Evaluation Uptake and Translocation of Iron Oxide Nanoparticles and Its Effect on Photosynthetic Pigmentation of Chrysanthemum (Chrysanthemum morifolium) ‘Salvador’
الموضوعات : مجله گیاهان زینتیSeyed Mohammad Banijamali 1 , Mohammad Feizian 2 , Afsaneh Alinejadian Bidabadi 3 , Ebrahim Mehdipour 4
1 - Ornamental Plants Research Center
2 - Soil Science Department, Faculty of Agriculture, Lorestan University, Khoramabad, Iran.
3 - Soil Science Department, Faculty of Agriculture, Lorestan University, khoramabad, Iran.
4 - Chemistry Department, Faculty of Science, Lorestan University, khoramabad, Iran.
الکلمات المفتاحية: Chlorophyll, Humic acid, Chelate, Chlorosis, Nanofertilizer,
ملخص المقالة :
Recently, the use of superparamagnetic iron oxide nanoparticles (SPIONS) as a new and promising source of iron in agriculture has been suggested that further investigation is needed before extensive field use. In a greenhouse experiment, the effect of coated magnetite nanoparticles with humic acid (Fe3O4/HA NPs) was investigated on iron deficiency chlorosis and photosynthesis efficiency compared to iron chelates of Fe-EDTA (Fe-Ethylenediaminetetraacetic acid) and Fe-EDDHA [Fe-Ethylene diamine-di (o-hydroxyphenylacetic acid)] as control treatments in chrysanthemum cut flower (Chrysanthemum morifolium) in the open hydroponic cultivation system. The feasibility of absorption and translocation of nanoparticles in the plant was evaluated by vibrating sample magnetometry (VSM). The results of tracing by magnetization measurement was demonstrated that NPs penetrated in root and transferred to the aerial parts of chrysanthemum. The greenhouse experiment demonstrated that the application 20 mg/L Fe3O4/HA NPs in nutrient solution significantly (P
Antisari, L.V., Carbone, S., Gatti, A., Vianello, G. and Nannipieri, P. 2015. Uptake and translocation of metals and nutrients in tomato grown in soil polluted with metal oxide (CeO2, Fe3 O4, SnO2, TiO2) or metallic (Ag, Co, Ni) engineered nanoparticles. Environmental Science and Pollution Research, 22: 1841-1853.
Asadifard, R., Tilki, R., Rangbar, M., Dini, M., Arab, A., Gajavand, M. and Moradi, A. 2005. Introduction to nanotechnology laboratory equipment: Measurement and characterization. Nanotechnology Laboratory of Iran. Secretariat of the Headquarters for Nanotechnology Development. Science and Technology, Iran. 158 p. (In Persian)
Aslani, F., Bagheri, S., Muhd Julkapli, N., Juraimi, A.S., Hashemi, F.S.G. and Baghdadi, A. 2014. Effects of engineered nanomaterials on plants growth: An overview. The Scientific World Journal.Volume 2014, Article ID 641759, 28 pages.
Atak, C., Celik, O., Olgun, A., Alikamanoglu, S. and Rzakoulieva, A. 2007. Effect of magnetic field on peroxidase activities of soybean tissue culture. Biotechnology and Biotechnological Equipment, 21 (2): 166-171.
Barak, P. and Chen, Y. 1982. The evaluation of iron deficiency using a bioassay-type test 1. Soil Science Society of America Journal, 46 (5): 1019-1022.
Brackhage, C., Schaller, J., Bäucker, E. and Dudel, E.G. 2013. Silicon availability affects the stoichiometry and content of calcium and micronutrients in the leaves of common reed. Silicon, 5 (3): 199-204.
Bucak, S., Yavuzturk, B. and Sezer, A.D. 2012. Magnetic nanoparticles: Synthesis, surface modifications and application in drug delivery. In: Recent advances in novel drug carrier systems. In Tech. Chapter 7, 36 page.
Chen, Y. and Schnitzer, M. 1978. The surface tension of aqueous solutions of soil humic substances. Soil Science, 125 (1): 7-15.
Cifuentes, Z., Custardoy, L., de la Fuente, J.M., Marquina, C., Ibarra, M.R., Rubiales, D. and Pérez-de-Luque, A. 2010. Absorption and translocation to the aerial part of magnetic carbon-coated nanoparticles through the root of different crop plants. Journal of Nanobiotechnology, 8: 26.
