Nanotechnology in Plant Growth Promotion and Protection. Группа авторов
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which mainly include understanding the impact of different properties of NPs (shape, size, surface coatings, etc.) on plant growth for better design of Zn NPs. Zn NPs are widely known for their antimicrobial effects, their application against seed and plant pathogen is lacking. The benefits of seed treatments to produce disease‐free seedling and antimicrobial mechanisms to protect against specific diseases are still to be studied further. Similarly, Zn NPs are found effective in enhancing crop performance under abiotic stress, which can be particularly useful for promoting plant growth in a stressed environment. However, studies on stress tolerance and the related mechanism are still lacking. Moreover, the impacts of Zn NPs highly vary with crop species, but there are not sufficient researches done within comparative studies on plants to identify the genetic traits which control the interactions between Zn NPs and plants. To provide immediate supplement foliar application can be very effective. While considering fertilizer use efficiency, sustainability, and crop health substrate application could be a better option, where cytotoxicity due to direct absorption can be eliminated at higher concentrations. So, more studies should be done simultaneously to fully understand the positive and negative effects of the Zn application method. It is proved that proper application of Zn NPs significantly increases leaf pigment content and plant growth in most crops. Still, the contribution toward the quality and quantity of economic production of most of the crops has not been explored well which needs to address in a scientific manner. Finally, it is well‐known that most of the studies done so far are limited to the laboratory as a well‐controlled system. Therefore, more and more field studies are needed for better understanding of crops response to Zn NPs in the highly complex systems with a multitude of variables.
References
1 Awasthi, A., Bansal, S., Jangir, L.K. et al. (2017). Effect of ZnO nanoparticles on germination of Triticum aestivum seeds. Macromolecular Symposia‐ 2017. Wiley Online Library, 1700043.
2 Broadley, M.R., White, P.J., Hammond, J.P. et al. (2007). Zinc in plants. New Phytologist 173: 677–702.
3 Burman, U., Saini, M., and Kumar, P. (2013). Effect of zinc oxide nanoparticles on growth and antioxidant system of chickpea seedlings. Toxicological & Environmental Chemistry 95: 605–612.
4 Butler, R. (1993). Coatings, films and treatments. Seed World 10: 18–24.
5 Chamani, E., Karimi Ghalehtaki, S., Mohebodini, M., and Ghanbari, A. (2015). The effect of zinc oxide nanoparticles and humic acid on morphological characters and secondary metabolite production in Lilium ledebourii Bioss. Iranian Journal of Genetics and Plant Breeding 4: 11–19.
6 Choudhary, R.C., Kumaraswamy, R., Kumari, S. et al. (2019). Zinc encapsulated chitosan nanoparticle to promote maize crop yield. International Journal of Biological Macromolecules 127: 126–135.
7 Deinlein, U., Weber, M., Schmidt, H. et al. (2012). Elevated nicotianamine levels in Arabidopsis halleri roots play a key role in zinc hyperaccumulation. The Plant Cell 24: 708–723.
8 Dimkpa, C.O., Mclean, J.E., Britt, D.W., and Anderson, A.J. (2015). Nano‐CuO and interaction with nano‐ZnO or soil bacterium provide evidence for the interference of nanoparticles in metal nutrition of plants. Ecotoxicology 24: 119–129.
9 Dimkpa, C., Andrews, J., Fugice, J. et al. (2020). Facile coating of urea with low‐dose ZnO nanoparticles promotes wheat performance and enhances Zn uptake under drought stress. Frontiers in Plant Science 11: 168.
10 Eichert, T. and Goldbach, H.E. (2008). Equivalent pore radii of hydrophilic foliar uptake routes in stomatous and astomatous leaf surfaces–further evidence for a stomatal pathway. Physiologia Plantarum 132: 491–502.
11 Elhaj Baddar, Z. and Unrine, J.M. (2018). Functionalized‐ZnO‐nanoparticle seed treatments to enhance growth and zn content of wheat (Triticum aestivum) seedlings. Journal of Agricultural and Food Chemistry 66: 12166–12178.
12 Faizan, M., Faraz, A., Mir, A.R., and Hayat, S. (2020). Role of zinc oxide nanoparticles in countering negative effects generated by cadmium in Lycopersicon esculentum. Journal of Plant Growth Regulation: 1–15.
