Document Type : Original Article

Authors

1 MSc Student of Agronomy, Department of Plant Production and Genetic Engineering, Faculty of Agriculture, Lorestan University, Iran

2 Associate Prof., Department of Plant Production and Genetic Engineering, Faculty of Agriculture, Lorestan University, Iran

3 Assistant Prof., Department of Plant Production and Genetic Engineering, Faculty of Agriculture, Lorestan University, Iran

Abstract

Introduction
Sesame (Sesamum indicum L.) is one of the oldest oil seed crops, growing widely in tropical and subtropical areas. Drought is a polygenic stress and is considered as one of the most important factors limiting crop yields around the world. Most of the Iranian soils have a high pH and calcareous nature, and micronutrients solubility in these soils is low. Micronutrient deficiency, especially iron, is widespread where soil is calcareous with high pH, low organic matter, continuous drought, high bicarbonate content in irrigation water, and imbalanced application of NPK fertilizers. Foliar nutrition is an option when nutrient deficiencies cannot be corrected by applications of nutrients to the soil. Microelements Foliar application is very helpful when the roots cannot provide necessary nutrients. Iron is an important element in crops, because it is essential for many enzymes including cytochromes, which is involved in the electron transport chain, chlorophyll synthesis, and maintains the structure of chloroplasts. Nowadays, nanoparticles of metals are widely used in many sections, such as medicine, agriculture, and industry. Iron oxide nanoparticles have a large surface area and high reactivity. Moreover, when compared to many other metallic nanoparticles, the iron oxide nanoparticles are constant, less expensive, and less toxic. Iron oxide nanoparticles have high magnetization amounts, a size smaller than 100 nm and a thin particle size distribution. These particles also have a special surface cover of magnetic particles, which has to be harmless and biocompatible.

Materials and methods
To study the effect of drought stress and iron oxide nanoparticle foliar application on quantitative and qualitative traits of sesame (Sesamum indicum L.), an experiment was conducted as split-plot with three replications at the research farm of Agricultural Faculty, Lorestan University in 2016. The experimental factors were included drought stress in two levels of non-stress (Irrigation to reach soil water to FC 100%) and drought stress (Irrigation to reach soil water to FC 50%) as the main factor, and iron oxide nanoparticle foliar application in five levels of non-foliar application (Control), foliar application by water (1000 liters of water per hectare), iron oxide nanoparticle 0.05% (0.5 kg/1000 L of water per hectare), iron oxide nanoparticle 0.1% (1.0 kg/1000 L of water per hectare) and iron oxide nanoparticle 0.15% (1.5 kg/1000 L of water per hectare) as the sub factor. The measured traits included number of capsules per plant, 1000 grain weight, grain yield, biological yield, harvest index, grain oil content, grain oil yield, grain protein content and grain protein yield. Analysis of variance was performed using general linear model (GLM) procedure of statistical analysis system (SAS version: 9.3). The means were analyzed using the Tukey test at P=0.05.

Results and discussion
Results showed that the drought stress decreased significantly traits of 1000 grain weight (18.51%), grain yield (26.52%), biological yield (9.42%), harvest index (3.94%), grain oil content (10.30%), grain oil yield (40.47%) and grain protein yield (24.90%) except for the number of capsules per plant and grain protein content. However, the iron oxide nanoparticle application improved significantly traits of 1000 grain weight (19.86%), grain yield (37.43%), biological yield (22.91%), harvest index (3.86%), grain oil content (6.49%), grain oil yield (45.70%) and grain protein yield (40.93%) under drought stress except for the number of capsules per plant, and grain protein content. Among different levels of foliar application, iron oxide nanoparticle 0.15% had the most effect on increasing the measured traits except for the harvest index.

Conclusions
In general, iron oxide nanoparticle foliar application can be used, especially at a concentration of 0.15%, to reduce the harmful effects of drought stress and improve the quantitative and qualitative traits of sesame in Khorramabad city.

