Drought Stress: Responses and Mechanism in Plants

Pamungkas, Saktiyono Sigit Tri; Suwarto, .; Suprayogi, Suprayogi; Farid, Noor

doi:10.7831/ras.10.0_168

Cited by 18 publications

(6 citation statements)

References 130 publications

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“…Drought stress boosts the reduction in the net rate of photosynthesis and changes the metabolic carbon distribution, which ultimately leads to waste, energy dispersion, and a decline in yield [25]. The lack of water adversely affects cell division and differentiation and reduces the stabilization of CO 2 ; thus, the photosynthesis process would be reduced, and the accumulation of ROS may increase, all of which may result in a lack of plant production [26]. The results of Table (3) also showed significant superiority in the weight of bulb, number of cloves per bulb, and garlic bulb yield when plants were sprayed with a concentration of Se (20 mg.L -1 ) achieving the highest mean for (80.95 g.plant -1 ), (37.10 cloves.bulb -1 ), and ( 21.76 t.ha -1 ), respectively.…”

Section: Resultsmentioning

confidence: 99%

Effect of Water Stress and Selenium Spraying on Vegetative and Yield Indicators of Garlic Allium sativum L.

Al-Salami,

Alhasnawi

2023

IOP Conf. Ser.: Earth Environ. Sci.

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A field trial was carried out at the research station of the Faculty of Agriculture - University of Kufa, Iraq, during the growing season in September 2022 to evaluate the effect of water stress and spraying with selenium on the growth and yield of garlic. Three irrigation levels (100%, 80%, and 60%) of the water required for garlic and three concentrations of selenium (0, 10, and 20) mg.L-1. A strip-plot system was set up within a randomized complete block design with three replicates, where irrigation levels were placed in the main plots and selenium concentrations were designated in the subplots. Plant height, number of leaves, total chlorophyll content, shoot dry weight, number of cloves, bulb weight, and bulb yield were recorded as the agro-physiological traits. Furthermore, analysis of variance exhibited significant differences between both factors and their interactions for all traits measured. The results showed significant differences in all the aforementioned traits when irrigation levels were reduced from 100% to 60% of the water requirement. Spraying selenium at 20 mg.L-1 achieved the highest values in most of the above-mentioned characteristics in comparison with the absolute control, which gave the lowest values. The interaction treatment (100% watering + 20 mg.L-1 selenium) provided the highest mean for plant height, number of leaves, number of cloves, bulb weight, and yield compared with the other treatments.

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Section: Resultsmentioning

confidence: 99%

Effect of Water Stress and Selenium Spraying on Vegetative and Yield Indicators of Garlic Allium sativum L.

Al-Salami,

Alhasnawi

2023

IOP Conf. Ser.: Earth Environ. Sci.

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“…Osmolytes in osmoregulation create a more water-absorbent environment in plant cells, allowing them to withstand drought [39]. Moreover, small molecules of osmolytes including soluble carbohydrates, proteins, free amino acids, betaine, and proline have a neutral charge and are required for protective membranes and the denaturation of proteins as well as for osmotic potential and cell expansion under stress [39,40]. In the present study, glucose, fructose, betaine, and proline levels in leaves were increased under drought treatment, indicating that both inoculated and uninoculated walnuts actively accumulate osmolytes to resist drought.…”

Section: Discussionmentioning

confidence: 99%

Growth Performance and Osmolyte Regulation of Drought-Stressed Walnut Plants Are Improved by Mycorrhiza

Wen,

Zhou,

et al. 2024

Agriculture

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This study aims to evaluate whether a selected arbuscular mycorrhizal fungus, Diversispora spurca, improves growth in drought-stressed walnut (Juglans regia L. cv. Qingxiang) plants and whether this improvement is associated with changes in osmolyte (fructose, glucose, sucrose, soluble protein, proline, and betaine) levels. After 60 days of soil drought treatment (50% of maximum field water-holding capacity), root D. spurca colonization rate and soil mycelium length decreased by 13.57% and 64.03%, respectively. Soil drought also inhibited the growth performance of aboveground (stem diameter, leaf number, leaf biomass, and stem biomass) and underground (root projected area, surface area, and average diameter) parts, with uninoculated plants showing a stronger inhibition than D. spurca-inoculated plants. D. spurca significantly increased these growth variables, along with aboveground part variables and root areas being more prominent under drought stress versus non-stress conditions. Although drought treatment suppressed the chlorophyll index and nitrogen balance index in leaves, mycorrhizal inoculation significantly increased these indices. Walnut plants were able to actively increase leaf fructose, glucose, sucrose, betaine, and proline levels under such drought stress. Inoculation of D. spurca also significantly increased leaf fructose, glucose, sucrose, betaine, proline, and soluble protein levels under drought stress and non-stress, with the increasing trend in betaine and soluble protein being higher under drought stress versus non-stress. Drought stress dramatically raised leaf hydrogen peroxide (H2O2) levels in both inoculated and uninoculated plants, while mycorrhizal plants presented significantly lower H2O2 levels, with the decreasing trend higher under drought stress versus non-stress. In conclusion, D. spurca symbiosis can increase the growth of drought-stressed walnut plants, associated with increased osmolyte levels and decreased H2O2 levels.

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“…Here, we do not attempt to provide a full review on drought stress, because recent reviews are available (Dietz et al 2021;Pamungkas & Farid 2022). Rather, we will summarize options to improve the efficiency of water use for agricultural crop production, with or without irrigation.…”

Section: Introductionmentioning

confidence: 99%

Water for agriculture: more crop per drop

Geilfus,

Zörb,

Jones

et al. 2024

Plant Biol J

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Global crop production in agriculture depends on water availability. Future scenarios predict increasing occurrence of flash floods and rapidly developing droughts accompanied by heatwaves in humid regions that rely on rain‐fed agriculture. It is challenging to maintain high crop yields, even in arid and drought‐prone regions that depend on irrigation. The average water demand of crops varies significantly, depending on plant species, development stage, and climate. Most crops, such as maize and wheat, require relatively more water during the vegetative phase compared to the ripening phase. In this review, we explain WUE and options to improve water use and thus crop yield. Nutrient management might represent another possibility to manipulate water uptake and use by plants. An emerging topic involves agroforest co‐cultivation, where trees in the system facilitate water transfer through hydraulic lift, benefiting neighbouring crops. Other options to enhance crop yield per water use are discussed.

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Drought Stress: Responses and Mechanism in Plants

Cited by 18 publications

References 130 publications

Effect of Water Stress and Selenium Spraying on Vegetative and Yield Indicators of Garlic Allium sativum L.

Effect of Water Stress and Selenium Spraying on Vegetative and Yield Indicators of Garlic Allium sativum L.

Growth Performance and Osmolyte Regulation of Drought-Stressed Walnut Plants Are Improved by Mycorrhiza

Water for agriculture: more crop per drop

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