Determination of Optimum Maturity Stage for Ocimum sanctum L. Grown under Different Growing Systems in Terms of Therapeutically Active Secondary Metabolites

K.W. ABEYWARDHANA; D.C. ABEYSINGHE; R.M. DHARMADASA; A.M.L ATHTHANAYAKE

World Journal of Agricultural Research. 2014, 2(4), 159-162
DOI: 10.12691/WJAR-2-4-4

Original Research

Determination of Optimum Maturity Stage for Ocimum sanctum L. Grown under Different Growing Systems in Terms of Therapeutically Active Secondary Metabolites

K.W. ABEYWARDHANA¹, D.C. ABEYSINGHE¹, R.M. DHARMADASA^2, and A.M.L ATHTHANAYAKE¹

¹Department of Plantation Management, Faculty of Agriculture and Plantation Management, Wayamba University of Sri Lanka, Makandura, Gonawila (NWP)

²Industrial Technology Institute, Baudhaloka Mawatha, Colombo, Sri Lanka

Pub. Date: July 15, 2014

Full Text PDF

Cite this paper

K.W. ABEYWARDHANA, D.C. ABEYSINGHE, R.M. DHARMADASA and A.M.L ATHTHANAYAKE. Determination of Optimum Maturity Stage for Ocimum sanctum L. Grown under Different Growing Systems in Terms of Therapeutically Active Secondary Metabolites. World Journal of Agricultural Research. 2014; 2(4):159-162. doi: 10.12691/WJAR-2-4-4

Abstract

Ocimum sanctum L. (Lamiaceae) is therapeutically important medicinal plant used in traditional systems of medicine. Present study was undertaken to determine the optimum growth stage in terms of total phenolic content (TPC), total flavonoid content (TFC) and antioxidant capacity (TAC) of leaf and bark extracts of hydroponically and field grown plants of O. sanctum in three different maturity stages. Alkaloids, flavonoids, saponins, tannins and steroid glycosides were qualitatively screened through established protocols. TPC, TFC and TAC were determined by colorimetric Folin-Ciocalteu method, aluminum nitrate method and Ferric Reducing Antioxidant Power (FRAP) assay respectively. Leaf and bark extracts of O. sanctum grown under both field and hydroponic conditions, at all three maturity stages exhibited the presence of all phytochemicals tested. TPC, TFC and TAC were increased with the maturity. Significantly higher TPC (8.34 ± 0.14 mg GAE /g DW), TFC (132.29 ± 1.45 mg RE /g DW) and TAC (120.02 ± 4.06 mg TE /g DW) were observed in leaf extracts taken from field grown plants at fully maturity stage. The order of increase was just before flowering< just after flowering< fully maturity stage. Presence of higher content of TPC, TFC and TAC in O. sanctum leaves at fully maturity stage, scientifically validate the traditional claims of harvesting of O. sanctum leaves at fully maturity stage for better therapeutic value. Moreover, presence of all tested phytochemicals in hydroponically grown plants is positive sign of use of hydroponic system as an alternative growing system for O. sanctum.

Keywords

antioxidant capacity, growing systems, Ocimum sanctum, maturity stages, secondary metabolites

Copyright

This work is licensed under a Creative Commons Attribution 4.0 International License. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/

References

[1]	Abeysinghe, D.C., Li, X.., Sun, C., Zhang, W., Zhou, C., and Chen, K, “Bioactive compounds and antioxidant capacities in different edible tissues of citrus fruits of four species” Food chemistry, 104. 1338-1344. 2007.

[2]	Ahmed, M., Ahamed R.N., Aladakatti, R.H. and Ghosesawar, M.G. “Reversible anti-fertility effect of benzene extract of Ocimum sanctum leaves on sperm parameters and fructose content in rats,” J. Basic Clin. Physiol. Pharmacol, 13(1). 51-9. 2002.

[3]	Ali, H., and Dixit, S, “In-vitro antimicrobial activity of flavonoid of Ocimum sanctum with synergistic effect of their combined form,” Asian Pac J. Trop Dis. 2. 396-398.2012.

[4]	Anita, B., and Anna, T, “Biotic and abiotic factors affecting the content of the chosen antioxidant compounds in vegetables. Vegetable Crops Research Bulletin” 76. 55-78. 2012.

[5]	Bell, E.A., and Charlwood, B.V, The Possible Significance of Secondary Compounds in Plant, Secondary Plant Products, Springer-Verlag, New York, 1980,11-21.

