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Year 2018, Volume: 2 Issue: 2, 171 - 179, 08.12.2018

Abstract

References

  • Anghinoni I., Barber S. A., 1980. Phosphorus influx and growth characteristics of corn roots as influenced by phosphorus supply. Agronomy Journal, 72:685-688.
  • Araujo R., Macedo S., Korn M., Pimentel M., Bruns R., Ferreira S., 2008. Mineral composition of wheat flour consumed in Brazilian cities. Journal of Brazilian Chemical Society, 19:935–942.
  • Bagayoko M., George E., Romheld, V., Buerkert, A.B., 2000. Effects of mycorrhizae and phosphorus on growth and nutrient uptake of millet, cowpea and sorghum on a West African soil. Journal of Agricultural Science, 135: 399-407.
  • Balligar V.C., Fageria N.K, Elrashidi M.A., 1998. Toxicity and nutrient constraints on root growth. HortScience, 33:960-965.
  • Bargaz A., Noyce G.L., Fulthorpe R., Carlsson G., Furze J.R., Jensen E.S., Dhiba D., Isaac, M.E., 2017. Species interactions enhance root allocation, microbial diversity and P acquisition in intercropped wheat and soybean under P deficiency. Applied Soil Ecology, 120: 179-188.
  • Canny, M.J. 1984. Advanced plant physiology. Pitman Publishing, London, UK.
  • Choi I., Kang C.S., Hyun J.N., Choon-Ki Lee C.K., Park, K.G., 2013. Mineral compositions of korean wheat cultivars. Preventive Nutrition and Food Science, 18(3): 214-217.
  • Davis D.R., 2009. Declining fruit and vegetable nutrient composition: What is the evidence? HortSciences, 44: 15–19.
  • Fageria N.K., Baligar V.C., Clark R.B., 2006. Physiology of crop production. The Haworth Press, New York.
  • Fageria, N.K. 2013. The role of plant roots in crop production. CRC Press, Boca Raton, FL.
  • Fageria, N.K., Moreira A.B., Santos A., 2013. Phosphorus uptake and use efficiency in field crops. Journal of Plant Nutrition, 36:2013–2022.
  • Fageria, N.K., Moreira A., 2011. The role of mineral nutrition on roots growth of crop plants. Advances in Agronomy, 110: 251-331.
  • Faye I., Diouf O., Guisse A., Sene M., Diallo N., 2006. Characterizing root responses to low phosphorus in pearl millet (Pennisetumglaucum L. R. Br.). Agronomy Journal, 98:1187-1194.
  • Gücdemir İ.H., 2006. Türkiye gübre ve gübreleme rehberi. 5. Baskı. Tarım ve Köyişleri Bakanlığı Tarımsal Araştırmalar Genel Müdürlüğü Toprak ve Gübre Araştırma Enstitüsü Yayınlan, Genel Yayın No: 231, Teknik Yayın No: 69, Ankara.
  • Hinsinger P., 2004. Nutrient availability and transport in the rhizo¬sphere. In Encyclopedia of Plant and Crop Science (R.M Goodman, ed.), pp. 1094–1097. Marcel Dekker, New York.
  • Hussain Z., Khattak R.A., Irshad M., Mahmood Q., An P., 2016. Effect of saline irrigation water on the leachability of salts, growth and chemical composition of wheat (Triticum aestivum L.) in saline-sodic soil supplemented with phosphorus and potassium. Journal of Soil Science and Plant Nutrition, 16: 604-620.
  • Jarrell W.M., Beverly R.B., 1981. The dilution effect in plant nutri¬tion studies. Advances in Agronomy, 34: 197–224.
  • Kacar B., 2012. Toprak analizleri. Nobel Akademik Yayıncılık, Ankara.
  • Kacar B., 2013. Temel bitki besleme. Nobel Yayınları, Ankara.
  • Liebersbach H., Steingrobe B., Claassen N., 2004. Roots regulate ion transport in the rhizosphere to counteract reduced mobility in dry soil. Plant and Soil,260:79-88.
  • Lynch J., Lauchli A., Epstein E., 1991. Vegatative growth of the common bean in response to phosphorus nutrition. Crop Science, 31:380-387.
  • Marschner H., 1995. Mineral nutrition of higher plants. 2nd Ed. p. 1-889. Academic Pres, New York.
  • Marschner, P., 2012. Marschner’s mineral nutrition of higher plants. 3rd edition, Academic Press, London.
  • Osaki M., 1995. Ontogenetic changes of N, P, and K contents in individual leaves of field crops. Soil Science and Plant Nutrition, 41:429–438.
  • Robinson A.D., Pitman J.B., 1983. Interactions between nutrients in higher plants. In: Inorganic Plant Nutrition: Encyclopedia of Plant Physiology, vol. 1A, eds. A. Lauchli and R. L. Bieleski, pp. 147–180. Springer-Verlag, New York.
  • Smith F.W., Jackson W.A., Vberg P.J., 1990. Internal phosphorus flows during development of phosphorus stress in Stylosanthes hamata. Australian Journal of Plant Physiology, 17:451-464.
  • Tisdale S.L., Nelson W.L., Beaton J.D., 1985. Soil Fertility and Fertilizers. Macmillan Publishing Company, New York.
  • TUIK, 2018. https://biruni.tuik.gov.tr/medas/?kn=92&locale=tr (erişim tarihi: 28.09.2018)
  • USDA, 2017. https://www.fas.usda.gov/
  • Uygur V., Karabatak I., 2009. The effect of organic amendments on mineral phosphate fractions in calcareous soils. Journal of Plant Nutrition and Soil Science, 172: 336-345.
  • Wilkinson S.R., Grunes D.L., Sumner M.E., 2000. Nutrient interactions in soil and plant nutrition. In: Handbook of Soil Science, ed. M. E. Sumner, pp. D-89–D-111. CRC Press, Boca Raton, FL.
  • Zhang Y., Song Q., Yan J., Tang J., Zhao R., Zhang Y., He Z., Zou C., Ortiz-Monasterio I., 2010. Mineral element concentrations in grains of Chinese wheat cultivars. Euphytica, 174: 303-313.

