Effects of TiO2 nanoparticles on morphological characteristics of chickpea (Cicer arietinum L.) under drought stress

Ghorbani, Roya; Movafeghi, Ali; Gangeali, Ali; Nabati, Jafar

doi:10.22077/escs.2020.2485.1654

Document Type : Original Article

Authors

¹ Ph.D. Student in Plant Physiology, Tabriz University, Tabriz, Iran

² Professor, Plant Biology Department, Tabriz University, Tabriz, Iran

³ Associate Professor, Plant Biology Department and Research Center for Plant Sciences, Ferdowsi University of Mashhad, Mashhad, Iran

⁴ Assistant Professor, Legume Department, Research Center for Plant Sciences, Ferdowsi University of Mashhad, Mashhad, Iran

https://doi.org/10.22077/escs.2020.2485.1654

Abstract

Introduction
Drought stress is one of the most important environmental stresses affecting plant growth and yield. Chickpeas are drought tolerant plant, but drought as a limiting factor affects their yield. Drought stress in chickpeas reduces the length of flowering period and decrees the growth period. There are various strategies for mitigating drought stress, in which nanotechnology has received special attention in plant sciences in recent years. The use of nanoparticles in various plant species indicates their positive effects on plant growth and development. Nanoparticles are atomic or molecular assemblies with dimensions of 1-100 nanometers. Highly permeable nanoparticles increase the water uptake of nutrients and ultimately improve growth. The use of nanoparticles can be effective as a way to mitigate the effects of drought stress.
Materials and methods
The experiment was carried out as a factorial experiment with three replications in a completely randomized design in a greenhouse. The morphological and physiological characteristics of the plant were assessed at different levels (40, 60 and 90 percentage) of field capacity (FC). FC was measured by calculating the amount of soil humidity. The titanium dioxide nanoparticles (TiO₂-NPs) are used in five concentration including 0, 5, 20, 10 and 40 mg/L. Firstly characteristics of nanoparticles were investigated by measuring zeta potential, XRD and TEM. Secondly, a 100 mg/l mother solution was prepared in deionized water. TiO₂-NPs were dispersed by ultrasonic bath for 40 min before spraying the solution on the plants. The plants completely were soaked by sprayed solution 4 times each 14 days .Finally after the growth duration some morphological and physiological parameters were measured. The data were analyzed using ANOVA with Statistical Analysis System (Minitab .17) software and the significance of difference between means was determined by Tuky test.
Result and discussions
The results showed that the leaf area of chickpea was significantly affected by the test factors and their interactions. A 35%-increase in leaf area was observed at the lowest level of irrigation after exposure to 20 mg/L of TiO₂-NPs. Chlorophyll index of chickpea was significantly affected by the test factors and their interactions. The interaction of two test factors showed that with an increase in the concentration of TiO₂-NPs to 20 mg/L, chlorophyll index of chickpea was increased in all levels of irrigation. At all levels of irrigation, using the concentration of 40 mg/L of TiO₂-NPs, the chlorophyll index in chickpea leaves were reduced compared to the concentration of 20 mg/L. The highest osmotic potential was observed in 40% capacity after treatment with 5 and 10 mg/L titanium dioxide nanoparticles. There were no significant differences between 40 and 20 mg/L at this level of irrigation. At all irrigation levels, the application of the nanoparticle produced the highest osmotic potential, and thus, the use of nanoparticles increases the osmotic potential compared to control plants. Osmotic regulation under the water shortage conditions decreases cellular inflammation by maintaining water and collecting material in the cell. Also, the percentage of dry weight of the whole chickpea plants was significantly affected by the test factors and their interactions. The interaction of two factors showed that with the increasing concentration of TiO₂-NPs to 20 mg/L, the dry weight of chickpea in the lowest irrigation level was increased by10% compared to control plants. Stomatal conductivity in all irrigation levels had an upward trend by using TiO₂-NPs.
Conclusion
Generally, TiO₂-NPs showed a positive effect on the total dry and fresh weight of the whole chickpea plants. The application of 20 mg/L TiO₂-NPs at all levels of irrigation reduced drought stress and prevented further plant losses. The application of low concentration of nanoparticles promoted plant growth and at high levels showed inhibitory effects on growth. Taken all together, due to the increasing use of chemical fertilizers in agriculture, nano compounds can be used as an appropriate alternative that increases product quality.