Denre, M., Ghanti, S. and Sarkar, K. 2014. Effect of humic acid application on accumulation of mineral nutrition and pungency in garlic (Allium sativum L.). International Journal of Biotechnology and Molecular Biology Research, 5 (2): 7-12.
DeRosa, M.C., Monreal, C., Schnitzer, M., Walsh, R. and Sultan, Y. 2010. Nanotechnology in fertilizers. Nature Nanotechnology, 5 (2): 91–94.
Ditta, A. and Arshad, M. 2016. Applications and perspectives of using nanomaterials for sustainable plant nutrition. Nanotechnology Reviews, 5 (2): 209-229.
El-Temsah, Y. S. and Joner, E.J. 2012. Impact of Fe and Ag nanoparticles on seed germination and differences in bioavailability during exposure in aqueous suspension and soil. Environmental Toxicology, 27 (1): 42-49.
Fahn, A. 1982. Plant anatomy. Pergamon Press, Oxford UK.
Fang, M., Strom, V., Olsson, R.T., Belova, L. and Rao, K.V. 2012. Particle size and magnetic properties dependence on growth temperature for rapid mixed co-precipitated magnetite nanoparticles. Nanotechnology, 23 (14): 1-9.
Fleischer, A., Oneill, M.A. and Ehwald, R. 1999. The pore size of non-graminaceous plant cell walls is rapidly decreased by borate ester cross-linking of the pectic polysaccharide rhamnogalacturonan II. Plant Physiology, 121 (3): 829-838.
Fonteno, W.C. and Bilderback, T.E. 1993. Impact of hydrogel on physical properties of coarse-structured horticultural substrates. Journal of the American Society, 118 (2): 217-222.
Ghafariyan, M.H., Malakouti, M.J., Dadpour, M.R., Stroeve, P. and Mahmoudi, M. 2013. Effects of magnetite nanoparticles on soybean chlorophyll. Journal of Science and Technology, 47: 10645−10652.
Hajdua, A., Illes, E., Tombacz, E. and Borbath, I. 2009. Surface charging polyanionic coating and colloid stability of magnetite nanoparticles. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 347: 104–108.
Hopkins, W. G. 1999. Introduction to plant physiology. John Wiley and Sons. 528 page.
Imamy, A. 1996. Plant decomposition methods. Soil and Water Research Institute, Tehran Technical Bulletin, No. 982. (In Persian)
Jalali, M., Ghanati, F. and Modarres-Sanavi, A.M. 2016. Effect of Fe3O4 nanoparticles and iron chelate on the antioxidant capacity and nutritional value of soil-cultivated maize (Zea mays) plants. Crop and Pasture Science, 67: 621–628.
Kim, J., Lee, Y., Kim, E., Gu, S., Sohn, E.J., Seo, Y.S. and Chang, Y.S. 2014. Exposure of iron nanoparticles to Arabidopsis thaliana enhances root elongation by triggering cell wall loosening. Environmental Science and Technology, 48 (6): 3477-3485.
Kong, H., Song, J. and Jang, J. 2010. One-step fabrication of C-Fe2O3/polyrhodanine magnetic nanoparticles using in situ chemical oxidation polymerization and their antibacterial properties. Chemical Communications, 46 (36): 6735–6737.
Kosegarten, H. and Koyro, H.W. 2001. Apo plastic accumulation of iron in the epidermis of maize (Zea mays) roots grown in calcareous soil. Physiologia Plantarum, 113 (4): 515–522.
Kosegarten, H.U., Hoffmann, H. and Menge, K.1999. Apo plastic pH and Fe3+ reduction in intact sunflower leaves. Harald Plant Physiology, 121 (4): 1069–1079.
Li, J., Chang, P., Huang, J., Wang, Y., Yuan, H. and Ren, H. 2013. Physiological effects of magnetic iron oxide nanoparticles towards watermelon. Journal of Nanoscience and Nanotechnology, 13 (8): 5561-5567.
Li, J., Hu, J., Ma, C., Wang, Y., Wu, C., Huang, J. and Xing, B. 2016. Uptake, translocation and physiological effects of magnetic iron oxide (γ-Fe2O3) nanoparticles in corn (Zea mays L.). Chemosphere, 159: 326-334.
