ailments1. Different parts of plants such as raw or dried and stored for uses round the year. They , young shoots, stem, tender flowers, fruits, have long been recognized most abundant sources of pods, roots, rhizome and tubers are used as protein, vitamins and minerals. vegetables. Some vegetables are under-utilized and In this study, we have selected Alternanthera their consumption is not widely accepted as it is Forsskal for investigation which is an under-exploited considered to be poor’s diet. Many researchers have genus of Family Amaranthaceae, moderately a large also reported nutritional composition of various types family with 77 genera and over 840 species. of wild edible plants being used in the developing Amaranthus tristis and Alternanthera sessilis known 2 countries . All of them emphasize that analyzing for their medicinal usage have been used as well as locally available plants for various nutrients would for food. Both plants have been reported to possess enable identification of unconventional food unique bioactive compounds that contribute to their resources. Leafy vegetables are the major component pharmacological activities. A. tristis contains amarantin, in traditional diet due to its health benefits, which is isoamarantin, betaine, aminoacids and sterols4. There are mainly because of presence of more phytochemicals yet other plants in Amaranthaceae which are invasive with potential antioxidant properties. They are and luxuriantly growing in our locality. Among them, the species of Alternanthera needs special consideration —————— as some of them viz. Alternanthera brasiliana, *Correspondence: Phone: +91 9496254040 (Mob) A. philoxeroides and A. sessilis are medicinally E-mail: [email protected] important and are also used as leafy vegetables, PREETHA et al.: NUTRITIONAL ANALYSIS OF ALTERNANTHERA spp. 49

though not extensively5-8. A. sessilis is used to relieve proteins10, soluble sugars (Anthrone method), amino headache and dizziness. It is also used to treat acids11, lipids12, flavanoids13, reducing sugars14, snakebites and to stop blood vomiting. Young shoots pigments15, vitamin A16 and vitamin C17 as per and leaves are eaten as a vegetable in southeast Asia9. standardized procedures. Antinutritional factors, such Hence, a thorough analysis of these neglected/under- as total phenol18, phytic acid19 and tannins20 were also utilized green leafy vegetables is required since they analyzed. All the experiments were done in triplicate. can be sources of essential components, such as The data were statistically analyzed by ANOVA and flavonoids, phenolics and vitamins. Till date, the means were compared by t-test at P ≤0.05. Alternanthera spp. have not been investigated for their nutritional potentiality. Here, we analyzed the Results nutritional and antinutritional factors in the targeted Quantitative analysis of nutritional factors species for their effective utilization as a potential Nutritional factors estimated in the targeted species candidate for managing nutrition deficiency. are given in Table 1. The predominant phytochemicals present in the plant were carbohydrates. High amount Materials and Methods of carbohydrate were seen in Alternanthera sessilis -1 -1 Plant material (48±0.22 mg g ) and A. brasiliana (45±0.31 mg g ) Selected species of Alternanthera, collected from and the amount of reducing sugar was also highest in -1 different localities of Thiruvanathapuram district of them (56.12±0.20 and 81.07±0.23 mg g , respectively). Kerala State (herbarium voucher numbers prefixed Protein content (%) in the samples varied from -1 with UCBD) viz. A. brasiliana (L.) Kuntze (Attingal, 2.57±0.02 to 12.70± 0.25 mg g . A. brasiliana Thiruvananthapuram, Kerala; UCBD13696)*, recorded the highest concentration of protein -1 A. philoxeroides (C. Martius) Griseb. (Nedumangad, (12.70±0.25 mg g ); while A. versicolor showed the -1 Thiruvananthapuram, Kerala; UCBD13697), A. sessilis lowest protein content (2.57±0.02 mg g ). A. sessilis -1 (L.) R. Br. ex DC. (Manacadu, Thiruvananthapuram, exhibited high amount of lipid (4.64±0.06 mg g ) -1 Kerala; UCBD13698), A. tenella Colla (Peroorkada, and maximum flavonoid content (9.15±0.06 mg g ). Thiruvananthapuram, Kerala; UCBD13699) and Total amino acid content was highest in -1 A. versicolor R. Br. (Palode, Thiruvananthapuram, A. philoxeroides (4.821±0.03 mg g ) followed by -1 Kerala; UCBD136700), served as the source A. sessilis (4.33±0.01 mg g ) and A. versicolor -1 plant materials for the study. They were identified (3.128±0.04 mg g ). by the authorities at University of Calicut and Quantitative analysis of vitamins and pigments the herbarium specimens were deposited at the The results denoted that A. versicolor has higher Herbarium of Department of Botany, University amount (2.82 µg g-1) of vitamin A; while A. tenella College, Thiruvananthapuram (Voucher numbers have the least (0.0158 µg g-1) compared to other specified as above). species investigated. All of them showed predominantly high amount of vitamin C (1.0317- Quantitative analysis of nutritional and antinutritional factors -1 Fresh samples locally collected from selected 1.275 µg g ) (Fig. 1A). species were used for quantitative analysis of The different species analyzed varied in the amount biochemical parameters such as total soluble of the green pigment chlorophyll. A. phlioxeroides

