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Vol. 9 No. 2 (2010)

Articles

THE EFFECT OF DIVERSE IODINE FERTILIZATION ON NITRATE ACCUMULATION AND CONTENT OF SELECTED COMPOUNDS IN RADISH PLANTS (Raphanus sativus L.)

Submitted: January 20, 2021
Published: 2010-06-30

Abstract

Plant fertilization with iodine may be an alternative source of this element in human diet. Iodine influence on nitrogen metabolism in plants has not yet been thoroughly described. Thus, there is an urgent need to determine the effect of iodine application on nitrate(V) accumulation in plants. The aim of the study was to determine the influence of soil and foliar application of iodine forms (I-, IO3-) on nitrate accumulation and concentration of selected compounds in radish plants. The following treatments were applied in the experiment: 1 – control (without application of iodine), 2 – foliar application in KI form, 3 – foliar application in KIO3 form, 4 – soil fertilization in KI form, 5 – soil fertilization in KIO3 form, 6 – soil fertilization in KI form + foliar application in KI form, 7 – soil fertilization in KIO3 form + foliar application in KIO3 form. Soil fertilization with iodine was carried out before radish sowing to the level of 15 mg I·dm-3 soil. Foliar application of this element was performed twice using iodine solution in a concentration per pure element of 0.2%, in dose of 0.4 dm3· m-2. In all tested combinations with iodine treatment an increase of ammonium ion content in radish roots was observed in comparison to the control. Both, foliar nutrition with KI as well as nitrogen fertilization with KIO3
(combination 2 and 6, respectively) resulted in a significant increase of free amino acids concentration in radish roots. No significant influence of tested factors was noted for the root and leaf content of: dry mass, nitrates(V), nitrates(III) as well as root level of total soluble sugars and leaf concentration of photosynthetic pigments and ammonium ions in radish.

References

Arnon, D. J., 1949. Coppre enzymes isolated chloroplast oxidase in Beta vulgaris. Plant Physiology 24, 1–15.
Borst-Pauwels G.W.F.H., 1961. Iodine as a micronutrient for plants. Plant Soil 14 (4), 377–392.
Dai J-L, Zhu Y-G, Zhang M, Huang Y-Z., 2004. Selecting iodine-enriched vegetables and the residual effect of iodate application to soil. Biol. Trace Element Res. 101, 265–276.
Dai J.L., Zhu Y.G., Huang Y.Z., Zhang M., Song J.L., 2006. Availability of iodide and iodate to spinach (Spinacia oleracea L.) in relation to total iodine in soil solution. Plant and Soil 289, 301–308.
Hong Chun-Lai, Weng Huan-Xin, Qin Ya-Chao, Yan Ai-Lan, Xie Ling-Li, 2008. Transfer of iodine from soil to vegetables by applying exogenous iodine. Agron. Sustain. Dev vol. 28, no 4, pp. 575–583. (DOI: 10.1051/agro:2008033)
Hung C.C., Wong G.T.F., Dunstan W.M., 2005. Iodate reduction activity in nitrate reductase extracts from marine phytoplankton. Bull. Marine Sci.76 (1), 61–72
Jacobson MF., 2009. Salt The Forgotten Killer. Centre for Science in the Public Interest Washington, D.C. (http://cspinet.org/new/pdf/saltreport/pdf)
Kabata-Pendias A., Mukherjee A.B., 2007. Trace elements from soil to human. Springer.
Korenman S., 1973. Photometric analysis. Wyd. Nauk.-Tech., Warszawa, Poland. [In Polish].
Laurens S., Commanay L., 1970. Influence of sodium iodine concentration on the nitrogen metabolism of marine organism: Microcosmus sabatieri R. CR Seances Soc. Biol. Fil. 25, 164(2), 455–459 (in French).
Ledwożyw I., Smoleń S., Strzetelski P., 2009. Wpływ sposobu biofortyfikacji jodem na wielkość oraz jakość plonu sałaty gruntowej (badania wstępne). Zesz. Nauk. UR w Krakowie. In print.
Ledwożyw I., Kołton A., Smoleń S., Strzetelski P., 2010. Wpływ dokarmiania dolistnego sałaty gruntowej jodem na aktywność reduktazy azotanowej i azotynowej w liściach Zesz. Nauk. UR w Krakowie. In print
Mackowiak C.L., Grossl P.R., Cook K.L., 2005. Iodine toxicity in a plant-solution system with and without humic acid. Plant and Soil (2005) 269, 141–150.
Maćkowiak CL., Grossl PR., 1999. Iodate and iodine effect on iodine uptake and partitioning (Oryza sativa L.) grown in solution culture. Plant and Soil, 212 (2), 135–143.
Nowosielski O., 1988. Zasady opracowywania zaleceń nawozowych w ogrodnictwie. Warsaw, Poland, PWRiL.
PN-EN ISO 11732:2005 (U). Water quality. Determination of ammonium nitrogen. Method by flow analysis (CFA and FIA) and spectrometric detection. [In Polish].
PN-EN ISO 13395:2001. Water quality – Determination of nitrite nitrogen and nitrate and the sum of both by flow analysis (CFA and FIA) and spectrometric detection. [In Polish].
Smoleń S., Ledwożyw I., Strzetelski P., Sady W., Rożek S., 2009a. Wpływ nawożenia jodem i azotem na efektywność biofortyfikacji w jod oraz na jakość biologiczną marchwi. Ochrona Środ. i Zasobów Natur. 40, 313–320.
Smoleń S., Sady W., Strzetelski P., Rożek S., Ledwożyw I., 2009b. Wpływ nawożenia jodem i azotem na wielkość i jakość plonu marchwi. Ochrona Środ. i Zasobów Natur. 40, 286–292.
Strzetelski P., Smoleń S., Rożek S., Sady W., 2009. The effect of differentiated fertilization and foliar application of iodine on yielding and antioxidant properties in radish (Raphanus sativus L.) plants. Ecol. Chemistry Eng. In print
Strzetelski P., 2005. Występowanie i przemieszczenie jodu w systemie gleba-roślina. Post. Nauk Rol. 6, 85–100.
Waite T.J., Truesdale V.W., 2003. Iodate reduction by Isochrysis galbana is relatively insensitive to de-activation of nitrate reductase activity: are phytoplankton really responsible for iodate reduction in seawater? Marine chemistry. 81 (3–4), 137–148.
WHO. 2007. Reducing Salt intake in populations. Report of a WHO Forum and Technical Meeting.” Geneva, World Health Organization, (http://www.who.int/dietphysicalactivity/Salt_Report_VC_april07.pdf, assessed on 16th April 2007).
Xia ST., Peng KQ., Xiao LT., Liu ZM., 2003. Effects of iodine application on growth and content of iodine, amino acid, vitamin C and fiber in radish sprouts. Acta Hort. Sinica 30 (2), 218–220.
Yemm, E. W., Wills A. J., 1954. The estimation of carbohydrates in plant extracts by antrone. Biochem. J. 57, 508–514.

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