Response to Soil Acidity of Common Bean Genotypes (Phaseolus vulgaris L.) Under Field Conditions at Nedjo, Western Ethiopia
Keywords:
Common bean, Genotypes, Lime, Soil acidity, Relative yieldAbstract
Soil acidity has become a serious threat to crop production in most highlands of Ethiopia in general and in the western part of the country in particular. A field experiment was conducted to evaluate soil acidity tolerant on 25 genotypes of common bean (Phaseolus vulgaris L.) on lime treated and untreated acid soils. The genotypes were evaluated based on morpho-agronomic parameters. Soil acidity had an effect on maturity, growth and yield of the tested genotypes. High significant(P<0.01) differences were observed among genotypes for days to maturity, leaf area index, plant height, number of pods per plant, pod length, hundred seed weight, grain yield, pod harvest index and harvest index in lime treated and untreated soils. Considerable variability exists among the genotypes tested based on the growth, and yield components measured for soil acidity tolerance. The genotypes gave higher yield and yield components when grown in lime treated soil than lime untreated with average yield reduction of 26% due to soil acidity effect. Relative grain yield was calculated as the ratio of grain yield in lime untreated to lime treated soil also showed higher significant differences among the tested genotypes. Genotypes such as Dimtu, new BILFA 58, Beshbesh, SER176, new BILFA51 and new BILFA 61 gave higher absolute and relative yield, whereas Dinknesh, Chore, Nasser and new BILFA 60 gave lower absolute grain and relative yield. Moreover, the great variability of 25 common bean genotypes exhibited a good potential to screening large germplasm of common bean for soil acidity tolerance and develop a cultivar that are tolerant to soil acidity in the country.
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Abdenna Deressa, Negassa Chewaka and Tilahun Geleto.( 2007). Inventory of Soil Acidity Statusin Crop Lands of Central and Western Ethiopia. (http://www.tropentag.de/2007/abstracts/links/De ressa_kmwmgGas.pdf).
Arya, P.S., Ajai, R. and Rana, A. (1999). Study of direct and indirect influence of some yield traits on green pod yield in French bean (Phaseolus vulgaris L.). Advances in Horticulture and Floriculture 6:99-106.
Assady, B., Dorri, H.R. and Vaezi, S. (2005). Study of genetic diversity of bean (Phaseolus vulgaris L.) genotypes by multivariate analysis methods. The first Iranian Pluses symposium, research centre for plant sciences. Ferdowsi University of Mashhad, Mashhad, Iran. Pp.650.
Bambara, S. and Ndakidemi, PA. (2010). The potential roles of lime and molybdenum on the growth, nitrogen fixation and assimilation of metabolites in nodulated legume: A special referenceto Phaseolus vulgaris L. African Journal of Biotechnology 8(17):2482-2489.
Bray, R.H. and Kurtz, LT. (1945). Determination of total organic and available phosphorus in soils. Soil Science 59:39-45.
Changezi, M.S., Khaghani and Khaghani, S. (2005). Trait correlations and yield component analysis of local beans in Arak. The first Iranian pulse symposium, research centre for plant sciences, Ferodwsi University of Mashad, Iran.Pp.321.
CSA (Central Statistical Authority). (2012). Crop production Forecast sample survey. Report on area and crop production forecast for major grain crops. Bulletin Statistics, Vol. I, Addis Ababa, Ethiopia.
Dursun, A. (2007). Variability, heritability and correlation studies in bean (Phaseolus vulagris L.) genotypes. World Journal of Agricultural Sciences 3(1): 12-16.
Eswaran, H., Reich, P. and Beinroth, F. (1997). Global distribution of soils with acidity. In: Plant- Soil Interactions at Low pH. Moniz, A.C (eds.). Brazilian Soil Science Society. Pp. 159-164.
Evans, L. S., Lewin, K.F. and Vella, FA. (1980). Effect of nutrient pH on symbiotic nitrogen fixation by Rhizobium leguminosarum and Pisum sativum. Plant and Soil 56: 71-80.
Fageria, N.K., Santos, A.B. and Baligar, V.C. (1997). Phosphorous Soil Test Calibration for Lowland Rice on an Inceptisol. Agronomy Journal 89:737–742.
Fisher, J.A. and Scott, B.J. (1987). Response to selection for aluminum tolerance. In: PGE Searle, BG Davey, eds, Priorities in Soil/Plant Relations: Research for Plant Production. The University of Sydney, Sydney, Australia, pp 135- 137
Foy, C.D. (1988). Plant adaptation to acid, aluminum toxic soils. Commendams of Soil Science. Plant Analysis 19:959–987.
Foy, C.D., Fleming, A.L. and Gerloff, G.C. (1972). Differential aluminium tolerance in two snap bean varieties. Agronomy Journal 64:815–818.
Foy, C.D. (1984). Physiological effects of hydrogen, aluminum, and manganese toxicities in acid soil. In: Soil Acidity and Liming. Adams, F. (ed.). American Society of Agronomy, Inc., Madison, WI. pp. 57-97.
Jackson, M.L. (1958). Soil Chemical Analysis. Prentice Hall Inc., Engle Wood Cliffs, NJ, USA. Subtropics. Longman Scientific and technical, Essex, New York.