13 Farooq, M., Wahid, A., and Siddique, K.H. (2012). Micronutrient application through seed treatments: a review. Journal of Soil Science and Plant Nutrition 12: 125–142.
14 Fernández, V. and Eichert, T. (2009). Uptake of hydrophilic solutes through plant leaves: current state of knowledge and perspectives of foliar fertilization. Critical Reviews in Plant Sciences 28: 36–68.
15 García‐Gómez, C. and Fernández, M.D. (2019). Impacts of metal oxide nanoparticles on seed germination, plant growth and development. In: Analysis, Fate, and Toxicity of Engineered Nanomaterials in Plants, vol. 84 (eds. S.K. Verma and A.K. Das), 75–124. Amsterdam, UK: Elsevier.
16 García‐López, J.I., Niño‐Medina, G., Olivares‐Sáenz, E. et al. (2019). Foliar application of zinc oxide nanoparticles and zinc sulfate boosts the content of bioactive compounds in habanero peppers. Plants 8 (254) https://doi.org/10.3390/plants8080254.
17 Ghodake, G., Seo, Y.D., and Lee, D.S. (2011). Hazardous phytotoxic nature of cobalt and zinc oxide nanoparticles assessed using Allium cepa. Journal of hazardous materials 186: 952–955.
18 Hafeez, B., Khanif, Y., and Saleem, M. (2013). Role of zinc in plant nutrition‐a review. Journal of Experimental Agriculture International 3 (2): 374–391.
19 Hänsch, R. and Mendel, R.R. (2009). Physiological functions of mineral micronutrients (cu, Zn, Mn, Fe, Ni, Mo, B, cl). Current Opinion in Plant Biology 12: 259–266.
20 Helaly, M.N., El‐Metwally, M.A., El‐Hoseiny, H. et al. (2014). Effect of nanoparticles on biological contamination of in vitro cultures and organogenic regeneration of banana. Australian Journal of Crop Science 8: 612–624.
21 Hussain, D., Haydon, M.J., Wang, Y. et al. (2004). P‐type ATPase heavy metal transporters with roles in essential zinc homeostasis in Arabidopsis. The Plant Cell 16: 1327–1339.
22 Hussein, M. and Abou‐Baker, N. (2018). The contribution of nano‐zinc to alleviate salinity stress on cotton plants. Royal Society Open Science 5: 171809. https://doi.org/10.1098/rsos.171809.
23 Israel García‐López, J., Lira‐Saldivar, R.H., Zavala‐García, F. et al. (2018). Effects of zinc oxide nanoparticles on growth and antioxidant enzymes of Capsicum chínense. Toxicological & Environmental Chemistry 100: 560–572.
24 Kisan, B., Shruthi, H., Sharanagouda, H. et al. (2015). Effect of nano‐zinc oxide on the leaf physical and nutritional quality of spinach. Agrotechnology 5 https://doi.org/10.4172/2168‐9881.1000135.
25 Kołodziejczak‐Radzimska, A. and Jesionowski, T. (2014). Zinc oxide from synthesis to application: a review. Materials 7: 2833–2881.
26 Krämer, U. (2010). Metal hyperaccumulation in plants. Annual Review of Plant Biology 61: 517–534.
27 Latef, A.A.H.A., Alhmad, M.F.A., and Abdelfattah, K.E. (2017). The possible roles of priming with ZnO nanoparticles in mitigation of salinity stress in lupine (Lupinus termis) plants. Journal of Plant Growth Regulation 36: 60–70.
28 Laware, S. and Raskar, S. (2014). Influence of zinc oxide nanoparticles on growth, flowering and seed productivity in onion. International Journal of Current Microbiology Science 3: 874–881.
29 Mahajan, P., Dhoke, S., and Khanna, A. (2011). Effect of nano‐ZnO particle suspension on growth of mung (Vigna radiata) and gram (Cicer arietinum) seedlings using plant agar method. Journal of Nanotechnology 2011: 696535. https://doi.org/10.1155/2011/696535.
30 Malandrakis, A.A., Kavroulakis, N., and Chrysikopoulos, C.V. (2019). Use of copper, silver and zinc nanoparticles against foliar and soil‐borne plant pathogens. Science of the Total Environment 670: 292–299.
31 Masuthi, D.A., Vyakaranahal, B., and Deshpande,