Effect of Foliar Application of Potassium Silicate and Amino Acids on Growth, Yield and Fruit Quality of 'keitte' Mango Trees | ||||
Journal of the Advances in Agricultural Researches | ||||
Article 13, Volume 24, Issue 2 - Serial Number 92, June 2019, Page 238-251 PDF (835.96 K) | ||||
Document Type: Research papers | ||||
View on SCiNiTO | ||||
Authors | ||||
Mahmoud Ali1; Mohamed Mohamed Harhash1; Rabea Ibrahim Mahmoud2; Salah AbdelAtey Kabel2 | ||||
1Plant Production Dept., Faculty of Agric., Saba Bacha, Alex. Univ. | ||||
2Hort. Res. Institute, Agric. Res. Center, Giza, Egypt | ||||
Abstract | ||||
This study was carried out during the two successive seasons 2016 and 2017 on seven years old 'keitte' mango trees (mangifera indica L.) budded on succary rootstock, grown in a sandy soil under drip irrigation system in a private orchard located at El-Shagaa Village El-Nubaria, Beheira Governorate, Egypt. The aim of this research was to investigate the effect of foliar application of potassium silicate at (5, 10 and15 cm3/l) and amino acids at (2.5, 5 and 7.5 cm3/l) single or mixed on growth, yield and fruit quality of 'keitte' mango trees at two application time; the first application time was taken place at beginning growth season in march, while the second application was after fruit set. The experimental design was randomized complete block design with four replicates. Results indicated that foliar application of potassium silicate and amino acids significantly increased vegetative growth of 'keitte' mango by 15 cm3/l potassium silicate plus 7.5 cm3/l amino acids was increased vegetative growth as shoot length and shoot thickens and number of leaves/shoot but leaf area increased by spring 5 cm3/l potassium silicate plus 5 cm3/l amino acids. on the other hand potassium silicate at 15 cm3/l plus amino acids at 7.5 cm3/l treatment, significantly increased fruit weight, yield kg/ tree and total yield (ton/feddan). However, foliar application of amino acids at 10 cm3 /l treatment significantly increased fruit length (cm). Amino acids at 7.5 cm3/l treatment significantly increased fruit length/ diameter ratio as compared with control. Foliar application of potassium silicate at 10 cm3/l + amino acids at 7.5 cm3/l treatment was increased total soluble solids at the second season but decreased fruit juice acidity (%) as compared with the control. Moreover, spraying 'keitte' mango trees potassium silicate at 10 cm3/l plus amino acids at 7.5 cm3/l treatment increased vitamin C on fruit juice at both season. | ||||
Keywords | ||||
'keitte' mango; potassium silicate; amino acids; growth; yield; fruit quality | ||||
References | ||||
Abd El-Gawad, N. H. G., A. I. Abu El-Azm and M. S. Hikal (2017). Effect of potassium silicate on tuber yield and biochemical constituents of potato plants grown under drought stress conditions. Middle East J. Agri. Res., 6 (3):718-731.
Abd El-Rahman, M. M. A. (2015). Relation of spraying silicon with fruiting of Keitte mango trees growing under Upper Egypt conditions. Stem Cell, 6 (2):1-5.
Abd El-Razek, E. and M. M. S. SaleH (2012). Improve productivity and fruit quality of 'Florida Prince' peach trees using foliar and soil applications of amino acids. Middle-East J. Sci. Res., 12 (8): 1165-1172.
Abdel Gawad, N. M. A. (2017). Effect of some treatments for overcoming frost injury and improving productivity also fruit quality of mango (mangifera indica l.) c.v.” hindi khasa”. Middle East J. App. Sci. 7 (2): 373-384.
Ahmed, F. F. and M. H. Morsy (1999). A new method for measuring leaf area in different fruit species. Minia J. Res. and develop., 19: 97-105.
Ahmad, A., M. Afzal, , A.U. H. Ahmad, and M. Tahir (2013a). Effect of foliar application of silicon on yield and quality of rice (Oryza sativa L.). Cercetari Agronomice in Moldova. XLVI, 3 (155): 21-28.
Ahmed, F. F., A. E. M. Mansour, A. Y. Mohamed, E. A. M. Mostafa, and N. E. Ashour (2013b). Using silicon and salicylic acid for promoting production of 'Hindybisinnara' mango trees grown under sandy soil. Middle East J. Agri. Res. 2 (2): 51-55.
Ahmed, F. F., M. Kh. Kamel and H. L. M. Ibrahim (2014). The synergistic effect of using plant extracts and salicylic acid on yield and fruit quality of 'Keitte' mango trees. Stem Cell. 5 (2): 30-39.
Amr M. E. and M. G. Alaa (2017). fruiting of 'keitte' mango trees in relation to application of glutathione and boron hortScience journal of suez canal university, volume 6 (1): 73-80
AOAC (1985). Official methods of analysis of the association of official analytical chemists. washington D C, USA, 14th Ed.
Belal, B. E. A., M. A. El-Kenawy and M. K. U. Wakiem (2016). Foliar application of some amino acids and vitamins to improve growth, physical and chemical properties of flame seedless grapevines. Egypt. J. Hort. 43(1):123-136.
Chen, B. M. and W. M. Mellenthin (1981). Effect of harvest date on ripening capacity and post – harvest life of Anjou pears. J. Amer. Soc. Hort. Sci., 106: 38-42.
