Phytochemical Analysis and Antifungal Effects of the Extracts and Oils of Harjel (Solenostemma argel) Basil (Ocimum basilicum) and Parsley (Petroselinum crispum) on the Fungus Aspergillus flavus Growth and Aflatoxin Production, Sudan
DOI:
https://doi.org/10.18034/ra.v11i2.658Keywords:
Phytochemical Analysis, Antifungal, Aflatoxin ProductionAbstract
Sudan is one of the largest countries in Africa and is rich in many valuable plants that produce materials important for human and animal health. Some of these were used in traditional medicine. The present study aims to investigate the antifungal activities and the phytochemical composition of the extracts and oils of three plants (Hargel et al.). The study was conducted at the Food Microbiology Laboratory, Faculty of Engineering and Technology, University of Gezira. The mycelial growth and spore germination methods were used for the antifungal tests, using a selective medium, while thin-layer chromatography was used for phytochemical tests and aflatoxin analysis. The effects of clove oil and some amino acids were used for comparison. The results of the fungal growth showed that the leaf extracts of Hargel were highly effective and gave complete inhibition (0.0 cm radial growth), while the stem extracts and oil of Hargel were less effective, given (0.3 mm). Rehan (Basil) oil was the most effective (0.0 cm) compared to (0.4cm) and (0.5cm) for the extracts of the leaf and stem, respectively. The oil, leaf, and stem extracts of Parsley and clove oil were all highly effective, giving (0.0 cm) radial growth. The results of the effects of the amino acids on radial growth indicated that they were all highly effective, giving complete (0.0 cm) at a higher concentration (100mg/ml). The results of the effect on mycelial weights showed that the oils of the three plants, as well as that of clove, gave complete inhibition (0.0 mg weight); in contrast, the extracts of leaf of Hargel, Parsley, and Basil showed (1.74, 3.26 and 3.34, mg respectively) while, the extracts of the stems gave (3.29, 1.86 and 1.86, mg respectively). Among the amino acids tested, only methionine, leucine, and arginine were adequate (7.0, 7.4, and 7.4 mg, respectively). Concerning the effects of the spore germination, it was found that all the oils tested gave complete inhibition (0.0 %, pore germination) and the stem extracts of the three plants. However, only the leaf extracts of Parsley were highly influential; those of Harjel and Rehan were less effective (7.69% and 15.0 % germination, respectively). All the amino acids tested were less effective, giving about (10.0 % germination). The leaf and stem extracts of Harjel and both Parsley and Clove oils inhibited aflatoxin production by the fungus at all concentrations. The stem extracts of Rehan, the leaf extracts of Parsley, and the oil of Harjel inhibited aflatoxin production at higher concentrations only. The stem extracts and Rehan's oil were found to be unable to inhibit aflatoxin production at all tested concentrations. The chemical analysis of the tested plants' extracts and oils revealed that they contained saponins, tannins, flavonoids, alkaloids, and phenolics but not Steroids. However, glutamic acid was the only amino acid that inhibited aflatoxin production at all concentrations. From the results, it could be concluded that the oils of the plants were more effective than the extracts, and the leaf and stem extracts of Parsley were better among the extracts. It could be recommended that more plant extracts be tested since some plants may be more effective.
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References
Abdallah, A.E.M. (2001). Effects of Aspergillus flavus Growth and Aflatoxins on the Nutritive Value of some Legume Seeds and Cereal Grains .M.Sc, Thesis Univ. of Gezira - Sudan.
Abdel-Daim, Z.J. (2001). Z.J. Phytochemical and Microbial Studies on some Senna Species. M.Sc., Faculty of Science, University of Khartoum.
Abdel-Rahim, A.M. and Arbab, H.A (1985). Factors affecting condiospore germination in Aspergillus niger. Mycopathologia, 89: 75–79.
Abdel-Rahim, A.M.;Osman, N.A. and Idris, M.O.(1989). Survey of some cereal grains and legume seeds for aflatoxin contamination in the Sudan. Zentralbl. Mikrobiol, 89: 75-79.
Abdel-Rahim, A.M.; Al-Jali, Z.I. and Al-Mismari, S.S. (1997). Factors affecting the growth and aflatoxin production by the fungi A. flavus and A.parasiticus. 6th Arab Congress on Plant Protection, Beirut, Lebanon, OCT. 1997.
Abdel-Rahim, A.M.;Mohammed -Ali, R.J. and Al-Jali, Z.I. (2002). Effects of natural products on fungal growth and aflatoxin production in A.flavus and A.parasiticus. The 3rd International Conference on fungi, Cairo, Egypt, OCT. 2002.
Abdel-Rahim, A.M.(2005). Aflatoxin. Gezira Publishing Company Ltd. Wad Medani, Sudan.