[6]	Benzie, I.F.F., and Strain, J.J, “The ferric reducing ability of plasma as a measure of antioxidant power: The FRAP assay,” Journal of analytical Biochemistry, 293. 70-76. 1996.

[7]	Briskin, D.P, (2000). “Medicinal Plants and Phytomedicines. Linking Plant Biochemistry and Physiology to Human Healt,” Plant Physiology, 124. 507-514. 2000.

[8]	Chandur, U., Shashidhar, S., Chandrasekar S.B., Bhanumathy M. and Midhun, T, “Phytochemical evaluation and anti-arthritic activity of root of Saussurea lappa,” Pharmacologi, 2. 265-267. 2011.

[9]	Desider, A.. and Falconi, M,” Prokaryotic Cu, Zn superoxide dismutases,” Biochem Soc Trans, 1322-5. Dec. 31(Pt 6).

[10]	Farnsworth, N, “Biological and phytochemical screening of plants,” Journal of pharmaceutical Science, 55. 225-276. 1966.

[11]	Gontier, E., Clement, A., Tran, T.L.M., Gravot, A., Lievre, K., Guckert, A. and Bourgaud, “Hydroponic combined with natural or forced root permeabilization: A promising technique for plant secondary metabolite production,” Plant Sci., 163. 723-732. 2002.

[12]	Jayaprakasha, G.K. and Rao, L.J, “Phenolic constituents from lichen Parmotrema stuppeum (Nyl.) Hale and their antioxidant activity. Zeitschrift für Naturforschung. C,” Journal of Bioscience, 55. N. 11-12. 1018-1022. 2000.

[13]	Kamel Msaada, Karim Hosni, Mouna Ben Taarit, Thouraya Chahed, Mohamed Elyes Kchouk, Brahim Marzouk,”Changes on essential oil composition of coriander (Coriandrum sativum L.) fruits during three stages of maturity,” Food Chemistry, 102 ( 4 ). 1131-1134. 2007.

[14]	Kathirvel, P. and Ravi, S, Chemical composition of the essential oil from basil (Ocimum basilicum Linn.) and it’s in vitro cytotoxicity against HeLa and HEp-2 human cancer cell lines and NIH 3T3 mouse embryonic fibroblasts, Nat Prod Res.,Sep 22. 2011. (Epub ahead of print).

[15]	Kaufman, P.B., Cseke, L.J., Warber, S., Duke, J.A. and Brielmann, H.L, Natural Products from Plants, CRC Press, Boca Raton, FL. 1999.

[16]	Liu, M., Li, X.Q., Weber, C., Lee, C.Y., Brown, J. and Liu, R.H, “Antioxidant and Anti-proliferative Activities of Raspberries,” J. Agric. Food Chem., 50. 2926-2930. 2002

[17]	Panabokke, C. R,Soil and agroecological environmenst of Sri Lanka, Natural Resources Energy and Science Authority,Colombo,Sri Lanka. 1996.

[18]	Rahman, S., Islam, R., Kamruzzaman, M., Alam, K. and Jamal, A.H.M, “Ocimum sanctum, L. A Review of Phytochemical and Pharmacological Profile,” American Journal of Drug Discovery and Development, 1-15. 2011.

[19]	Sharma, R. K., Samant, S. S., Sharma, P. and Devi, S, “Evaluation of antioxidant activities of Withania somnifera leaves growing in natural habitats of North- west Himalaya, India,” Journal of Medicinal Plants Reaserch, 6 (5). 657-661. 2011.

[20]	Shiow, Y., Wang and Hsin-Shan Lin, “Antioxidant Activity in Fruits and Leaves of Blackberry, Raspberry, and Strawberry Varies with Cultivar and Developmental Stage,” J. Agric. Food Chem., 48 (2). 140-146. 2000.

[21]	Singh, E., Sharma, S., Dwivedi, J. and Sharma, S, “Diversified potentials of Ocimum sanctum Linn. (Tulsi): An exhaustive survey,” J. Nat. Prod. Plant Resour; 2(1). 39-48. 2012.

[22]	Siriwardana, A.S., Dharmadasa, R.M., Samarasinghe, K, “Distribution of withaferin A, an anticancer potential agent, in different parts of two verities of Withania somnifera (L.) Dunal grown in Sri Lanka,” Pakistan Journal of Biological Sciences, 16(3).141-144. 2013.