Table 1 — Quantitative analysis of nutritional factors in Alternanthera species Parameters analyzed Alternanthera species A. tenella A. sessilis A. brasiliana A. philoxeroides A. versicolor Total protein (mg g-1) 8.32±0.12b 6.95± 0.15c 12.70± 0.25a 5.60± 0.40d 2.57±0.02e Total Carbohydrate (mg g-1) 24.02±0.10b 48.64±0.22a 45.23±0.31a 19.67±0.24c 28.83±0.11b Reducing sugar (mg g-1) 15.61±0.04d 56.12±0.20b 81.07±0.23a 14.86±0.12d 27.02±0.10c Lipid (µg g-1) 2.74±0.01b 4.64±0.06a 1.64±0.02c 0.36±0.01d 2.16±0.04b Total amino acid (µg g-1) 0.691±0.02c 4.33±0.01a 0.031±0.15d 4.821±0.03a 3.128±0.04b Flavanoid (mg g-1) 5.51±0.02b 9.15±0.06a 0.13±0.03e 4.45±0.05c 2.25±0.04d [Data represents mean values of three replicates. Mean values followed by the same letter in the superscript in a row do not differ significantly based on ANOVA and t-test at P ≤0.05] 50 INDIAN J EXP BIOL, JANUARY 2018

showed high content of chlorophyll (0.0662 µg g-1) A. phlioxeroides (0.28 µg g-1). In A. tenella (0.567 µg g-1) followed by A. sessilis (0.0381 µg g-1), A. versicolor and A. versicolor (0.533 µg g-1) almost same quantity (0.0156 µg g-1), A. tenella (0.0064 µg g-1) and of carotenoid was displayed while it was 0.789 µg g-1 A. brasiliana (0.0045 µg g-1), respectively (Fig. 1B). in A. brasiliana (Fig. 1C). The carotenoid content was highest in A. sessilis Quantitative analysis of antinutritional factors (0.959 µg g-1) and the least value was observed in The presence of antinutritional factors, such as phenols, phytic acid and tannic acid was analyzed in the present study. Higher concentration of phenol was found in A. phlioxeroides (0.56 mg g-1) and lower in A. tenella as well as A. brasiliana, where the phenolic content was 0.34 mg g-1 and 0.298 mg g-1, respectively. A. sessilis and A. versicolor exhibited same phenolic content in them (0.412 mg g-1 and 0.415 mg g-1, respectively). Phytic acid was more in A. versicolor (0.219 µg g-1) and A. tenella (0.205 µg g-1); while it was less in A. phlioxeroides (0.063 µg g-1) and A. sessilis (0.032 µg g-1). Low amounts of tannic acid were recorded in A. phlioxeroides (0.025 µg g-1) and A. brasiliana (0.031 µg g-1) (Fig. 1D).

Discussion Vegetables are considered to be a good source of dietary supplement on account of carbohydrates, proteins, fats, oils, etc. Out of the huge numbers of vegetables, hardly 24-26 types of vegetables are consumed by the common people globally. Recently, worldwide attention has been drawn towards the lesser known or under-utilized vegetables, widely consumed by the ethnic communities for their health benefits. Such vegetables are integral part of their diet as they get these plants in their immediate surroundings. Since both the nutritional and health are guarded by these resources, such vegetables are considered as ‘nutraceuticals’. The present study analyzed the nutritional as well as anti-nutritional factors in selected species of Alternanthera as they are available irrespective of season and information regarding their nutritional value is meager.

Nutritional analysis Carbohydrates, fats and proteins are the essential nutrients of life. Significant variation was observed amongst different species of Alternanthera from nutritional point of view. Available carbohydrate content (%) ranged between 19±0.24 to 48±0.22. High amount of carbohydrate and reducing sugar were seen in A. sessilis and A. brassiliana and the amount of reducing sugar was also highest in them -1 Fig. 1 — Quantitative analysis of (A) vitamins; (B) chlorophyll; (C) (56.12±0.20 and 81.07±0.23 mg g , respectively) in carotenoids; and (D) antinutritional factors in Alternanthera spp. corroboration with the published reports of 20.0 to PREETHA et al.: NUTRITIONAL ANALYSIS OF ALTERNANTHERA spp. 51