THE EFFECT OF PHOSPHORUS APPLICATION ON NUTRIENT UPTAKE AND TRANSLOCATION IN WHEAT CULTIVARS

Year 2018, Volume: 2 Issue: 2, 171 - 179, 08.12.2018

Abstract

Phosphorus (P) in soils is ultimately deficient plant nutrient that has
astonishing impacts over crop production especially under rain-fed agricultural
conditions. Typically, P deficiency in plants is to stimulate root growth. This
response influences the balance of all plant nutrients, including P nutrition,
in varieties with different root / stem development. For this reason, the
effects of P fertilization on nutrient composition of both straw and grain for 12
bread and 3 durum wheat varieties, which are widely cultivated in the
Mediterranean Region under rain-fed conditions, were studied with and without P
application. The experiment was set-up in completely randomised design in
factorial arrangement with three replications. In the experiment, nitrogen (N),
potassium (K) and zinc (Zn) were applied to all pots; P was administered at a
dose of 0 and 50 mg kg-1. Nitrogen, P, K, calcium (Ca), magnesium
(Mg), sodium (Na), iron (Fe), copper (Cu), Zn and manganese (Mn) concentrations
were determined in both the straw and grains of the harvested plants.
Phosphorous fertilization affected the concentration of P, N and Mn in the
grain positively, while it affected the concentration of Ca, Mg, Na, Fe, Cu and
Zn negatively, while K did not change the concentration. In straw, N
concentration was not affected by P fertilization; Fe and Na concentrations
were to accumulate in the straw; Cu, Mn, Zn, P, Ca, Mg and K concentrations
were to decrease. On the other hand, varieties showed different responses to P
fertilization in terms of their nutrient composition. Consequently, the
susceptibility of the varieties to phosphorus deficiency significantly changed
the nutrient uptake and partition of the plant nutrients between grain and
straw.

