Responses of the leaf application of glycine betaine on sugarcane submitted to drought stress and rehydration
DOI:
https://doi.org/10.5965/223811712022021128Keywords:
Saccharum officinarum L., osmoprotection, growthAbstract
The growth of sugarcane plants is greatly reduced due to the occurrence of drought stress, which ultimately affects production. Therefore, different strategies have been used to attenuate stress conditions, such as the exogenous application of glycine betaine. The objective of this work was to evaluate the growth rate and dry mass of sugarcane that received a glycine betaine application and was submitted to drought stress and rehydration. The experiment was carried out in a greenhouse with six treatments: G0I - plants without glycine betaine with adequate irrigation, G0E - plants without glycine betaine and drought stress, G1I - plants with an application of glycine betaine and adequate irrigation, G1E - plants with an application of glycine betaine and drought stress, G2I - plants with two applications of glycine betaine and adequate irrigation, G2E - plants with two applications of glycine betaine and drought stress. Six days after the stress, the plants were rehydrated. The relative growth rates of sugarcane plants decreased with the drought stress. However, these reductions were partially minimized with the foliar application of glycine betaine, mainly with the rehydration, with the relative growth rate decreasing by only 19% and 18.4%, respectively, in G1 and G2, while the reduction was 37.2% in G0. Glycine betaine also minimized reductions in total dry mass production under drought stress, with decreases of 5.8% and 5.9% in G1 and G2, respectively, while it was 15.1% in G0. The leaf application of glycine betaine improves the relative growth rate of sugarcane plants under drought stress, especially after rehydration, which decreases the negative effects of stress on dry mass production.
Downloads
References
ANJUM SA et al. 2011. Gas exchange and chlorophyll synthesis of maize cultivars are enhanced by exogenously-applied glycine betaine under drought conditions. Plant, Soil and Environment 57: 326-331.
ANJUM SA et al. 2012. Protective role of glycine betaine in maize against drought-induced lipid peroxidation by enhancing capacity of antioxidative system. Australian Journal of Crop Science 6: 576-583.
ANJUM SA et al. 2016. Effect of progressive drought stress on growth, leaf gas exchange, and antioxidant production in two maize cultivars. Environmental Science and Pollution Research 23: 17132-17141.
ASHRAF M & FOOLAD MR. 2007. Roles of glycine betaine and proline in improving plant abiotic stress resistance. Environmental and Experimental Botany 59: 206-216.
BARBOSA AM et al. 2015. Biomass and bioenergy partitioning of sugarcane plants under water deficit. Acta Physiologiae Plantarum 37: 1-8.
DAWOOD MG. 2016. Influence of osmoregulators on plant tolerance to water stress. Scientia Agriculturae 13: 42-58.
FAROOQ M et al. 2008. Physiological role of exogenously applied glycine betaine to improve drought tolerance in fine grain aromatic rice (Oryza sativa L.). Journal Agronomy Crop Science 194: 325-333.
GUPTA N & THIND SK. 2015. Improving photosynthetic performance of bread wheat under field drought stress by foliar applied glycine betaine. Journal of Agricultural Science and Technology 17: 75-86.
INMAN-BAMBER NG & SMITH DM. 2005. Water relations in sugarcane and response to water deficits. Field Crops Research 92: 185-202.
IQBAL N et al. 2008. Glycinebetaine, an osmolyte of interest to improve water stress tolerance in sunflower (Helianthus annuus L.): water relations and yield. South African Journal of Botany 74: 274-281.
JANGPROMMA N et al. 2012. Effects of drought and recovery from drought stress on above ground and root growth, and water use efficiency in sugarcane (Saccharum officinarum L.). Australian Journal of Crop Science 6: 1298-1304.
SILVA MA et al. 2007. Use of physiological parameters as fast tools to screen for drought tolerance in sugarcane. Brazilian Journal of Plant Physiology 19: 193-201.
SOUZA JKC et al. 2015. Crescimento da cana-de-açúcar submetido a diferentes lâminas de irrigação e adubação com zinco. ACSA - Agropecuária Científica no Semiárido 11: 114-119.
VAN DILLEWIJN C. 1952. Botany of sugarcane. Waltham: Chronica Botanica.
WANG Y et al. 2006. A novel LEA gene from Tamarix androssowii confers drought tolerance in transgenic tobacco. Plant Science 171: 655-662.
ZHANG LX et al. 2014. Interactive effects of sudden and gradual drought stress and foliar-applied glycine betaine on growth, water relations, osmolyte accumulation and antioxidant defence systemin two maize cultivars differing in drought tolerance. Journal Agronomy Crop Science 200: 425-433.
Downloads
Published
How to Cite
Issue
Section
License
Copyright (c) 2021 Revista de Ciências Agroveterinárias (Journal of Agroveterinary Sciences)
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.
Authors publishing in this journal are in agreement with the following terms:
a) Authors maintain the copyrights and concede to the journal the copyright for the first publication, according to Creative Commons Attribution Licence.
b) Authors have the authority to assume additional contracts with the content of the manuscript.
c) Authors may supply and distribute the manuscript published by this journal.
