Int J Pharm Pharm Sci, Vol 7, Issue 3, 465-467Short Communication

TOTAL POLYPHENOL CONTENT AND ANTIOXIDANT AND CYTOTOXIC ACTIVITIES OF THE SRI LANKAN ENDEMIC PLANT GENUS SCHUMACHERIA

CHAMARA JANAKA BANDARA¹, D. NEDRA KARUNARATNE¹, ANURA WICKRAMASINGHE¹, D. S. A. WIJESUNDARA², B. M. RATNAYAKE BANDARA¹, VERANJA KARUNARATNE^1,3*

¹Department of Chemistry, University of Peradeniya, Peradeniya, Sri Lanka, ²Royal Botanic Gardens, Peradeniya, Sri Lanka, ³Sri Lanka Institute of Nanotechnology, Homagama, Sri Lanka.
Email: veranjak@slintec.lk

Received: 12 Aug 2014 Revised and Accepted: 15 Sep 2014

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ABSTRACT

Objective: Schumacheriais a genus endemic to Sri Lanka distributed in lowland rain forests and mountain rain forests. The total polyphenol content and antioxidant and cytotoxic activities of hexane, dichloromethane and methanol extracts of stem-bark, root-bark, leaves and flowers of the three representative plant speciesS. castaneifolia, S. alnifolia and S. angustifolia belonging to the endemic genus Schumacheriaare reported.

Methods: Antioxidant activity was determined using the DPPH (1,1-diphenyl-2-picrylhydrazine) radical scavenging assay. The total polyphenol content, expressed as the gallic acid equivalent, was determined using theFolin-Ciocaltue method and the cytotoxic activity was determined using the brine shrimp (Artemiasalina) assay.

Results: The methanol extract of S. castaneifolia flowers (IC₅₀ = 6.8±0.1 ppm)and the methanol extracts of S. alnifolia stem-bark (IC₅₀ =7.1±0.4 ppm) and leaves (IC₅₀ =8.3±0.3 ppm) showed antioxidant activity higher than that of α-tocopherol(IC₅₀ = 10.9±4.3 ppm). The methanol extracts of S. alnifolia stem-bark (69.3±6.9 mg g^-1) and leaf (57.7±0.0 mg g^-1) extracts showed the highest polyphenol content closely followed by the methanol extracts of S. castaneifolia flowers (71.2±0.6 mg g^-1). The highest cytotoxic activity was exhibited by the methanol extract of S. castaneifolia flowers (LC₅₀ = 1.3±0.7 ppm), and all the other extracts showed comparatively less cytotoxic activity.

Conclusion: S. castaneifolia and S. alnifolia exhibit potent bioactivitiesvalidating the ethnomedical claims where the former has been used for oral aphthous.

Keywords: Schumacheria, Endemic genus, Total polyphenols, Antioxidant, Cytotoxic.

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In terms of the richness of its flora, Sri Lanka is a biodiversity hotspot. Out of the 3210 flowering plants recorded from the island, 916are endemic. As for the non-flowering plants such as lichens and mosses, whose accurate numbers are yet to be determined, new species continue to be reported [1, 2]. Considering the potential medicinal value of Sri Lankan plants, thus far there have been only a relatively few attempts at screening for biologically active compounds [3-6]. However, Sri Lankan plants have yielded alkaloids [7, 8], terpenoids [9, 10], iron chelating lichen hydroxybenzoic acids [11, 12],saponins [7], butenolides [13], and phenolic acids [14] all of which have shown potent biological activity.

The genus Schumacheria belonging to the family Dilleniaceae is an endemic genus, comprising of three species, namely S. alnifolia Hook. f. & Thoms., S. angustifolia Hook. f. &Thoms., and S. castaneifolia Vahl. All three species of genus Schumacheriaare considered as relic plant species and their evolution probably started during the late Cretaceous and early territory period in the Gondwanaland about 100 to 120 million years ago [15]. They are erect or scrambling evergreen shrubs or small trees, [16] currently found in lowland-rainforest and mountain-rainforest of Sri Lanka. The two species S. alnifolia and S. angustifolia are extremely limited in their distribution and are endangered,while S. castaneifolia is common,but restricted to the lowland rainforest [17, 18]. As they have not been evaluated previously, it is important that proper systematic bioactivity studies of these three endangered species of Schumacheriaare carried out. We report herein, the antioxidant and cytotoxic activities and the total polyphenol content of the three representative species of the endemic genus Schumacheria.