Li, L., Wu, H., Peijnenburg, W. and Gestel, C. 2015. Both released silver ions and particulate Ag contribute to the toxicity of Ag NPs to earthworm Eiseniafetida. Nanotoxicology, 9 (6): 792-801.
Lichtenthaler, H.K. 1987. Chlorophylls and carotenoids: Pigments of photosynthetic bio membranes. Methods in Enzymology, 148: 350-382.
Lin, D. and Xing, B. 2007. Phytotoxicity of nanoparticles: Inhibition of seed germination and root growth. Environmental Pollution, 150 (2): 243-250.
Liu, J.F., Zhao, Z.S. and Jiang, G.B. 2008. Coating Fe3O4 magnetic nanoparticles with humic acid for high efficient removal of heavy metals in water. Environmental Science and Technology, 42: 6949–6954.
Liu, X.M., Zhang, F.D., Feg, Z.B., Zhang, S.Q., He, X.S., Wang, R.F. and Wang, Y.J. 2005. Effects of nano-ferric oxide on the growth and nutrients absorption of peanut. Journal of Plant Nutrition Fertilizer, 11: 551-555.
Luttge, U. 1971. Structure and function of plant glands. Annual Review of Plant Physiology, 22: 23–44.
Maity, D. and Agrawal, D.C. 2007. Synthesis of iron oxide nanoparticles under oxidizing environment and their stabilization in aqueous and non-aqueous media. Journal of Magnetism and Magnetic Materials, 308: 46–55.
Marshner, H. 2012. Mineral nutrition of higher Plants. Third Edition. Publication of Elsevier, Oxford, 649 p.
Means, J.L., Crerar, D.A. and Duguid, J.O. 1978. Migration of radioactive wastes: Radionuclide mobilization by complexing agents. Science, 200: 1477-1481.
Miralles, P., Church, T.L. and Harris, A.T. 2012. Toxicity, uptake, and translocation of engineered nanomaterials in vascular plants. Journal of Environmental Science and Technology, 46 (17): 9224−9239.
Nair, R., Varghese, S.H., Nair, B.G., Maekawa, T., Yoshida, Y. and Sakthi Kumar, D. 2010. Nanoparticulate material delivery to plants. Plant Science, 179: 54-163.
Navarro, E., Piccapietra, F., Wagner, B., Marconi, F., Kaegi, R., Odzak, N., Sigg, L. and Behra, R. 2008. Toxicity of silver nanoparticles to Chlamydomonas reinhardtii. Journal of Environmental Science and Technology, 42: 8959-8964.
Nowack, B. 2002. Environmental chemistry of aminopolycarboxylate chelating agents. Journal of Environmental Science and Technology, 36 (19): 4009−4016.
Nyerges, E.I. 2005. Interaction of humic acid with magnetite nanoparticles: From soils to magnetic fluids. Ph.D. Thesis, Department of Colloid Chemistry, University of Szeged, Szeged, Hungary.
Pariona, N., Martínez, A.I., Hernandez-Flores, H. and Clark-Tapia, R. 2017. Effect of magnetite nanoparticles on the germination and early growth of Quercus macdougallii. Science of the Total Environment, 575: 869-875.
Qian, H., Peng, X., Han, X., Ren, J., Sun, L. and Fu, Z. 2013. Comparison of the toxicity of silver nanoparticles and silver ions on the growth of terrestrial plant model Arabidopsis thaliana. Journal of Environmental Sciences, 25 (9): 1947-1956.
Racuciu, M. and Creang, D.E. 2009. Biocompatible magnetic fluid nanoparticles internalized in vegetal tissue. Romanian Journal of Physics, 54: 115-124.
Rauch, J., Kolch, W., Laurent, S. and Mahmoudi, M. 2013. Big signals from small particles: Regulation of cell signaling pathways by nanoparticles. Chemical Reviews, 113 (5): 3391-3406.
Rico, C.M., Hong, J., Morales, M.I., Zhao, L., Barrios, A.C., Zhang, J.Y., Peralta-Videa, J.R. and Gardea-Torresdey, J.L. 2013. Effect of cerium oxide nanoparticles on rice: A study involving the antioxidant defense system and in vivo fluorescence imaging. Environmental Science and Technology, 47 (11): 5635-5642.
Sala, F. 1999. Magnetic fluids effect upon growth processes in plants. Journal of Magnetism and Magnetic Materials, 201 (1): 440−442.
