PRE-SOWING SEED TREATMENTS WITH SILICON NANO-IRON AND NANO-SILICON PARTICLES ON GERMINATION OF DRAGONHEAD
Naser Sabaghnia
sabaghnia@yahoo.comDepartment of Agronomy and Plant Breeding, Faculty of Agriculture, University of Maragheh, Maragheh, Iran (Iran, Islamic Republic of)
Saeed Yousefzadeh
Assistant Professor, Department of Agriculture, Payame Noor University, Tehran, Iran (Iran, Islamic Republic of)
Mohsen Janmohammadi
Department of Agronomy and Plant Breeding, Faculty of Agriculture, University of Maragheh, Maragheh, Iran (Iran, Islamic Republic of)
Mehdi Mohebodini
Department of Horticulture Science, Faculty of Agriculture, University of Mohaghegh Ardabili, Ardabil, Iran (Iran, Islamic Republic of)
Abstract
Nanotechnology is an emerging field of science widely exploited in agriculture in recent years. In this investigation, application of nanotechnology in agriculture via application of some nano-particles (nano-iron and nano-silicon) have been investigated in seed priming of dragonhead. Seeds were subjected to prehydration treatments by factor nano-silicon dioxide as; (S1) 0 mM or distilled water, (S2) 1 mM concentration and (S3) 2 mM concentration and and factor nano-iron oxide as; (F1) 0 Mm or distilled water, (F2) 1 mM concentration and (F3) 2 mM concentration. Germination percent, root fresh weight, shoot fresh weight, root length, shoot length, dry weight of the seed residue, root dry weight and shoot dry weight were measured. Analysis of variance showed significant variation for the main effect of nano-silicon dioxide as well as nanoiron dioxide in root length and dry weight of the seed residue. The interaction effect of nano-silicon × nanoiron priming treatments were significant in all of the measured traits except germination percentage and root fresh weight. The highest germination percentage was recorded in S2-F3, S3-F1 and S3-F3 while the root fresh weight was high in S2-F3 and treatments S1-F1 following to S2-F3 and S3-F2 produced the highest shoot fresh weight. Also, S2-F3 has the highest root length (16.1 cm) and the highest shoot length (18.4 cm). The best treatment combination suitable for obtaining of high values of germination characteristics of dragonhead was identified as S2-F3 (1 mM nano-silicon dioxide plus 2 mM nano-iron dioxide).
Keywords:
germination, nanoparticle, nanotechnology, Dracocephalum moldavica L.References
AOSA (Association of Official Seed Analysis). 1991. Rules for testing seeds. Seed Sci. Tech., 12: 18–9.
Google Scholar
Asadi M., Zahedi M., Ehtemam M.H., Khoshgoftarmanesh A.H. 2016. Effects of nano zinc oxide on the growth and ion content of four wheat cultivars under salinity stress J. Sci. & Technol. Greenhouse Culture, 7: 25–34.
Google Scholar
Azimi R., Borzelabad M.J., Feizi H., Azimi A. 2014. Interaction of SiO2 nanoparticles with seed prechilling on germination and early seedling growth of tall wheatgrass (Agropyron elongatum L.) Polish J. Chem. Tech., 16: 25–29.
Google Scholar
Ashraf M., Foolad M.R., 2005. Pre-sowing seed treatment – a shotgun approach to improve germination, plant
Google Scholar
growth, and crop yield under saline and non-saline conditions. Advan. Agron., 88: 223–271.
Google Scholar
Aziz, E.E., El-Sherbeny, S.E., 2003. Effect of some micro-nutrients on growth and chemical constituents of
Google Scholar
Sideritis montana as a new plant introduced into Egypt. Arab Univ. J. Agric. Sci., Ain Shams Univ., Cairo 12: 391– 403.
Google Scholar
Basra S.M.A., Farooq M., Wahid A., Khan M.B., 2006. Rice seed invigoration by hormonal and vitamin priming. Seed Sci. Tech., 34: 753–758.
Google Scholar
Chachoyan, A.A., Oganesyan, G.B., 1996. Antitumor activity of some species of family Lamiaceae. Rastitel 32 (4), 59–64.
Google Scholar
Clement, L., Hurel, C., Marmier, N. 2012. Toxicity of TiO2 nanoparticles to cladocerans, algae, rotifers and plants – Effects of size and crystalline structure. Chemosphere, 90: 1083–1090.
Google Scholar
Domokos J., Peredi J., Halaszzelnik K. 1994. Characterization of seed oils of dragonhead (Dracocephalum moldavica L.) and catnip (Nepeta cataria var. citriodora Balb.). Ind. Crop Prod., 3, 91–-94.
Google Scholar
El-Temsah, Y.S., Joner, E.J. 2012. Impact of Fe and Ag nanoparticles on seed germination and differences in bioavailability during exposure in aqueous suspension and soil. Environ. Toxicol., 27: 42–49.
Google Scholar
Feizi, H., Kamali, M., Jafari, L., Rezvani-Moghaddam P. 2013. Phytotoxicity and stimulatory impacts of nanosized and bulk titanium dioxide on fennel (Foeniculum vulgare Mill). Chemosphere, 91: 506–511.
Google Scholar
Haghighi M., Afifipour Z., Mozafarian M. 2012. The effect of N–Si on tomato seed germination under salinity levels. J. Biolo. Environ. Sci., 6: 87–90.
Google Scholar
Hu J., Zhu Z.Y., Song W.J., Wang J.C., Hu W.M. 2005. Effects of sand priming on germination and field performance in direct-sown rice (Oryza sativa L.). Seed Sci. Tech., 33: 243–248.