Keywords

https://dorl.net/dor/20.1001.1.22287604.1400.14.1.8.5

References

Ahmad, A., Senapati, S., Khan, M.I., Kumar, R., Sastry, M., 2005 Extra-intracellular biosynthesis of gold nanoparticles by an alkalotolerant fungus, Trichothecium sp. Journal of Biomedical Nanotechnology. 1(1), 47-53.

Ajouri, A., Asgedom, H., Becker, M., 2004. Seed priming enhances germination and seedling growth of barley under conditions of P and Zn deficiency. Journal of Plant Nutrition and Soil Science. 167(5), 630-636.

Akkerman, Q.A., Gandini, M., Di Stasio, F., Rastogi, P., Palazon, F., Bertoni, G., Ball, J.M., Prato, M., Petrozza, A., Manna, L., 2017. Strongly emissive perovskite nanocrystal inks for high-voltage solar cells. Nature Energy. 2(2), 16942.

Anwar, M.R., McKenzie, B.A., Hill, G.D., 2003. Phenology and growth response to irrigation and sowing date of Kabuli chickpea (Cicer arietinum L.) in a cool-temperate subhumid climate. The Journal of Agricultural Science. 141(3-4), 273-284.

Ashkanvand, P., Tabari, M., Zarafshar, M., 2015. Apllied of Nanoparticle in botany, from www.nano.ir.

Azizi, Kh., Norozian, A., Yaghoobi, S., 2011. Effect of foliar application of zinc and bore elements on the grain yield, yield components, some indicators of growth, protein and oil content of rapeseed seed in climate Khorramabad. Journal of Agricultural Science. 4, 1-16. [In Persian with English Summary].

Bacelar, E.A., Santos, D.L., Moutinho-Pereira, J.M., Lopes, J.I., Gonçalves, B.C., Ferreira, T.C., Correia, C.M., 2007. Physiological behaviour, oxidative damage and antioxidative protection of olive trees grown under different irrigation regimes. Plant and Soil. 292(2-1), 1.

Baura-Pena, M.P., Martínez-Lope, M.J., García-Clavel, M.E., 1991. Synthesis and characterization of a hydrated titanium (IV) oxide. Thermochimica Acta. 179, 89-97.

Burnett, S., Paul T., Iersel, M.V., 2005. Postgermination drenches with PEG-8000 reduce growth of salvia and marigolds. Horticultural Science. 40, 675-790.

Chaves, M.M., Oliveira, M.M., 2004. Mechanisms underlying plant resilience to water deficits: prospects for water-saving agriculture. Journal of Experimental Botany. 55(407), 2365-2384.

FAO, 2017. FAO Hunger map. (www.fao.org)

Feizi, H., Kamali, M., Jafari, L., Moghaddam, P.R., 2013. Phytotoxicity and stimulatory impacts of nanosized and bulk titanium dioxide on fennel (Foeniculum vulgare Mill). Chemosphere. 91(4), 506-511.

Ganjeali, A., Kafi, M., 2007. Genotypic differences for allometric relationships between root and shoot characteristics in Chickpea (Cicer arietinum L.). Pakistan Journal of Botany. 21, 1523-1531.

Gao, W.R., Wang, X.S., Liu, Q.Y., Peng, H., Chen, C., Li, J.G., Zhang, J.S., Hu, S.N., Ma, H., 2008. Comparative analysis of ESTs in response to drought stress in chickpea (Cicer arietinum L.). Biochemical and Biophysical Research Communications. 367(3), 578-583.

Haghighi, M., Daneshmand, B., 2013. Comparing the effects of titanium and nano-titanium on growth and photosynthetic changes of tomato in hydroponic culture. Journal of Science and Technology of Greenhouse Culture. 4(13), 73-80. [In Persian with English Summary].

Hamzei, J., Seyedi, M., 2014. Study of canopy growth indices in mono and intercropping of chickpea and barley under weed competition. Journal of Sustainable Agriculture and Production. 24, 75-90. [In Persian with English Summary].

Hashemi, D.E., Mousavi, M., MoallemI, N., Ghafariyan, M.M.H., 2016. Effect of nanoparticles of titanium dioxide (anatase) on physiological characteristics of strawberry (Fragaria ananassa cv queen elisa) in hydroponic condition. Journal of Plant Process and Function. 1-8. (In Persian with English Summary).