Sattelmacher, B. and Horst, W.J. 2007. The apoplast of higher plants: Compartment of storage, transport and reactions–the significance of the apoplast for the mineral nutrition of higher plants. Dordrecht, Netherlands: Springer.
Schwab, F., Zhai, G., Kern, M., Turner, A., Schnoor, J. L. and Wiesner, M.R. 2016. Barriers, pathways and processes for uptake, translocation and accumulation of nanomaterials in plants: Critical review. Nanotoxicology, 10 (3): 257-278.
Servin, A., Elmer, W., Mukherjee, A., Dela Torre-Roche, R., Hamdi, H., White, J.C., Bindraban, P. and Dimkpa, C. 2015. A review of the use of engineered nanomaterials to suppress plant disease and enhance crop yield. Journal of Nanoparticle Research, 17 (2): 1-21.
Shafiee-Masouleh, S.S., Hatamzadeh, A., Samizadeh, H. and Rad-Moghadam, K. 2014. Enlarging bulblet by magnetic and chelating structures of nano-chitosan as supplementary fertilizer in Lilium. Horticulture, Environment, and Biotechnology, 55 (6): 437-444.
Shahrekizad, M., Gholamalizadeh Ahangar A. and Mir, N. 2015. EDTA-Coated Fe3O4nanoparticles: A novel biocompatible fertilizer for improving agronomic traits of sunflower (Helianthus annuus). Journal of Nanostructures, 5 (2): 117-127.
Sharma, P., Bhushan Jha, A., Shanker Dubey, R. and Pessarakli, M. 2012. Reactive oxygen species, oxidative damage, and antioxidative defense mechanism in plants under stressful conditions. Journal of Botany, Volume 2012, Article ID 217037, 26 pages.
Shenker, M. and Chen, Y. 2005. Increasing iron availability to crops: Fertilizers, organo fertilizers, and biological approaches. Soil Science and Plant Nutrition, 51 (1): 1-17.
Sladky, Z. 1959. The effect of extracted humus substances on growth of tomato plants. Biologia Plantarum, 1 (2): 142-150.
Sladky, Z. and Tichy, V. 1959. Application of humus substances to over ground organs of plants. Biologia Plantarum, 1 (1): 9-15.
Sun, D., Hussain, H.I., Yi, Z., Siegele, R., Cresswell, T., Kong, L. and Cahill, D.M. 2014. Uptake and cellular distribution, in four plant species, of fluorescently labeled mesoporous silica nanoparticles. Plant Cell Reports, 33 (8): 1389-1402.
Taran, M., Amoabediny, G. and Kashanian, F. 2016. The effect of coating on the toxicity of magnetic nanoparticles. Nanotechnology Monthly, 10: 21-27. (In Persian)
Taweesak, V., Abdullah, T.L., Hassan, S.A., Kamarulzaman, N.H. and Yusoff, W.A.W. 2014. Growth and flowering responses of cut chrysanthemum grown under restricted root volume to irrigation frequency. The Scientific World Journal, Volume 2014, Article ID 254867, 6 pages.
Ursache-Oprisan, M., Focanici, E., Creanga, D. and Caltun, O. 2011. Sunflower chlorophyll levels after magnetic nanoparticle supply. African Journal of Biotechnology, 10 (36): 7092-7098.
Vaughan, D. and Ord, B.G., 1981. Uptake and incorporation of 14C-labelled soil organic matter by roots of Pisum sativum L. Journal of Experimental Botany, 32(4): 679-687.
Verma, S.K., Das, A.K., Patel, M.K., Shah, A., Kumar V. and Gantait, S. 2018. Engineered nanomaterials for plant growth and development: A perspective analysis. Science of the Total Environment, 630: 1413–1435.
Wang, H., Kou, X., Pei, Z., Xiao, J. Q., Shan, X. and Xing, B. 2011. Physiological effects of magnetite (Fe3O4) nanoparticles on perennial ryegrass (Lolium perenne L.) and pumpkin (Cucurbita mixta) plants. Nanotoxicology, 5 (1): 30-42.
Westmeier, D., Stauber, R.H. and Docter, D. 2016. The concept of bio-corona in modulating the toxicity of engineered nanomaterials (ENM). Toxicology and Applied Pharmacology, 299: 53-57.