The plant material of the three species was collected in 2011;S. castaneifolia from Thummodara region in Rathnapura; S. alnifolia at Fishing-hut in Maskeliya andS. angustifolia from Haycock Hillin Hiniduma. The taxonomic identification of plant species was carried out by Dr. D. S. A. Wijesundara, Royal Botanic Gardens, Peradeniya. The specimens have been deposited in the National Herbarium of the Royal Botanical gardens, Peradeniya.

Plant materials were separately cleaned, air dried, ground, sequentially extracted into hexane, dichloromethane and methanol using a bottle-shaker, and the solvent extracts were concentrated to provide the dry crude extract. The methanol extracts (0.5 g) of Schumacheria plant specimens were separately dissolved in 70 % methanol-water solution (25.0 ml) and were centrifuged at 1500 g for 10 min. The resulting supernatants were evaluated for the total polyphenol content.

The total polyphenol content was determined by mixing a 10 fold diluted Folin-Ciocaltue reagent (1.0 ml) and the extract(200 µl); after 8 minutes, Na₂CO₃ [7.5 % (m/v)] aqueous solution (800 µl) was added, kept for 1 h and the UV absorbance measured at 765 nm. A calibration plot using standard gallic acid ranging in concentration from 1.0 to 20.0 ppm was obtained. The total polyphenol content of commercially available branded tea was determined and all data were represented equivalent to gallic acid (GAE). A commercially available tea extract (0.5 g) dissolved in 70% methanol-water (25 ml) was used as a positive control.

The antioxidant activity of the plant extracts was determined using DPPH (1,1-diphenyl-2-picrylhydrazyl) radical scavenging method [19]. The final concentration of DPPH in the test mixture was maintained at 1× 10-4mol dm-3 in methanol, and α-tocopherol was used as a positive control. The IC50 values were determined in triplicate using solutions of 1, 5, 10, 15, 20, 40, 60, 80 and 100 ppm. The absorbance of the test solutions was measured at 517 nm after 30 min using a UV spectrophotometer (Shimadzu, UV-1800). The antioxidant activity was calculated using the formula: % antioxidant activity = [(Ai-Af) / Ai] × 100, where Ai is the initial absorbance of the test mixture following the addition of DPPH and Af is the absorbance after 30 min.

Cytotoxic activity was determined using the brine shrimp assay [20]. From each dry plant extracts, a concentration series was prepared ranging from 2000, 750, 200, 75.0, 20.0, 7.5, 2.0 and 0.75 ppm in DMSO (1% v/v) in sea water. A final volume of 5.0 ml was maintained for each test sample and 10 one day old shrimp larvae were added to each concentration level. After 24 h, the viable number of shrimps was counted for each concentration level and the percent lethality was determined using Probit analysis. The LC₅₀ values were determined with 95 % confidence intervals using software Minitab^®16. (4S)-4-Methyl-2-(11-dodecynyl)-2 butenolide [21] and DMSO (1.0 % v/v) in sea water were used as a positive control and a negative control, respectively.

All tests were carried out in triplicate. The data was statistically analyzed and expressed as mean±SD.

The IC­₅₀ values representing the antioxidant activity are given in table 1 where the methanol extract of S. castaneifolia flowers and the methanol extracts of S. alnifolia stem-bark (IC₅₀ = 7.1±0.4 ppm) and leaves (IC₅₀ = 8.3±0.3 ppm) showed significant activity (α-tocopherol, IC₅₀ = 10.9±4.3 ppm). Importantly, antioxidants play a major role in the neutralising of free radicals formed during the cellular processes. These radicals can lead to various diseases, including cancer and aging by decreasing the efficiency of the living cells [22].

The total polyphenol content of all methanol extracts, the plant extracts and a commercially available branded tea sample were expressed as equivalent to the gallic acid content (GAE) in mg per 1.0 g of dry plant material (table 1). A calibration plot was obtained from a gallic acid standard solution series and the gradient (m = 0.0982) and the graph linearity (R² = 0.9993) were obtained. The tea extract showed the highest polyphenol content (GAE, 182.3±15.5 mg g^-1). Although the methanol extracts of S. alnifolia stem-bark (69.3±6.9 mg g^-1), leaves (57.7±0.0 mg g^-1) and S. castaneifolia flowers (71.2±0.6 mg g^-1) exhibited values lower than tea, they were still high enough to be significant. It has been shown that polyphenols possess potent antioxidant properties [23] which agree well with the high polyphenol content and corresponding high antioxidant activities of these two plants.