Hossinzadeh, S.R., Ganjeali, A., Salami, A., Ahmadpour, R., 2012. Effects of foliar application of methanol on growth and root characteristics of chickpea (Cicer arietinum L.) under drought stress. European Journal of Experimental Biology.12, 2.

Jaberzadeh, A., Moaveni, P., Tohidi Moghadam, H.R., Modari, A., 2010. Effects of TiO₂ NPs foliar spraying on the wheat under drought stress, Iranian Journal of Plant Eco- Physiology. 4, 295-301. [In Persian with English Summary].

Javadi, T., Bahramnejad, B., 2010. Eefect of water stress on growth and some biochemichal traits of three pear genotypes from kudrestan proviance. Iranian Horticultural Science.24(2), 327-335. [In Persian with English Summary].

Jazizadeh, E., Mortezanejhad, F., 2016. Effects of drought stress on physiological indices on cannis Chcorium intybus L. Journal of Plant Process and Function. 6(21), 279-290. [In Persian with English Summary].

Khater, M.S., Osman, Y.A.H., 2015. Influence of TiO₂ nanoparticles on growth, chemical constituents and toxicity of fennel plant. Arab Journal of Nuclear Sciences and Applications. 48(4), 178-186.

Larue, C., Castillo-Michel, H., Sobanska, S., Cécillon, L., Bureau, S., Barthès, V., Ouerdane, L., Carrière, M., Sarret, G., 2014. Foliar exposure of the crop Lactuca sativa to silver nanoparticles: evidence for internalization and changes in Ag speciation. Journal of Hazardous Materials. 246, 98-106.

Lei, Z., Mingyu, S., Chao, L., Liang, C., Hao, H., Xiao, W., Xiaoqing, L., Fan, Y., Fengqing, G., Fashui, H., 2007. Effects of nanoanatase TiO₂ on photosynthesis of spinach chloroplasts under different light illumination. Biological Trace Element Research. 119(1), 68-76.

Leport, L., Turner, N.C., French, R.J., Barr, M.D., Duda, R., Davies, S.L., Tennant, D., Siddique, K.H.M., 1999. Physiological responses of chickpea genotypes to terminal drought in a Mediterranean-type environment. European Journal of Agronomy. 11(3-4), 279-291.

Liu, X.M., Zhang, F.D., Zhang, S.Q., He, X.S., Fang, R., Feng, Z., Wang, Y.J., 2005. Effects of nano-ferric oxide on the growth and nutrients absorption of peanut. Plant Nutrition and Fertilizer Science. 11, 14-18.

Lu, C., Zhang, C., Wen, J., Wu, G., Tao, M., 2002. Research of the effect of nanometer materials on germination and growth enhancement of Glycine max and its mechanism. Soybean Science. 21(13), 171-178.

Mamyandi, M.M., Pirzad, A., Zardoshti, M.R., 2012. Effect of Nano-iron spraying at varying growth stage of sugar beet (Beta vulgaris L.) on the size of different plant parts. International Journal of Agriculture and Crop Sciences. 2(4), 740-745.

Mansori, M., Akbari, G., Mortazavian, S.M.M., 2017. The effect of nanoparticles of titanium dioxide sprayed on yield and yield components of different ecotype cumin in drought stress. Journal of Crops Improvement. 19(2), 461-473. (In Persian with English Summary).

Moaveni, P., Farahani, H.A., Maroufi, K., 2011. Effect of TiO₂ nanoparticles spraying on barley (Hordem vulgare L.) under field condition. Advances in Environmental Biology. 5(8), 2220-2224.

Nair, R., Varghese, S.H., Nair, B.G., Maekawa, T., Yoshida, Y., and Kumar, D.S., 2010 Nanoparticulate material delivery to plants. Plant Science. 179(3), 154-163.

Navarro, E., Baun, A., Behra, R., Hartmann, N.B., Filser, J., Miao, A.J., Quigg, A., Santschi, P.H., Sigg, L., 2008. Environmental behavior and ecotoxicity of engineered nanoparticles to algae, plants, and fungi. Ecotoxicology. 17(5), 372-386.

Neumann, P.M., 2008. Coping mechanisms for crop plants in drought-prone environments. Annals of Botany.101(7), 901-907.

Nori, M., and Movaeni, P., 2016. Effect of titanium dioxide spraying on chlorophyll, yield and yield components of lentil. Research Journal of Legume. 8, 68-57.