References

  • Anghinoni I., Barber S. A., 1980. Phosphorus influx and growth characteristics of corn roots as influenced by phosphorus supply. Agronomy Journal, 72:685-688.
  • Araujo R., Macedo S., Korn M., Pimentel M., Bruns R., Ferreira S., 2008. Mineral composition of wheat flour consumed in Brazilian cities. Journal of Brazilian Chemical Society, 19:935–942.
  • Bagayoko M., George E., Romheld, V., Buerkert, A.B., 2000. Effects of mycorrhizae and phosphorus on growth and nutrient uptake of millet, cowpea and sorghum on a West African soil. Journal of Agricultural Science, 135: 399-407.
  • Balligar V.C., Fageria N.K, Elrashidi M.A., 1998. Toxicity and nutrient constraints on root growth. HortScience, 33:960-965.
  • Bargaz A., Noyce G.L., Fulthorpe R., Carlsson G., Furze J.R., Jensen E.S., Dhiba D., Isaac, M.E., 2017. Species interactions enhance root allocation, microbial diversity and P acquisition in intercropped wheat and soybean under P deficiency. Applied Soil Ecology, 120: 179-188.
  • Canny, M.J. 1984. Advanced plant physiology. Pitman Publishing, London, UK.
  • Choi I., Kang C.S., Hyun J.N., Choon-Ki Lee C.K., Park, K.G., 2013. Mineral compositions of korean wheat cultivars. Preventive Nutrition and Food Science, 18(3): 214-217.
  • Davis D.R., 2009. Declining fruit and vegetable nutrient composition: What is the evidence? HortSciences, 44: 15–19.
  • Fageria N.K., Baligar V.C., Clark R.B., 2006. Physiology of crop production. The Haworth Press, New York.
  • Fageria, N.K. 2013. The role of plant roots in crop production. CRC Press, Boca Raton, FL.
  • Fageria, N.K., Moreira A.B., Santos A., 2013. Phosphorus uptake and use efficiency in field crops. Journal of Plant Nutrition, 36:2013–2022.
  • Fageria, N.K., Moreira A., 2011. The role of mineral nutrition on roots growth of crop plants. Advances in Agronomy, 110: 251-331.
  • Faye I., Diouf O., Guisse A., Sene M., Diallo N., 2006. Characterizing root responses to low phosphorus in pearl millet (Pennisetumglaucum L. R. Br.). Agronomy Journal, 98:1187-1194.
  • Gücdemir İ.H., 2006. Türkiye gübre ve gübreleme rehberi. 5. Baskı. Tarım ve Köyişleri Bakanlığı Tarımsal Araştırmalar Genel Müdürlüğü Toprak ve Gübre Araştırma Enstitüsü Yayınlan, Genel Yayın No: 231, Teknik Yayın No: 69, Ankara.
  • Hinsinger P., 2004. Nutrient availability and transport in the rhizo¬sphere. In Encyclopedia of Plant and Crop Science (R.M Goodman, ed.), pp. 1094–1097. Marcel Dekker, New York.
  • Hussain Z., Khattak R.A., Irshad M., Mahmood Q., An P., 2016. Effect of saline irrigation water on the leachability of salts, growth and chemical composition of wheat (Triticum aestivum L.) in saline-sodic soil supplemented with phosphorus and potassium. Journal of Soil Science and Plant Nutrition, 16: 604-620.
  • Jarrell W.M., Beverly R.B., 1981. The dilution effect in plant nutri¬tion studies. Advances in Agronomy, 34: 197–224.
  • Kacar B., 2012. Toprak analizleri. Nobel Akademik Yayıncılık, Ankara.
  • Kacar B., 2013. Temel bitki besleme. Nobel Yayınları, Ankara.
  • Liebersbach H., Steingrobe B., Claassen N., 2004. Roots regulate ion transport in the rhizosphere to counteract reduced mobility in dry soil. Plant and Soil,260:79-88.
  • Lynch J., Lauchli A., Epstein E., 1991. Vegatative growth of the common bean in response to phosphorus nutrition. Crop Science, 31:380-387.
  • Marschner H., 1995. Mineral nutrition of higher plants. 2nd Ed. p. 1-889. Academic Pres, New York.
  • Marschner, P., 2012. Marschner’s mineral nutrition of higher plants. 3rd edition, Academic Press, London.
  • Osaki M., 1995. Ontogenetic changes of N, P, and K contents in individual leaves of field crops. Soil Science and Plant Nutrition, 41:429–438.
  • Robinson A.D., Pitman J.B., 1983. Interactions between nutrients in higher plants. In: Inorganic Plant Nutrition: Encyclopedia of Plant Physiology, vol. 1A, eds. A. Lauchli and R. L. Bieleski, pp. 147–180. Springer-Verlag, New York.
  • Smith F.W., Jackson W.A., Vberg P.J., 1990. Internal phosphorus flows during development of phosphorus stress in Stylosanthes hamata. Australian Journal of Plant Physiology, 17:451-464.
  • Tisdale S.L., Nelson W.L., Beaton J.D., 1985. Soil Fertility and Fertilizers. Macmillan Publishing Company, New York.
  • TUIK, 2018. https://biruni.tuik.gov.tr/medas/?kn=92&locale=tr (erişim tarihi: 28.09.2018)
  • USDA, 2017. https://www.fas.usda.gov/
  • Uygur V., Karabatak I., 2009. The effect of organic amendments on mineral phosphate fractions in calcareous soils. Journal of Plant Nutrition and Soil Science, 172: 336-345.
  • Wilkinson S.R., Grunes D.L., Sumner M.E., 2000. Nutrient interactions in soil and plant nutrition. In: Handbook of Soil Science, ed. M. E. Sumner, pp. D-89–D-111. CRC Press, Boca Raton, FL.
  • Zhang Y., Song Q., Yan J., Tang J., Zhao R., Zhang Y., He Z., Zou C., Ortiz-Monasterio I., 2010. Mineral element concentrations in grains of Chinese wheat cultivars. Euphytica, 174: 303-313.
There are 32 citations in total.

