Nanoselenium improves drought tolerance of sorghum via reduced transpiration rate and osmolytic accumulation

•Nanoselenium (n-Se) up to 20 mg L−1 did not cause toxicity at any trophic levels.•Application of n-Se at 20 mg L−1 reduced sorghum transpiration rate under drought.•Application of n-Se at 20 mg L−1 increased sorghum photosynthetic rate under drought.•During drought, n-Se enhanced seed-set by preser...

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Published in:South African journal of botany 2024-09, Vol.172, p.93-108
Main Authors: Djanaguiraman, M., Priyanka, A.S., Haripriya, S., Kalarani, M.K., Umapathi, M.
Format: Article
Language:English
Subjects:
antioxidant activity
drought
drought tolerance
ecotoxicology
foliar spraying
grain yield
hydrogen peroxide
leaves
Nanoselenium
Osmotic adjustment
Oxidative damage
photosynthesis
pollen
Pollen and pistil
proline
Reproductive success
seed set
seed yield
Selenium
sodium selenate
soil
Sorghum bicolor
stigma
superoxide anion
toxicity
transpiration
turgor
water content
water stress
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Summary:•Nanoselenium (n-Se) up to 20 mg L−1 did not cause toxicity at any trophic levels.•Application of n-Se at 20 mg L−1 reduced sorghum transpiration rate under drought.•Application of n-Se at 20 mg L−1 increased sorghum photosynthetic rate under drought.•During drought, n-Se enhanced seed-set by preserving reproductive tissue structures. Sorghum [Sorghum bicolor (L.) Moench] grain yield is vulnerable to drought stress. Therefore, developing appropriate technologies to mitigate drought is essential. We hypothesize that inhibition of photosynthesis and reproductive success by drought in sorghum can be improved by enhanced osmolyte accumulation and antioxidant defence system by foliar application of nanoselenium. In this study, the ecotoxicity potential and the physiological basis of drought alleviation by nanoselenium were evaluated. Nanoselenium did not cause toxicity to soil, aquatic and terrestrial organisms up to 20 mg L−1. During drought, foliar application of nanoselenium at 20 mg L−1 reduced the transpiration rate (16 %) compared to water spray. The superoxide radical content (50 %), hydrogen peroxide content (35 %), and membrane damage (26 %) were reduced, indicating antioxidant activity was exerted by nanoselenium. In contrast, the leaf turgor potential (80 %), relative water content (17 %), reducing sugars (57 %), non-reducing sugars (11 %), and proline (35 %) contents were increased by nanoselenium than water spray, indicating a higher tissue water content was maintained, which has increased the photosynthetic rate (26 %). Higher reproductive success in nanoselenium-sprayed plants under drought was associated with reproductive tissue morphology and an increased number of pollen grains attached to the stigma. Foliar application of nanoselenium at 20 mg L−1 increased seed-set percentage (21 %) and seed yield (26 %) under drought than control. A similar response was observed by foliar spray with sodium selenate. Overall, foliar application of nanoselenium at 20 mg L−1 improved the drought tolerance of sorghum by reducing the transpiration rate and increasing the antioxidant defense system.
ISSN:0254-6299
DOI:10.1016/j.sajb.2024.07.012