Cytotoxic activities were determined using the brine shrimp assay where (4S)-4-methyl-2-(11-dodecynyl)-2 butenolide was used as a positive control (LC₅₀ = 0.15±0.41 ppm). The highest activity was shown by the methanol extract (LC₅₀ = 1.3±0.7 ppm) and the dichloromethane extract (LC₅₀ = 11.3±5.6 ppm) of the S. castaneifolia flowers.

Table 1: Antioxidant and cytotoxic activities and total polyphenol content of the extracts of genus Schumacheria

Plant species botanical name	Plant a part(s) #(g)	Type of extract(s) * (g)	Antioxidant activityb IC50 (ppm)	Cytotoxic activityc LC50 (ppm)	Polyphenol content d (mg (GAE) g-1)
S. castaneifolia	FL (225)	n-Hexane (5.3)	307.0±37.5	512.8±375.6
		CH2­Cl2 (5.0)	262.4±35.2	11.3±5.6
		CH3OH (34.2)	6.8±0.1	1.3±0.7	71.2±0.6
S. castaneifolia	SB (600)	CH2­Cl2 (9.0)	295.3±5.2	73.4±13.4
		CH3OH (82.0)	9.8±0.3	903.8±168.2	65.8±0.7
S. castaneifolia	RB (34)	CH2­Cl2 (2.1)	199.6±6.4	30.9±13.6
		CH3OH (13.0)	8.1±0.1	81.6±18.7	44.0±0.1
S. castaneifolia	LF (600)	CH2­Cl2 (8.4)	266.7±27.0	340.1±80.5
		CH3OH (80.5)	10.5±0.4	66.0±17.8	49.2±0.9
S. angustifolia	FL (54)	Hexane (0.8)	686. 4±110.2	156.6±53.3
		CH2­Cl2 (0.2)	120.3±5.3	548.7±115.9
		CH3OH (6.8)	8.8±0.1	23.6±10.5	59.0±1.2
S. angustifolia	SB (370)	CH2­Cl2 (2.8)	336.8±8.5	270.3±101.1
		CH3OH (25.9)	8.2±0.2	33.7±16.3	36.7±2.3
S. angustifolia	RB (9)	CH2­Cl2 (0.6)	793.6±53.7	99.8±59.5
		CH3OH (3.8)	8.4±0.3	78.2±42.4	22.4±0.2
S. angustifolia	LF (370)	CH2­Cl2 (6.1)	393.1±41.8	573.6±281.7
		CH3OH (25.3)	14.4±0.6	26.4±11.3	19.9±0.3
S. alnifolia	SB (600)	CH2­Cl2 (11.2)	964.9±40.1	646.9±298.2
		CH3OH (70.5)	7.1±0.4	90.2±35.4	69.3±6.9
S. alnifolia	LF (600)	CH2­Cl2 (10.8)	178.3±14.3	115.5±50.9
		CH3OH (77.1)	8.3±0.3	50.5±20.5	57.7±0.0

^aFL, flowers; SB, stem-bark; RB, root-bark; LF, leaf , ^#Dry weight of each plant part, ^*Dry weight of each extract, ^bIC₅₀ values stated as mean±SD, in ppm, were based on different concentrations and three replicates, ^cLC₅₀ values stated as mean±SD, in ppm, were based on eight concentrations and three replicates, ^dPolyphenol content equivalent to the gallic acid content (GAE) in milligrams per 1.0 g of dry plant material (mg (GAE) g^-1) is based on three replications and is stated as mean±SD.

It can be concluded that the three representative species of the endemic genus Schumacheria possess high polyphenol content, antioxidant activity and cytotoxicity. In particular, it is significant that S. castaneifolia flowers possess the most potent activities in these three important bioassays giving credence to ethnomedical claims where it has been used, through a long period of oral tradition, for oral aphthous, in the Thummodararegion. Further studies are needed for the three plant species.

Financial support from the National Science Foundation, Research grant RG/2009/BS/01, is acknowledged.

