Open Access
Subscription Access
Open Access
Subscription Access
Correlation between Changes in Biochemical Roots of Wheat (Triticum durum desf) and Stress Induced by some Regimes Fertilizer NPK
Subscribe/Renew Journal
We studied the physio-biochemical parameters of the wheat ischolar_mains (Tritium durum Desf), in the water content (TE), total protein levels (TPL), carbohydrate (TCH) proline (TP), Malondialdehyde (MDA), on the one hand and enzyme activities catalase (CAT) and ascorbate-Perroxydase (APX) on the other hand, with four fertilizer regimes: 0.5: 01: 01, 0.5: 02: 01, 0.5: 03: 01 and 0.5: 04: 01g/propagator NPK. Our results show that the maximum content of water is obtained with the regime. 0.5: 01: 01g/propagator NPK. Total protein and the average maximum with 0.5 proline proved: 02: 01, 0.5: 03: 01 and 0.5: 04: 01g / hotbed of NPK. It records the total carbohydrate highest respectively 0.5: 02: 01; 0.5: 03: 01 and 0.5: 04: 01g/hotbed NPK. The activities of enzymes catalase (CAT), ascorbate peroxidase (APX), were measured simultaneously with the average rates of malondialdehyde (MDA) and the parameters as indicators of cellular disorders. The results obtained show that the schemes 0.5: 02: 01 and 0.5: 03: 01 and 0.5: 04: 01g/Propagator NPK are capable of generating oxidative stress expressed through stimulation of enzyme activity CAT and APX and resulted in a significant increase in the average rate of MDA. This does not seem to be the case for regime 0.5: 01: 01g/Propagator NPK. Our study thus demonstrates the existence of a positive correlation between water content, total protein, carbohydrate, proline, MDA, CAT and APX in ischolar_mains of wheat with three fertilizer regimes 0.5: 02: 01; 0.5: 03: 01 and 0.5: 04: 01g/Propagator NPK. Our results suggest a possible apparent toxicity may be associated with some phosphate fertilizers.
Keywords
NPK, Wheat, Fertilizer, Toxicity, Roots.
Subscription
Login to verify subscription
User
Font Size
Information
- Elalaoui A.C., 2007. Fertilisation minérale des cultures. Les éléments minéraux secondaires et oligoof éléments. Bull. Mens. Inf. PNTTA, 156: 1-4.
- Union des Industries Chimiques, (UIC); 2006. Céréales et oligoéléments. Revue Chimie, pp: 11.
- Pain, A.K., 1965. Effet de l'engrais NPK et de leurs combinaisons sur le rendement et la Valeur nutritive des mûriers. Indian J. Seric., 4: 1-8.
- Kasiviswanathan, K., S. Krishnaswamiet and P.C. Chowdhury, 1979. Études à long terme sur la variété, l'espacement et la fertilisation azotée pour l'amélioration du rendement potentiel de mûrier. Indian J. Seric., 18: 23-29.
- Islam, R., M.A. Bari et and Z. Ahsan, 1982. Effet de différents niveaux d'engrais sur les feuilles rendement du mûrier à la condition irriguée. Bangladesh J. Agric., 6(7): 25-30.
- Islam, R., M.A. Bari et. and R. Ali, 1985. Effet de l'azote, du phosphore et de potassium et leur combinaison sur le rendement en feuilles de mûrier. J. Asiatic. Soc. Bangladesh. (Sc.). 11: 1-5.
- Mahmoud, L.M., 2009. Effet de l'eau, du stress et de la fertilisation NPK sur la croissance et le contenu en résine Grindeliacamporum Greene. Bangladesh J. Agril. Res., 34(3): 435-442.
- Kayode, G.O., 2005. Effects of NPK fertilizer on tuber yield, starch content and dry matter accumulation of white guinea yam (Dioscorearotundata) in a forest alfisol of south western Nigeria. Exp. Agr., 21: 389-393.
- Lene, K.C., S.K. Upadhyaya, B. Jahn, D.C. Slaughter, E. Tan and D. Hills, 2007. Determining the Influence of Water Deficiency on NPK Stress Discrimination in Maize using Spectral and Spatial Information. Pre. Agr., 6: 539-550.
- Khaldi F., H. Djebar, R. Rouabhi and M.R. Djebar, 2009. Cellular Response of a Pollution Bioindicator Model (Ramalinafarinacea) Following Treatment with Fertilizer (NPKs). Am. Eur. J. Toxicol. Sci., 1(2): 69-73.
- Monneveux, P.H. and et M. Nemmar, 1986. Contribution à l'étude de la résistance à la sécheresse chez le blé tendre. Etude de l'accumulation de la proline au cours du cycle de développement. Agronomie. pp: 1-17.
- Bradford, M., 1976. A Rapid and Sensitive Method for the quantification of microgram quantities of protein utilizing the principal of protein-Dye Binding. Analytical Biochem. 72: 248-254.
- Troll, W. and J. Lindesley, 1955. A photometric for the determination proline. J. Biochem. 215: 655-660.
- Chai, T.T., N.M. Fadzillah, M. Kusnanand and M. Mahmood, 1999. Induction of oxidative stress in Musa sp. (variety Berangan) by paraquat treatments. in Proceedings of the First national banana seminar (Z. Wahab, M.T.M. Mohamed, S.K. Daud, N.M. Fadzillahand M. Mahmood, eds). Universiti Putra Malasia, Universiti Malaya and MARDI, Malaysia. pp: 186-190.
- Nakano, Y. and K. Azada, 1987. Purification of ascorbate peroxidase in spinach chloroplasts: its inactivation in ascorbate depleted medium and reactivation by mono dehydro ascorbate radical. Plant Cell. Physiol., 28: 131-140.
- Cakmak, I. and W.J. Horst, 1991. Effect of aluminum on lipid peroxidation, superoxide dismutase, catalase and peroxidase activities in ischolar_main tips of soybean (glycine max). Physiol. Plant. 83: 463-468.
- Miah, M.A.B., 1989. Des études sur la croissance et le rendement du mûrier (Morus alba L.). Ph.D. Thesis. Université de Rajshahi, Bangladesh.
- Quader, M.A., M.A. Qayyum, A.A. Sarkar, M.A. Rab et. and S.U. Ahmed, 1992. Bull. Sericult.
- Sbartai H., R. Rouabhi, I. Sbartai, H. Berrebbah and M.R. Djebar, 2007. Induction of anti-oxidative enzymes by cadmium stress in tomato (Lycopersiconesculentum) African J. Plant Sci., 2(8): 072-076.
Abstract Views: 279
PDF Views: 2