In collaboration with Scientific Association of Iranian Medicinal Plants

Document Type : Research Paper

Authors

1 Ph.D. student of Plantal Biotechnology, Agronomy and Plant Breeding Department, Agriculture and Natural Resources Faculty, University of Mohagheghe Ardabili, Ardabil, Iran

2 Agronomy and Plant Breeding Department, Agriculture and Natural Resources, University of Mohagheghe Ardabili, Ardabil, Iran

3 System Biology Department, Agricultural Biotechnology Institute of Iran, Agricultural Research Education and Extension Organization (AREEO), Karaj, Iran

Abstract

Fenugreek (Trigonella L.) is one of the most important and oldest known medicinal plants in the world, used in the treatment of many diseases due to its various secondary metabolites. The plant has more than 135 species growing throughout the world and in most climates. Trigonelline is the most important and most abundant alkaloid and one of the valuable metabolites found in fenugreek that is used to treat diabetes and reduce blood lipids. In this research, 22 genotypes from 10 species of fenugreek including: T. uncata, T. monantha, T. persica, T. anguina, T. stellate, T. spruneriana, T. astroites, T. monspeliaca, T. tehranica and T. foenum-graecum were collected from Khuzestan, Tehran, and Hormozgan provinces and their trigonelline levels were measured using HPLC technique. The results showed that T. foenum-graecum and T. tehranica had higher trigonelline content (1.34 and 0.9 mg/g seed, respectively) than other species. Also, there was a significant difference between genotypes for trigonelline content. The clustering based on Ward’s method separated genotypes into two groups. This study could be the basis for further work on the extraction of pharmaceutical compounds from other fenugreek species, especially native species of Iran such as T. tehranica.

Keywords

- Allen, O.N. and Allen, E.K., 1981. The Leguminosae: A source book of characteristics, uses and nodulation. Macmillan Co., London, 812p.
- Brossi, C., 1985. The Alkaloids: Chemistry and Pharmacology (Vol. 26). New York, NY: Wilely-Interscience, 401p.
- Cho, S., Jang, S., Chae, S., Chang, K.M., Moon, Y.H., An, G. and Jang S.K., 1999. Analysis of the C-terminal region of Arabidopsis thaliana APETALA1 as a transcription activation domain Plant Molecular Biology, 40: 419-429.
- Clarkson, C., Maharaj, V.J. and Crouch, N.R., 2004. In vitro antiplasmodial activity of medicinal plants native to or naturalised in South Africa. Journal of Ethnopharmacology, 92: 177-191.
- Esmaeili, A., Rashidi, B. and Rezazadeh, Sh., 2011. Biological activities of various extracts and chemical composition of Trigonella monantha C. A. Mey. subsp. monantha grown in Iran. Iranian Journal of Pharmaceutical Research, 11(4): 1127-1136.
- Fabricant, D.S. and Farnsworth, N.R., 2001. The value of plants used in traditional medicine for drug discovery. Environmental Health Perspective, 109(1): 69-75.
- Hutchinson, J., 1964. The Genera of Flowering Plants (Vol. I). Clarendon Press, Oxford, 659p.
- Jain, R., Udipi, S. and Ghugre, P., 2009. Mineral content of complementary foods. The Indian Journal of Pediatrics, 1: 37-44.
- Joshi, J.G. and Handler, P., 1960. Biosynthesis of trigonelline. Journal of Biological Chemistry. 235: 2981-2983.
- Liang, N. and Kitts, D.D., 2014. Antioxidant property of coffee components: assessment of methods that define mechanisms of action. Molecules, 19(11): 19180–19208.
- Martin, E., Akan, H., Ekici, M. and Aytac, Z., 2011. New chromosome numbers in the genus Trigonella L. (Fabaceae) from Turkey. African Journal of Biotechnology, 10(2): 116-125.
- Mehra, P., Yadar, R. and Kamal, R., 1996. Influence of nicotinic acid on production of trigonelline from Trigonella polycerata tissue culture. Indian Journal of Experimental Biology, 34(11): 1147-1149.
- Mehrafarin, A., Qaderi, A., Rezazadeh, Sh., Naghdi Badi, H., Noormohammadi, Gh. and Zand, E., 2010. Bioengineering of important secondary metabolites and metabolic pathways in fenugreek (Trigonella foenum-graecum L.). Journal of Medicinal Plant, 9(35): 1-18.
- Minorsky, P.V., 2002. Global warming-- effects on plants. Plant Physiology, 129(4): 1421-1422.
- Pavarini, D.P., Pavarini, S.P., Niehues, M. and Lopes, N.P., 2012. Exogenous influences on plant secondary metabolite levels. Animal Feed Science and Technology, 176: 5-16.
- Petropoulos, G.A., 2002. Fenugreek, The Genus Trigonella. Taylor & Francis e-Library, 226p.
- Prasad, R., 2011. Identification of high seed yielding and stable fenugreek mutants. M.Sc. Thesis. Lethbridg Univ., Alberta, Cananda.
- Rajasekaran, L.R., Jones, G.P., Aspinall, D. and Paleg, L.G., 2001. Stress Metabolism: IX. Effect of salt stress on trigonelline accumulation in tomato. Canadian Journal of Plant Science. 81:487-498.
- Reasat, M., Jafari, A.A., Bahmanzadegan, A., Hatami, A. and Zareiyan, F., 2017. The constituents of essential oil in leaves of Karaj accession of Trigonella foenum graecum. Natural Product Research, 31(14):1709-1712.
- Reasat, M., Karapetyam, J. and Nasirzadeh, A., 2002. Karyotypic analysis of Trigonella genus of Fars Province. Iranian Journal of Rangelands Forests Plant Breeding Genetic Research, 11(1): 127-145.
- Rechinger, K.H., 1989. Flora Iranica, Fasc, 111-162.
- Rongjie, Z., Li, W., Longxing, W., Hongbin, X. and Shaoqing, C., 2010. Determination of trigonelline in Trigonella foenume graecum L. by hydrophilic interaction chromatography. Chinese Journal of Chromatography, 28: 379-382.
- Sampaio, B.L., Edrada-Ebel, R. and Costa, F.B.D., 2016. Effect of the environment on the secondary metabolic profile of Tithonia diversifolia: a model for environmental metabolomics of plants. Scientific Reports, 6: 29265.
- Selma, U.G.S. and Gamze, K., 2018. Tocopherol, sterol and amino acid compositions of Trigonella strangulata Boiss. seeds. International Research Journal of Pharmacy and Medical Sciences (IRJPMS), 2(1): 36-39.
- Ueda, M. and Yamamura, S., 2000. Chemistry and Biology of Plant Leaf Movements. Angewandte Chemie International Edition, 39: 1400-1414.
- Zhou, J., Chan, L. and Zhou, S., 2012. Trigonelline: a plant alkaloid with therapeutic potential for diabetes and central nervous system disease. Current Medicinal Chemistry, 19: 3523-3531.