Abdel-Rahim,A.M. and Suleiman, A.E.(2009). Aflatoxin Contamination of some Foods in the Gezira State, and its Prevention. Report Ministry of Higher Education and Scientific.5 (2):29-110.
Abdel-Rahim, A.M. and Idris, F.A. (2010). Survival of Staphylococcus aureus and E.coli on cotton fabrics treated with garad extract (Acacia nilotica).Gezira J. of Eng. & Applied Sci. 5 (2): 127-134.
Abdel-Rahim, A.M., Alsheikh, M.S., & Suleiman, A.E.(2010).Aflatoxin contamination in some cereal and legume seeds and their products in the Gezira state.5 (2):92–110.
Abdel-Rahim.A.M.; Bashiar,H.A. and Suleiman,A.E.(2012a). Antimicrobial activity of the extracts of pomegranate (Romman) plant (Punica grantum L). Gezira J. of Eng and Applied Sci., 7(1): 1-18.
Abdel-Rahim,A.M.; Yousif, W.A. and Idris, F.A.(2012b). Antifungal activity of the extracts of Garad (Acacia nilotica). Gezira Jornal of Engineering Applied Sciences 7(2)1-18.
Ahemd M.M. (2004). Phytochemical. Antimalarial, Molluscicigdal and Antimicrobial activity of selected Sudanese Medicinal Plants with Emphasis on Nigella sativa L. seeds. Ph.D. thesis, University of Gezira.
Alderman, G. G., & Marth, E. H. (1976). Citrus oils inhibit the growth and Aflatoxin production of Aspergillus parasitic. Z. Lebensm. Unters Forsch 160:353-358.
Al-Jali, Z. I. Al-Mismari, F. A. and Abdel-Rahim, A.M. (1997). Contamination of Seeds of some Crops with Aflatoxins in the Jabel Al-Akhtar Region. Proceeding of the 6th. Arab Congress of Plant Protection, Beirut, Lebanon, p.294.
Bajpai, M; Pande, A; Tewari, SK; and Parkask, D; (2005). Phenolic content and antioxidant activity of some food and medicinal plants. International Journal of Food Sciences and Nutrition 56(4): 287-291.
Balbaa, S.I.(1974). The Alkaloids: Chemistry and Pharmacology V44: Chemistry and Pharmacology V44.
Bullerman, L.B.; Schroeder, L.L. and Park, K. (1984). Formation and control of mycotoxin in Food. J, Food Prot.47:637-646.
Damain, A.L. and Drew, S.W. (1977). Effect of primary metabolites on secondary metabolism. Ann.Rev. Microbial; 31:343-356.
Dowling, F. S. (1997). Fumonisin and its toxic Effect. Cereal Foods World, 42: pp. 13–15.
Elsaeim M. (2002).Herbs and Medicinal Plants in Curing Diseases. Alzahara Library, Cairo, Abdel-Aziz Street, Egypt. S.
Gabor, M. (1988). The bioflavonoids. In: Cody C, Middleton E Jr, Harnborne JB, Beretz A (Eds), Progress in Clinical and Biological Research Vol.280.NewYork, Alan R.Liss.; pp. 1–15.
Gupta B. L. (2000). Forest Flora of Chakrata, Dehra Dun and Saharanpur. A good flora for the middle Himalayan forests, sparsely illustrated. Not really for the casual reader.
Hanif, MA, AL-Maskari, MY, Al-Maskari A, and Al-shukaili A, (2011) ALshahabiN. Essential oil composition, antimicrobial and antioxidant activities of unexplored omani basil. J. MP Res, 5:751-757.
Harborne, A.J. (1998). Phytochemical Methods: A Guide to Modern Techniques of Plant Analysis. Publisher: Springer Netherlands. ISBN.978-0-412-7260-9.Edition3,
Havsteen, B.(1983). Flavonoids are a class of natural products of high pharmacological potency. Biochem Pharmacol.32:1441-1448.
Hussain, Al, Anwar, F, Sherazi, STH, Prcy, and by Lski R.(2008) Chemical composition, antioxidant and antimicrobial activity of basil (Ocimum basilicum) essential oils depends on seasonal variation—food Chem; 108:986-995.
Kuete V. Wansi, JD, Mbaveng, AT, Kana Sop, MM, Tadjong, AT, Beng, VP, Etoa, FX, Wandji, J, Meyer JJM, Lall, N, (2008). Antimicrobial activity of the methanolic extract and compounds from Tecleaafzelii (Rutaceae). South African Journal of Botany 74:572-576.
Kuete V, (2010). Potential of Cameroonian plants and derived- products against microbial infections: A review. Planta Medica 76:1- 13.
