Abstract
Being a salt sensitive crop, rice growth and development are frequently affected by soil salinity. Hydrogen sulfide (H2S) has been recently explored as an important priming agent regulating diverse physiological processes of plant growth and development. Despite its enormous prospects in plant systems, the role of H2S in plant stress tolerance is still elusive. Here, a combined pharmacological, physiological and biochemical approach was executed aiming to examine the possible mechanism of H2S in enhancement of rice salt stress tolerance. We showed that pretreating rice plants with H2S donor sodium bisulfide (NaHS) clearly improved, but application of H2S scavenger hypotaurine with NaHS decreased growth and biomass-related parameters under salt stress. NaHS-pretreated salt-stressed plants exhibited increased chlorophyll, carotenoid and soluble protein contents, as well as suppressed accumulation of reactive oxygen species (ROS), contributing to oxidative damage protection. The protective mechanism of H2S against oxidative stress was correlated with the elevated levels of ascorbic acid, glutathione, redox states, and the enhanced activities of ROS- and methylglyoxal-detoxifying enzymes. Notably, the ability to decrease the uptake of Na+ and the Na+/K+ ratio, as well as to balance mineral contents indicated a role of H2S in ion homeostasis under salt stress. Altogether, our results highlight that modulation of the level of endogenous H2S genetically or exogenously could be employed to attain better growth and development of rice, and perhaps other crops, under salt stress. Furthermore, our study reveals the importance of the implication of gasotransmitters like H2S for the management of salt stress, thus assisting rice plants to adapt to adverse environmental changes.
Highlights
Plants, being sessile in nature, are constantly exposed to an array of abiotic stresses throughout their life cycles
Under stressful conditions, plants’ basal capacity overwhelms and plants need to boost the protective mechanisms in order to surmount the detrimental consequences. effects, which were clearly observed in the levels of H2O2 and Our investigations clearly showed that the promotion of H2S level MDA as well as in the phenotypes of rice plants (Figures 1A,B, alleviated, and reduction of its level aggravated salt-induced toxic 3A–E, 5 and 6)
NaHS enhanced the contents of essential minerals under salt stress (Table 1) that are essential for activating a number of physiological and biochemical events associated with stress adaptations
Summary
Plants, being sessile in nature, are constantly exposed to an array of abiotic stresses throughout their life cycles. Salinity is one of the most brutal environmental constraints, affecting plant growth, development and productivity, especially in the arid and semi-arid regions (Parihar et al, 2015). Water shortage, hot and dry climate, and rising sea level due to global warming are aggravating the existing salinity problems, and worsening rice production in inland as well as coastal areas (Rabbani et al, 2013; Islam et al, 2015). Efforts to improve rice tolerance to salt stress through classical breeding have produced limited success and most of the existing varieties are unable to endure high salinity (Rabbani et al, 2013). Understanding the salt tolerance mechanisms of rice is indispensable in developing high salt-tolerant rice varieties to assure sustainable rice production in salt-affected regions
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