66.8% carbohydrate in some conventional Indian Carotenoids are organic pigments found in the leafy vegetables and 82.8% carbohydrate in sweet chloroplasts and chromoplasts of plants attributing potato leaves21,22. It has been observed that tuber of two important functions. First, they can contribute to Dioscorea bulbifera, leaves of Oxalis corniculata, photosynthesis. They do this by transferring some of Barella rubra, Cissus quadrangularis, Hibiscus the light energy they absorb to chlorophylls, which sabdiriffa and Cassia tora are good source of then uses this energy for photosynthesis. Second, they carbohydrate exhibiting 79.03±0.81, 69.59±2.81, can protect plants which are over-exposed to sunlight. 65.51±0.15, 71.01±1.16, and 64.83±0.43%, They do this by harmlessly dissipating excess light respectively of the same. Similarly, lipids are also energy which they absorb as heat. In the absence of important in energy storage. Out of 5 species under carotenoids, this excess light energy could destroy study, leaves of A. sessilis showed high amount of proteins, membranes and other molecules. In the lipid (4.64±0.06 mg g-1). The previously reported present study, the carotenoid content was highest in values ranged between 1.60-7.10% in some leafy Alternanthera sessilis (0.959 µg g-1) and lowest in vegetables consumed in Nigeria23. A. phlioxeroides (0.28 µg g-1). It has been previously Protein contents in the samples varied from reported that as A. sessilis is considerably rich in iron, 2.57±0.02 to 12.70±0.25 mg g-1. A. brasiliana showed vitamin A and dietary fibres, contains abundant carotene 28 the highest value (12.70±0.25%) while A. versicolor and is used for curing night blindness . Therefore, this recorded the lowest (2.57±0.02 mg g-1). Leaves of nutritive herb can be effectively utilized to overcome Amaranthus viridis, Chenopodium album, Centella problems associated with vitamin A deficiency. asiatica, Commelina benghalensis and Moringa Antinutritional analysis oleifera have also been found to be potential sources The antinutritional factors may be defined as those of protein. Soups made with the leaves of A. sessilis substances generated in natural feed stuffs by the are given to anemic patients in rural areas as it also normal metabolism of the stuffs by the normal has high content of protein24 which substantiated the metabolism of the species and by different mechanism present finding. (e.g., inactivation of some nutrients, diminution of the Present study showed that the amino acid content was digestive process or metabolic utilization of feed) -1 higher in A. phlioxeroides (4.821 µgg ) and A. sessilis which exert effect contrary to optimum nutrition. -1 (4.33 µg g ) compared to other reported green leafy Wild edible plants consumed by tribal people are rich 2 vegetable . These essential amino acids probably would in several nutrients. However, the main problem serve as alternative energy sources when carbohydrate related to the nutritional exploitation of wild edible metabolism is impaired via gluconeogenesis. plants is the presence of antinutritional and toxic Vitamin A (β-carotene) is a fat soluble vitamin compounds viz. phenolic compounds, phytic acid, supplied to the body in the form of its precursor, tannins, saponins, etc. Dietary diversity is essential to β-carotene, which is present in fruits, vegetables, reduce the effects of these anti-nutritional factors. leafy greens, etc. and it is not stored in the body when Phenols are a group of aromatic chemical compounds consumed abundant. In this study, A. versicolor has with weakly acidic properties characterized by a been found to possess higher vitamin A content hydroxyl (OH) group attached directly to an aromatic (2.82 µg g-1) while A. tenella have the least ring and the presence of phenols is considered to (0.0158 µg g-1) compared to other investigated be potentially toxic to the growth and development species. This amount was higher compared to of pathogens29. It is reported that phenolic compounds Bidens biternata (0.06 mg g-1), a green leafy have also been shown to posses’ antimutagenic, vegetable of Asteraceae25. All the Alternanthera spp. anticarcinogenic, antiglycemic and antioxidative recorded primarily high amount of vitamin C (1.0317- properties30. Higher concentration of phenol (0.56 mg g- 1.275 µg g-1) in contrast to other reported green 1) was recorded in A. phlioxeroides and the amount was leafy vegetable such as Trigonella foenum-graecum lower in A. tenella and A. brasiliana (0.34 and (0.010 mg g-1) belonging to the family Papilionaceae26 0.298 mg g-1, respectively). The phenolic content and the amount was comparatively lesser than that of was almost same in A. sessilis and A. versicolor vitamin A content. This is because vitamin C is fat (0.412 and 0.415 mg g-1, respectively). Plant materials soluble and its loss is always lower than the water rich in phenolics are increasingly being used in the soluble counter parts27. food industry because they retard oxidative 52 INDIAN J EXP BIOL, JANUARY 2018

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