Details

Primary Language English
Journal Section Original Papers
Authors

Veli Uygur

Mustafa Şen This is me

Publication Date December 8, 2018
Submission Date November 14, 2018
Acceptance Date December 6, 2018
Published in Issue Year 2018 Volume: 2 Issue: 2

Cite

APA Uygur, V., & Şen, M. (2018). THE EFFECT OF PHOSPHORUS APPLICATION ON NUTRIENT UPTAKE AND TRANSLOCATION IN WHEAT CULTIVARS. International Journal of Agriculture Forestry and Life Sciences, 2(2), 171-179.
AMA Uygur V, Şen M. THE EFFECT OF PHOSPHORUS APPLICATION ON NUTRIENT UPTAKE AND TRANSLOCATION IN WHEAT CULTIVARS. Int J Agric For Life Sci. December 2018;2(2):171-179.
Chicago Uygur, Veli, and Mustafa Şen. “THE EFFECT OF PHOSPHORUS APPLICATION ON NUTRIENT UPTAKE AND TRANSLOCATION IN WHEAT CULTIVARS”. International Journal of Agriculture Forestry and Life Sciences 2, no. 2 (December 2018): 171-79.
EndNote Uygur V, Şen M (December 1, 2018) THE EFFECT OF PHOSPHORUS APPLICATION ON NUTRIENT UPTAKE AND TRANSLOCATION IN WHEAT CULTIVARS. International Journal of Agriculture Forestry and Life Sciences 2 2 171–179.
IEEE V. Uygur and M. Şen, “THE EFFECT OF PHOSPHORUS APPLICATION ON NUTRIENT UPTAKE AND TRANSLOCATION IN WHEAT CULTIVARS”, Int J Agric For Life Sci, vol. 2, no. 2, pp. 171–179, 2018.
ISNAD Uygur, Veli - Şen, Mustafa. “THE EFFECT OF PHOSPHORUS APPLICATION ON NUTRIENT UPTAKE AND TRANSLOCATION IN WHEAT CULTIVARS”. International Journal of Agriculture Forestry and Life Sciences 2/2 (December 2018), 171-179.
JAMA Uygur V, Şen M. THE EFFECT OF PHOSPHORUS APPLICATION ON NUTRIENT UPTAKE AND TRANSLOCATION IN WHEAT CULTIVARS. Int J Agric For Life Sci. 2018;2:171–179.
MLA Uygur, Veli and Mustafa Şen. “THE EFFECT OF PHOSPHORUS APPLICATION ON NUTRIENT UPTAKE AND TRANSLOCATION IN WHEAT CULTIVARS”. International Journal of Agriculture Forestry and Life Sciences, vol. 2, no. 2, 2018, pp. 171-9.
Vancouver Uygur V, Şen M. THE EFFECT OF PHOSPHORUS APPLICATION ON NUTRIENT UPTAKE AND TRANSLOCATION IN WHEAT CULTIVARS. Int J Agric For Life Sci. 2018;2(2):171-9.

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