Pandey, A.C., S. Sanjay, S., S. Yadav, R., 2010. Application of ZnO nanoparticles in influencing the growth rate of Cicer arietinum. Journal of Experimental Nanoscience. 5(6), 488-49

Qi, M., Liu, Y., Li, T., 2013. Nano-TiO2 improve the photosynthesis of tomato leaves under mild heat stress. Biological trace Element Research. 156(1-3), 323-328.

Qian, Y.L., Fry, J.D., Wiest, S.C., Upham, W.S., 1996. Estimating turfgrass evapotranspiration using atmometers and the Penman-Monteith model. Crop Science. 36(3), 699-704.

Rasouli, F., Abedini, F., Zahdi, M., 2016. The effect of Titanium nano dioxide on physiological particular and chlorophyll fluorescence parameters in Egg plant (Solanum melongena L.) under water deficit stress. Journal of Vegtable Science. (4)2, 51-37. [In Persian with English Summary].

Scherrer, P., 1912. Bestimmung der inneren Struktur und der Größe von Kolloidteilchen mittels Röntgenstrahlen. In Kolloidchemie Ein Lehrbuch (pp. 387-409). Springer, Berlin, Heidelberg.

Shao, H.B., Chu, L.B., Jaleel, C.A., Zho, C.H., 2008. Wtaer-deficit stress-induced anatomical change in higher plants. Compect Rendus Biologis. 331(3), 215-225.

Takallu, S., DavodI, D., Omidi, M., Ebrahimi, MA., Rouzbeh, F., Rasulnia, AR., 2013. The effect of titanium dioxide nanoparticles on barley cytogenetical index. Journal of Agricultural Biotechnology. 5(1), 13-26. [In Persian with English Summary].

Voet, D., Voet, J.G., Pratt, C.W., 2001. Fundamentals of Biochemistry Upgrade. New York, Wiley.

Yang, F., Hong, F., You, W., Liu, C., Gao, F., Wu, C., Yang, P., 2006. Influence of nano-anatase TiO₂ on the nitrogen metabolism of growing spinach. Biological Trace Element Research.110(2), 179-190.

Yusefzaei, F., Poorakbar, L., Farhadi, Kh., Molaei, R., 2017. The Effect of copper nanoparticles and copper chloride solution on germination and solution some morphological and physiological factors Ocimum basilicum L. Journal of Plant Science Reseearch. 30(1), 221-231. [In Persian with English Summary].

Zarafshar, M., Akbarinia, M., Askari, H., Hosseini, S.M., Rahaie, M., Struve, D., Gustavo G.S., 2014. Morphological, physiological and biochemical responses to soil water deficit in seedlings of three populations of wild pear (Pyrus boisseriana). Biotechnology, Agronomy, Society and Enviroment. 18, 353-366.

Zarafshar, M., Akbarinia, M., Askari, H., Hosseini, S.M., Satarian, A., Niakan, N., 2018. Comprative effect of TiO₂ and SiO₂ nanoparticles on some morphological, physiological and biochemical responses to soil water deficit in seedlings of wild pear (Pyrus boisseriana). Journal of Applied Biology. 31(2), 101-118. [In Persian with English Summary].

Zare Meherjerdi, M., Bagheri, A., Bahrami, A.R., Nabati, J., Masoumi, A., 2016. Effect of drought stress on osmotic adjustment, proline and soluble sugars in root and shoot and relationship with drought tolerance in 12 genotypes of Chickpea (Cicer arietinum L.). Iran Agronomy Science. 47(3), 451-462. [In Persian with English Summary].

Zheng, L, Hong, F., Lu, S., Liu, C., 2005. Effect of nano-TiO₂ on strength of naturally aged seeds and growth of spinach. Biological trace element research. 104, 83-91.

Zhu, H., Han, J., Xiao, J.Q., Jin, Y., 2008. Uptake, translocation, and accumulation of manufactured iron oxide nanoparticles by pumpkin plants. Journal of Environmental Monitoring. 10, 713-717.

Environmental Stresses in Crop Sciences

Effects of TiO2 nanoparticles on morphological characteristics of chickpea (Cicer arietinum L.) under drought stress

References

References

Volume 14, Issue 1
Open Access Policy
April 2021
Pages 85-98

Effects of TiO2 nanoparticles on morphological characteristics of chickpea (Cicer arietinum L.) under drought stress

References

References

Volume 14, Issue 1 Open Access PolicyApril 2021Pages 85-98

Volume 14, Issue 1
Open Access Policy
April 2021
Pages 85-98