Costa, I. J. S., M. C. T. Pereira, G. P. Mizobutsi, V. M. Maia, J. F. Silva, J. A. A. Oliveira, M. B. Oliveira, V. N. R. Souza, S. Nietsche , E. F. Santos, and G. H. Korndorfer (2015). Influence of silicon fertilization on 'palmer' mango tree cultivation. Acta. Hortic. 26 (10):17660.1075.
Elade, Y. (1992). The use of antioxidants to control gray mould (Botrytic cinerg) and white mould (Scletotinia sclerotiorum) in various crops. Plant Pathol., 141: 417-426.
El-Gioushy, S. F. (2016). Productivity, fruit quality and nutritional status of 'Washington Navel' Orange trees as influenced by foliar application with salicylic acid and potassium silicate combinations. J. Horti. Sci. & Ornamental Plants.8 (2): 98- 107.
El-Hosieny, H. (2015). Effect of ascorbic and salicylic acid on leaf area, n, p, k content as well as yield and its components of mango (Mangifera indica L.) trees. J. Plant Production, M ansoura Univ., 6 (10): 1619 – 1629.
El-Kosary, S., I. E. El-Shenawy and S.I. Radwan (2011). Effect of microelements, amino and humic acids on growth, flowering and fruiting of some mango cultivars. J. Hort. Sci. & Ornamen. Plants, 3 (2): 152-161.
Epstein, E. (1999). Silicon. annu. rev. of plant physiology and plant molecular, biolog, 50: 641-664.
Faissal F. A., K H. K. Mohamed and I. M. I. Hamdy (2014). The synergistic effects of using plant extracts and salicylic acid on yield and fruit quality of 'Keitte' mango trees. Stem Cell. 5 (2): 30-39.
Gad El-Kareem, M. R., A. M. K. Abd El-Aal and A. Y. Mohamed (2014). the synergistic effects of using silicon and selenium on fruiting of Zaghloul Date Palm (Phoenix dectylifera L.). Int. J. Biological, Biomolecular, Agricultural, Food and Biotechnological Engineering. 8 (3):259-262.
Harvath, E., G. Szalai and T. Janda (2007). Induction of abiotic stress tolerance by salicylic acid signaling. J. Plant Growth Regul., 26: 290-300.
Khan, A., S. Hmad, A. Bilal, H. Muhammad, J. Jaskani, R. Ahmad and A. U. Malik (2012). Foliar application of mixture of amino acids and seaweed (Ascophylum nodosum) extract improve growth and physico-chemical properties. Int. J. Agric. Biol., 14 (3): 383–388.
Khattab, M. M., A. E. A. Shaban and A. E. Hassan (2016). Impact of foliar application of calcium, boron and amino acids on fruit set and yield of 'Ewais' and 'Fagry Kelan' mango cultivars. J. Hort. Sci. & Ornamen. Plants, 8 (2): 119-124.
Lee, H. L., J. Leon and I. Raskin (1995). Biosynthesis and metabolism of salicylic acid. Proc. Nati Acad Sci. U.S.A. 92: 4076-4079.
Matichenkov, V. V., D .V. Calvert and G. H. Synder (2000). Prospective of silicon fertilization for citrus in Florida. Proc. Soil and crop Sci. Soc. of Florida 5 pp. 137- 141.
Morales, J. P. (2015). Amino acids on mango yield and fruit quality at submedio são francisco region,brazil. acta. hortic12 (10):17660-1075.
Neumann, D. and M. Zur- Nieden (2011). Silicon and the metal tolerance of higher plants. Phytochmistry 685-692.
Norrie, J., T. Branson and P. E. Keathley (2002). Marine plant extracts impact on grape yield and quality. Acta Hort., 594:315–319.
Rahdari P., B. Panahi and A. Mozaphari (2012). Effect of free amino acids spray on the some nutrient elements accumulation in pistachios (pistachio Vera L.) Ohadi (Fandoghi) cultivar. Advances in Environmental Biology, 6 (5): 1780-1785.
Rao, M. V., J. R. Koch and K. R. Davis (2000). Ozone a total for robbing programmed cell death in plants. Plant Mol. Bid., 44: 346-358.
Raskin, I. (1992). Role of salicylic acid in plant. Ann. Rev. Plant Physiol. Plant Mol. Biol., 43: 439-463.
Satisha, G. C., A. K. Saxena, and A. N. Ganeshamurthy (2017). Effect of silicon and micronutrients on plant growth, yield and disease incidence in chili (Capsicum annum L.). proceedings of abstracts, 7th International conference on silicon in agriculture. pp. 144.
Sendecor, G. W. and W. G. Cochran (1980). Statistical methods. Oxford and J.B.H. Bub Com. State Univ. Press, Ames, Iowa. USA 6th Edition.
Shah, J. (2003). The salicylic acid loop in plant defense. Curr opin plant Biol., 6: 365-371.
Szepesi, A., J. Csiszar, K. Genus, E. Horvath, F. Horvath, M. I. Simon and I. Tari (2009). Salicylic acid improves acclimation to sall stress by stimulating abscisic aldehyde oxidase activity and absisic acid accumulation and increases Na+ content in leaves without toxicity symptoms in (Solanum lycopersicum L.). J. Plant Phys., 166: 914-925.
Taiz, L. and E. Zeiger (2002). Plant physiology. Sunderland: Sinauer, P. 690.
Wassel, A. H. M., A. A. Gobara, H. I. M Ibrahiem, and M. Shaaban-Mai (2015). Response of wonderful pomegranate trees to foliar application of amino acids, vitamins B and silicon. World Rural Observations. 7(3): 91-95. | ||||
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