REFERENCES

1. Orange A, Wolseley P, Karunaratne V, Bombuwela K. Two leprarioid lichens new to Sri Lanka. Bibl Lichenol 2001;78:327-33.
2. Jayalal RGU, Wolseley PA, Gueidan C, Aptroot A, Wijesundara DSA, Karunaratne V. Anziamahaeliyensisand Anziaflavotenuis, two new species from Sri Lanka. Lichenol 2012;44(3):381-9.
3. Bandara BMR, Fernando IHS, Hewage CM, Karunaratne V, Adikaram NKB, Wijesundara DSA. Antifungal activity of some medicinal plants of Sri Lanka. J Natl Sci Counc Sri Lanka 1989;17(1):1-13.
4. Bandara BMR, Hewage CM, Jayammane L, Karunaratne V, Bandara KANP, Adikaram NKB, et al. Biological activity of some steam distillates from leaves of ten species of Rutaceous plants. J Natl Sci Counc Sri Lanka 1990;18(l):71.
5. Hewage CM, Bandara KANP, Karunaratne V, Bandara BMR, Wijesundara DSA. Insecticidal activity of some medicinal plants of Sri Lanka. J Natl Sci Counc Sri Lanka 1997;25(3):141-50.
6. Hewage CM, Bandara BMRB, Karunaratne V, Wannigama GP, Pinto MRM, Wijesundara DSA. Antibacterial activity of some medicinal plants of Sri Lanka. J Natl Sci Counc Sri Lanka 1998;26(l):27–34.
7. Bandara BMR, Cortez D, Jayasinghe L, Karunaratne V, Wannigama GP, Sotheeswaran S. Aphorphine alkaloids from Litseagardineriand Actinodaphnespeciosa. Planta Med 1989;55:393.
8. Bandara BMR, Jayasinghe L, Karunaratne V, Wannigama GP, Bokel M, Kraus W, et al. Isolation of pheanthine from Cycleaburmanai. Planta Med 1990;56:245.
9. Gunatilaka AAL, Dhanabalasingham B, Karunaratne V, Kikuchi T, Tezuka Y. Studies on terpenoids and steroids. Part 27. Structure of a D: A-Friedo-oleanane Triterpenoid from Salacia reticulataand revision of the structure of kokoonol, kokzeylanol series of triterpenoids. Tetrahedron 1993;49(45):10397.
10. Dhanabalasingham B, Karunaratne V, Gunatilaka AAL, Tezuka Y, Kikuchi T. Biogenetically important quinonemethides and other constituents of Salacia reticulata. Phytochem 1996;42:1377.
11. Kathirgamanathar S, Ratnasooriya WD, Baekstrom P, Andersen RJ, Karunaratne V. Chemistry and bioactivity of physciaceae lichens pyxine consocians and Heterodermia leucomelos. Pharm Biol 2006;44(3):217-20.
12. Karunaratne V, Hoveyda HR, Orvig C. General method for the synthesis of trishydroxamic acids. Tetrahedron Lett 1992;33(14):1827-30.
13. Ratnayake R, Bandara BMR, Wijesundara DSA, Carr G, Andersen RJ, Karunaratne V. Four butanolides derivatives from Hortonia, a genus endemic to Sri Lanka. J Chem Res 2008;3:134-6.
14. Ratnayake Bandara BM, Hewage CM, Karunaratne V, Adikaram NKB. Methyl ester of para-coumaric acid: antifungal principle of the rhizome of Costusspeciosus. Planta Med 1988;54(5):477-8.
15. Somesekaram T, Editor. Arjuna’satlas of Sri Lanka. Arjuna Consulting Company; 1997. p. 36-8.
16. Dassanayake MD, Editor. A Revised handbook to the flora of Ceylon. AmarindPublishers: New Delhi; 1980-1987. p. 131-2.
17. MOE. The national red list of Sri Lanka: conservation status of the fauna and flora. Ministry of Environment, Colombo, Sri Lanka; 2012. p. 476.
18. Gunatilleke IAUN, Gunatilleke CVS. Distribution of endemics in the tree flora of a lowland hill forest in Sri Lanka. Biol Conserv 1984;28:275-85.
19. Budzianowski J, Budzianowska A. Chromatographic and spectrophotometric analyses of the DPPH free radical scavenging activity of the fractionated extracts from Lamium album L, Lamiumpurpureum L, Viscum album L. Herba Pol 2006;52(1/2):51-7.
20. Mayer BN, Ferrigni NR, Putnam JE, Jacobsen LB, Nichols DE, Mclaughlin JL. Brine shrimp: a convenient bioassay for active plant constituents. Planta Med 1982;45:31-4.
21. Ratnayake R, Karunaratne V, Bandara BMR, Kumar V, Macleod JK, Simmonds P. Two new lactones with mosquito larvicidal activity from three Hortoniaspecies. J Nat Prod 2001;61:376–8.
22. Palmer DM, Kitchin JS. Oxidative damage, skin aging, antioxidants and a novel antioxidant rating system. J Drugs Dermatol 2010;9(1):11-15.
23. Mozetič B, Tomažič I, Škvarč A, Trebše P. Determination of polyphenols in white grape berries cv. Rebula. Acta Chim Slov 2006;53:58–64.