Johnson, J.P., Craver, B.F. and Baligar V.C. (1997). Productivity in Great Plains acid soils of wheat genotypes selected for aluminium tolerance. Plant and Soil 188: 101-106.
Kochian, L.V., Hoekenga, O.A. and Piners, M.A. (2004). How do crop plants tolerate acid soils: Mechanism of aluminum tolerance and phosphorus efficiency. Annual Review of Plant Biology 55: 459-493.
Kumar, J., Singh, H., Singh, T., Tonk, D.S., Lal, R. (2002). Correlation and path coefficient analysis of yield and its components in summer mung (Vigna radiata L.). Crop Research 24: 374-377.
Manrique, G., Rao, I.M., Beebe, S. (2006). Identification of aluminum resistance common bean genotypes using hydroponic screening method. Paper presented at the 18th world congress of soil sciences, Philadephia, USA, July 9-15.
McLean, E.O. (1965). Aluminium. pp. 978-998. In:
C.A. Black (Ed.). Methods of Soil Analysis. Agronomy. No. 9. Part II. American Society of Agronomy, Madison, Wisconsin, USA.
Meda, A.R. and Furlani, P.R. (2005). Tolerance to Aluminum Toxicity by Tropical Leguminous Plants Used as Cover Crops. Brazilian Archives of Biology and Technology 48(2):309-317.
Mesfin Abebe. (2007). Nature and Management Of Acid Soils In Ethiopia. Addis Ababa, Ethiopia.
Noble, A.D., Lea, J.D., and Fey, M.V. (1985).
Genotypic tolerance of selected dry bean (Phaseolus vulgaris L.) cultivars to soluble Al and to acid, low P soil conditions. South African Journal of Plant Soil 2:113-119.
Oluwatoyinbo, F.I., Akande M.O. and. Adediran J.A. (2005). Response of Okra (Abelmoschus esculentus) to Lime and Phosphorus Fertilization in an Acid Soil. World Journal of Agricultural Sciences 1(2):178-183,
Piha, M. I. and Munns, D. N. (1987). Sensitivity of common bean (Phaseolus vulgaris L.) symbiosis to high soil temperatures. Plant and Soil 98:183- 194.
Rangel, A.F., Mobin, M., Rao, I.M. and Horst, W.J. (2005). Proton toxicity interferes with the screening of common bean (Phaseolus vulgaris L.) genotypes for aluminium resistance in nutrient solution. Journal of Plant Nutrition and Soil Science 168:607-616.
Rao, IM. (2001). Role of physiology in improving crop adaptation to abiotic stresses in the tropics: the case of common bean and tropical forages. Marcel Dekker, New York, USA, pp 583-613
Rao, I.M., Beebe, S., Ricaurte, J., Teran, H. and Singh, S. (2004). Common bean (Phaseolus vulgaris L.) genotypes tolerant to aluminium toxicity soils in the tropics. Proceedings of the 6th International symposium on plant Soil interactions at low pH (PSILP) held in Sendai, Japan from 31 July to 5, August 2004. Japanese society of sol science and Plantnutria., Sendai, Japan, pp. 272-273.
Rout, G.R., Samantaray, S. and Das, P. (2001). Aluminium toxicity in plants:a review. Agronomie 21: 2-21.
Salehi, M., Tajik, M. and Ebadi, A.G. (2008). The study of relationship between different traits in common bean (Phaseolus vulgaris L.) with multivariate statistical methods. American- Eurasian Journal of Agricultural & Environmental Science 3: 806-809.
SAS Institute Inc. (2004). SAS/STAT User's Guide: Version 9.1th edn. SAS Institute Inc., Cary,North Carolina.
Setegn, Gebeyehu. (2006). Physiological response to drought stress of common bean (Phaseolus vulgaris L.) genotypes differing in drought resistance. PhD Dissertation, Gottingen University, Germany.
Tesso, B. (2007). Yield and canning quality attributes of Navy beans (Phaseolus vulgaries L.) as influenced by genotype and environment(un Published MSc Thesis, 2007), Haramaya University
Thompson, M. and Banerjee, E.K. (1991). In: Haswell, S.J. (ed.) Atomic absorption spectrometery, Elsevier, Amsterdam, pp 289- 320.
.Vargas, A. A. T. and Graham, P. H. (1989). Cultivar and pH effect on competition for nodule sites between isolates of Rhizobium in beans. Plant and Soil 17: 195-200.
Walkley, A. and Black, C.A. (1934). An examination of Detergent method for determining soil organic matter and proposed modification of the proposed modification of the chromic acid titration method. Soil Science 37: 29-38
Wang, J., Raman, H. Zhang, G. Mendham, N. and Zou, M. (2006). Aluminium tolerance in barely (Horidium vulgaris L.):Physiological mechanisms, genetic and screening methods. Journal of Zhejiang University Science 7: 769-787.
Zhang, Xiao-Bin, Peng, L., Yang, Y.S. and Gen-Di xu. (2007). Effect of Al in soil on photosynthesis and related morphological and physiological characteristics of two soybean genotypes. Botanical Studies 48: 435-444.
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