Google Scholar
Janmohammadi M., Bashiri A., Asghari-Shirghan R., Sabaghnia N. 2013: Impact of pre-sowing seed treatments and fertilizers on growth and yield of chickpea (Cicer arietinum L.) under rainfed conditions. Natura Monten., 12: 217–229.
Google Scholar
Janmohammadi M., Sabaghnia N. 2015. Effect of pre-sowing seed treatments with silicon nanoparticles on germinability of sunflower (Helianthus annuus). Bot. Lithuan., 21: 13–21
Google Scholar
Khodakovskaya, M., Dervishi, E., Mahmood, M., Xu, Y., Li, Z., Watanabe, F. 2009. Carbon nanotubes are able to penetrate plant seed coat and dramatically affect seed germination and plant growth. ACS Nano 3 (10), 3221–7. DOI: 10.1021/nn900887m.
Google Scholar
Liang Y., Sun W., Zhu Y.G., Christie P. 2007. Mechanisms of silicon-mediated alleviation of abiotic stresses in higher plants: a review. Environ. Pollut., 147: 422–428.
Google Scholar
Lin, B., Diao, S., Li, C., Fang, L., Qiao, S., Yu, M.(2004. Effect of TMS (nanostructured silicon dioxide) on growth of Changbai larch seedlings. J. Fores. Res.,15: 138–140.
Google Scholar
Liu, X.M., Zhang F.D., Zhang S.Q., He X.S., Fang R., Feng Z., Wang Y. 2005. Responses of peanut to nanocalcium carbonate. Plant Nut. Fert. Sci., 11: 3 Cellular and Molecular Life Sciences 9.
Google Scholar
Lyons, K., Scrinis, G., Whelan, J. 2011. Nanotechnology, agriculture, and food. Nanotech. Global Sustain., 117.
Google Scholar
Ma J.F. 2004. Role of silicon in enhancing the resistance of plants to biotic and abiotic stresses. Soil Sci. Plant Nut., 50: 11 Cellular and Molecular Life Sciences 18.
Google Scholar
Ma J.F., Yamaji N. 2008. Functions and transport of silicon in plants. Cell. Mol. Life Sci., 65: 3049–3057.
Google Scholar
Minitab Inc. 2005. Minitab User’s Guide, vers. 14. Minitab Inc, Harrisburg, Pennsylvania, USA.
Google Scholar
Moghaddam, G., Ebrahimi, S.A., Rahbar-Roshandel, N., Foroumadi, A. 2011. Antiproliferative activity of flavonoids: influence of the sequential methoxylation state of the flavonoid structure. Phytother. Res. 26: 1023–1028.
Google Scholar
Rechinger, K.H. 1986. Flora Iranica: Labiatae, vol. 150. Akademische Druck- und Verlagsanstalt, Graz, pp. 218–230.
Google Scholar
Sabaghnia N., Janmohammadi M. 2014. Graphic analysis of nano-silicon by salinity stress interaction on germination properties of lentil using the biplot method. Agric. Fores., 60: 29–40.
Google Scholar
Sabaghnia N., Janmohammadi M. 2015. Effect of nano-silicon particles application on salinity tolerance in early growth of some lentil genotypes. Ann. UMCS, Biolo., 69: 39–55.
Google Scholar
SAS Ins. 2004. SAS/STAT User’s Guide. SAS Institute Inc., Cary, NC, USA.
Google Scholar
Sheykhbaglou R., Sedghi M., Tajbakhsh-Shishevan M., Seyed-Sharifi R. 2010. Effects of nano-iron oxide particles on agronomic traits of soybean. Not. Sci. Biol. 2:112–113.
Google Scholar
Shi Y., Zhang Y., Yao H., Wu J., Sun H., Gong H. 2014. Silicon improves seed germination and alleviates oxidative stress of bud seedlings in tomato under water deficit stress. Plant Physiol. Biochem., 78: 27– 36.
Google Scholar
Siddiqui, M.H., Al-Whaibi M.H. 2014. Role of nano-SiO2 in germination of tomato (Lycopersicum esculentum seeds Mill.). Saud. J. Biolo. Sci., 21: 13–17.
Google Scholar
Singh N.B., Amist N., Yadav K., Singh D., Pandey J.K., Singh S.C. 2013. Zinc oxide nanoparticles as fertilizer for the germination, growth and metabolism of vegetable crops. J. Nanoeng. Nanomanuf. 3: 353–364
Google Scholar
Soltani A., Gholipoor M., Zeinali, E. 2006. Seed reserve utilization and seedling growth of wheat as affected by drought and salinity. Envir. Exp. Bot., 55: 195–200.
Google Scholar
Torabi F., Majd A., Enteshari S. 2012. Effect of exogenous silicon on germination and seedling establishment in Borago officinalis L. J. Med. Plants Res., 6: 1896–1901.
Google Scholar
Zheng L., Hong F., Lu S., Liu C. 2005: Effect of nano-TiO2 on strength of naturally aged seeds and growth of spinach. Biolo. Trace Elem. Res., 104: 83–91.
Google Scholar
Authors
Naser Sabaghniasabaghnia@yahoo.com
Department of Agronomy and Plant Breeding, Faculty of Agriculture, University of Maragheh, Maragheh, Iran Iran, Islamic Republic of
Authors
Saeed YousefzadehAssistant Professor, Department of Agriculture, Payame Noor University, Tehran, Iran Iran, Islamic Republic of
Authors
Mohsen JanmohammadiDepartment of Agronomy and Plant Breeding, Faculty of Agriculture, University of Maragheh, Maragheh, Iran Iran, Islamic Republic of
Authors
Mehdi MohebodiniDepartment of Horticulture Science, Faculty of Agriculture, University of Mohaghegh Ardabili, Ardabil, Iran Iran, Islamic Republic of
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