Keywords

Abedi-koupai, J., Sohrab, F., 2004. Evaluating the application of superabsorbent polymers on soil water capacity and potential on three soil textures. Iranian Journal of Polymer Science and Technology. 3, 163-173. [In Persian with English Summary].
Ahmadi, J., Seyfi, M.M., Amini, M., 2012. Effect of spraying micronutrients Fe, Zn and Ca on grain and oil yield of sesame (Sesamus indicum L.) varieties. Journal of Crop Production. 5, 115-130.
Alizade, A., 1995. Increase of plants yield. Mashhad JDM Press. 300p. [In Persian].
Askary, M., Talebi, S.M., Amini, F., Dousti, A., 2017. Effects of iron nanoparticles on Mentha piperita L. under salinity stress. Biologija. 63, 65-75.
Ayobizadeh, N., Laei, G., Amini Dehaghi, M., Masood Sinaki, J., Bidokhti, S.R., 2017. Effect of nano-iron and folic acid foliar application on yield and yield components of sesame varieties after wheat cultivation under drought stress conditions. Journal of Crop Production Research. 9, 283-312. [In Persian with English Summary].
Babaeian, M., Heidari, M., Ghanbari, A., 2008. Effects of foliar micronutrient application on osmotic adjustments, grain yield and yield components in sunflower (Alster cultivar) under water stress at three stages. Journal of Science and Technology of Agriculture and Natural Resources, 40, 119-129. [In Persian with English Summary].
Bahrani, A., 2015. Effect of some micro and macro nutrients on seed yield and oil content of rapeseed (Brassica napus L.). International Journal of Chemical Environmental and Biological Sciences. 3, 71-74.
Boghori, M., Shamsi, H., Morovati, A., 2014. Effect of nano iron chelates on yield and amount iron and rate oil of sesame cultivar Darab 14. Journal of Plant Ecophysiology. 6, 69-79. [In Persian with English Summary].
Das, R., Kiley, P.J., Segal, M., Norville, J., Yu, A.A., Wang, L., Lebedev, N., 2004. Integration of photosynthetic protein molecular complexes in solid-state electronic devices. Nano Letters, 4, 1079-1083.
Eisvand, H.R., Esmaeili, A., Mohammadi, M., 2014. Effects of iron oxide nanoparticles on some quantity, quality and physiological characteristics in wheat (Triticum aestivum L.) at Khoramabad climate. Iranian Journal of Field Crop Science, 45, 287-298. doi: 10.22059/ijfcs.2014.51907
Gan, Y., Malhi, S.S., Brandt, S., Katepa-Mupondwa, F., Stevanson, C., 2008. Nitrogen use efficiency and nitrogen uptake of juncea canola under diverse environments. Journal of Agronomy. 100, 285-295.
Ghasemian, V., Ghalavand, A., Soroosh zadeh, A., Pirzad, A., 2010. The effect of iron, zinc and manganese on quality and quantity of soybean seed. Journal of Phytology. 2, 73-79.
Gholinezhad, E., Aynaband, A., Hassanzade, A., Noormohamadi, Gh., Bernousi, I., 2009. Study of the effect of drought stress on yield, yield components and harvest index of sunflower hybrid iroflor at different levels of nitrogen and plant population. Notulae Botanicae Horti Agrobotanici Cluj-Napoca. 37, 85-94.
Gholinezhad, E., Darvishzadeh, R., 2015. Effect of mycorrhizal fungi on yield and yield components of sesame (Sesamum indicum L.) landraces under different irrigation levels. Journal of Agricultural Science. 25(3), 119-135. [In Persian with English Summary].
Hassanzadeh, M., Ebadi, A., 2009. Investigation of water stress on yield and yield components of Sesame (Sesame indicum L.) in Moghan region. Research Journal of Environmental Science. 3, 239-244.
Heidari, M., Goleg, M., Ghorbani, H., Baradarn Firozabad, M., 2016. Effect of drought stress and foliar application of iron oxide nanoparticles on grain yield, ion content and photosynthetic pigments in sesame (Sesamum indicum L.). Iranian Journal of Filed Crop Science. 46, 619-628. [In Persian with English Summary].