Kumar, R., Mishra, A. K., Dubey, N. K. & Tripathi, Y. B. (2007). Evaluation of chenopodiumambrosiodes oil as a potential source of antifungal, Antiaflatatoxigenic, and Antioxidant activity. Hint.) Food Microbial., 115:159-164.
Mabrouk, and M. A. Shayeb, (1980). Inhibition of aflatoxin formation by some spices. J. Food. Sci, 171:344-347.
Manafii, M. and khosravinia, H. (2013). Effects of aflatoxin on the performance of broiler breeder and its alleviation through herbal mycotoxin binder. J. Agr. Sci-Tech. 15:55-63.
Mohamed E. Z., Amani, S. A., Mounerah, R., Reham, M. (2012). Antimicrobial activities of Saudi Arabian desert plants. Ply to pharmacology 2: pp. 106–13.
Mohammed Ali, E.E. (2002).The inhibitory effect of some essential oil on Aspergillus flavus. M.Sc. Ph.D. Thesis, University of Gezira.
Montes –Belmont, R. and M. Carvajal, (1998). Control of Aspergillus flavus in maize with plant essential oils and their components. J. Food Protect, 61: 616-619.
Moreau, C. (1979). Moulds, Toxin and Food. BM Press Roman by Preface Ltd p23-25.
Mothana, RAA. and Lindequist, U,(2005). Antimicrobial activity of some medicinal plants of the Island Socotra, Journal of Ethnopharmacology, 96:177-181.
Pelcazar, M.J.; Chan, E.C.S. and Krieg, R.N.(1977). Microbiology 5th ed. Mc Gram. Hill Book Company. New York. Pp.918.
Pratt, W.B.(1977). The Chemotherapy of Infection. Oxford University Press, New York.
Quiroga, E. N., Sampietro, D. A., Sgariglia, M A., Soteron, J. R and wattuone, M. A. (2009). Antimycomycotic Activity of 5 – prenylisoflavanones of the plant Geoffroeadecorticans against Aspergillus species. Int. J. Food Microbial. 132: 42-46.
Reddy, K. R. N., C. S. Reddy and k. Muralidharan, (2009). Potential of botanicals and biocontrol agents on growth and aflatoxin production by Aspergillus flavus infecting ice grains. Food control, 20: 173–178.
Reddy, K. R. N., Reddu, C. S. and Muraidharan, k. (2009). Detection of Aspergillus spp. And Aflatoxin B1 in Rice in India. Food Microbiol., 26:27-31.
Rios JL, and Recio, MC, (2005). Medicinal plants and antimicrobial activity. Journal of Ethnopharmacology, 100:80-84.
Saini, M.L. (2008). Comparative Pharmacognostical and antimicrobial studies of Acacia species (Mimosaceae). Journal of Medicinal Plants Research., 2(12):378–386.
Salari, R., Najafi, M. B. H., Boroushaki, M. T., Morazavi, S. A. and Najafi, M. F. (2012). Assessment of the microbiological quality and mycotoxin combination of Iranian Red pepper spice. J. Agr. Sci.Tech, 14:1511-1521.
Shukla, R., Kumar, A., Prasad C. S., Srivastava, B. and Dubey, N. K.(2008). Antimycotic and Antiaflatoxigenic potency of Adenocalymmaalliaceummier. Fungi are causing the biodeterioration of food commodities and Rew Harbel Drugs. Int. Biodeter. Biodegr., 62-248-351.
Shukla, R., Kumar, A., Singh. P. and Dubey, N. S. (2009). Efficacy of lippealba (mill.) N. E. Brown Essential oil and its Monoterpene Aldehyde constituents against fungi Isolated from some Edible legume seeds and aflatoxin B1 productions – Int. J. food Microbical., 135. 165-170.
Sulieman, A.E.; Ahmed, H.E. and Abdel Rahim, A.M. (2008). The Chemical Composition of Fenugreek (Trigonella et al. L) and the Antimicrobial Properties of its Seed Oil. Thesis University of Gezira.
Torres, B.; Varela, K.C.; Natito, E. and Centellles, K.J.(2002). Valorization of grape (Vitis Vinifera) by-products. Antioxidant and biological properties of polyphenolic fractions differing in procyanidin composition and flavonol content. J. of Agric. and Food Chem. 50, 7548-55.
Wojdylo A, Oszmianski J, and Czemerys R. (2007). Antioxidant activity and phenolic compounds in 32 selected herbs. Food Chem.105, 940-949.
Zinal, A.S., Abdel-Rahim, A.M.; Abu-Ali, R.M. and Radwan, S.S.(1988). Antimicrobial substances in the leaf litter of the Xerophyte prospis Juliflora. Zentralbl Microbial. 143,375-381.
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