Heidari, M., Galavi, M., Hassani, M., 2011. Effect of sulfur and iron fertilizers on yield, yield components and nutrient uptake in Sesame (Sesamum indicum L.) under water stress. African Journal of Biotechnology, 10, 8816-8822.
Jain, S., Yue-Lioang, R., Mei-wang, L. E., Ting-Xian, Y., Xiao-Wen, Y., Hong-Ving, Z., 2010. Effect of drought stress on sesame growth and yield characteristics and comprehensive evaluation of drought tolerance. Chinese Journal of Oil Crop Sciences. 32, 525-533.
Jalilian, J., Modarres Sanavy, S.A.M., Saberali, S.F., Asilan, K.S., 2012. Effects of the combination of beneficial microbes and nitrogen on sunflower seed yields and seed quality traits under different irrigation regimes. Field Crops Research. 127, 26–34.
Kaufman, H. P., 1958.  Analyse der fette and fettprodukte. Springer Verlag, Berlin.
Khajehpour, M.R., 2007. Industrial Cultivars of Jihad Publishing House. Isfahan Industrial Branch. 580p. [In Persian].
Mahdavi Khorami, A., Masoud Sinaki, J., Amini Dehaghi, M., Rezvanbidokhti, Sh., Damavandi, A., 2018. Investigation of relationship between some quantitative and qualitative characteristics affecting sesame yield under nitrogen, potassium and drought stress. Journal of Agricultural Science and Sustainable Production. 28, 15-34. [In Persian with English Summary].
Mazaherinia, S. Astaraei, A.R., Monshi, A., Fotovat, A., 2012. Comparison of iron oxides (ordinary and nano) and urban solid waste compost effect on nutrition of wheat plant. Agronomy Journal (Pajouhesh and Sazandegi). 96, 103-110. [In Persian with English Summary].
Mehrabi, Z., Ehsanzadeh, P., 2011. A study on physiological attributes and grain yield of sesame (Sesamum indicum L.) cultivars under different soil moisture regimes. Journal of Crop Improvement, 13, 75-88. [In Persian with English Summary].
Misagh, M., Movahhedi Dehnavi, M., Yadavi, A.R., Khadem Hamze, H.R., 2016. Improvement of yield, oil and protein percentage of sesame (Sesamum indicum L.) under drought stress by foliar application of zinc and boron. Journal of Crop Production. 9, 163-180. [In Persian with English Summary].
Monica, R.C., Cremonini, R., 2009. Nanoparticles and higher plants. Caryologia. 62, 161-165.
Rafie, M.R., Darabi, A., 2007. A study of the effects of frequency and depth of irrigation on total and marketable yield and yield components of potato cultivars. The Scientific Journal of Agriculture. 30, 30-39. [In Persian with English Summary].
Rastegar, M., 2007. Industrial Plants Cultivation. Jihad University Press. Ferdowsi University of Mashhad. 376p. [In Persian].
Salo-vaananen, P.P., Koivistoinen, P.E., 1996. Determination of protein in foods: comparison of net protein and crude protein (N6.25) values. Journal of Food Chemistry. 57, 27-31.
Silva, R.T., Oliveira, A.B., Lopes, M.D., Guimarães, M.A., Dutra, A.S., 2016. Physiological quality of sesame seeds produced from plants subjected to water stress. Revista Ciência Agronômica. 47, 643-648.
Siosemarde, A., Ahmadi, A., Poustini, K., Mohammadi, V., 2006. Evaluation of drought resistance indices under various environmental conditions. Field Crops Research. 98, 229-222.
Tabatabaei, S.J., 2013. Principles of mineral nutrition of plants. Tabriz University Press. 544p. [In Persian].
Zarei, G., Shamsi, H., Dehghani, S.M., 2010. The effect of drought stress on yield, yield components and seed oil content of three autumnal rapeseed cultivars (Brassica napus L.). Journal of Research in Agricultural Science. 6, 29-36.