Silicon Priming Regulates Morpho-Physiological Growth and Oxidative Metabolism in Maize under Drought Stress

Parveen, Abida; Liu, Wei; Hussain, Saddam; Asghar, Jaleel; Perveen, Shagufta; Xiong, Yanmei

doi:10.3390/plants8100431

Cited by 123 publications

(76 citation statements)

References 52 publications

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“…4c, the exposure to B-32°C induced a more significant oxidative damage in untreated plants than in Si-fertilized plants, indicating that Si application can prevent the structural and functional deterioration of cell membranes by protecting them from ROS toxicity and reducing oxidative stress. These findings are in accordance with the studies of Rubinowska et al (2014), Shekari et al (2017), and Parveen et al (2019), who stated that the Si treatment reduced the permeability of the membranes by stimulating the synthesis of antioxidant enzymes, which deactivate the H 2 O 2 responsible for the peroxidation of cell lipids. Moreover, these authors suggested that Si can act in the stability of cell membranes through changes in the ratio of unsaturated and saturated fatty acids, maintaining the integrity and functionality of plasmatic membranes.…”

Section: Antioxidant Activitysupporting

confidence: 93%

“…3b) content in plant tissues can be a precursor of a highly reactive oxygen species (Ślesak et al 2007). The accumulation of H 2 O 2 affects the structure and integrity of plasma membranes by influencing the stress-dependent peroxidation of membrane lipids (Liang et al 2006(Liang et al , 2007Parveen et al 2019). The present findings suggest that the increased CAT, POD, and APX activity in Si-treated plants (10 mM SiK®) was beneficial to the lower levels of H 2 O 2 under high temperature conditions (B-32°C), as compared to control plants (0 mM SiK®).…”

Section: Antioxidant Activitymentioning

confidence: 99%

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Stress Oxidative Evaluation on SiK®-Supplemented Castanea sativa Mill. Plants Growing Under High Temperature

Carneiro-Carvalho

Anjos

Pinto

et al. 2020

J Soil Sci Plant Nutr

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The protective effect of silicon (Si) against environmental stress has been observed in many crops. The objective of this work was to evaluate the impact of SiK® (potassium silicate) fertilization on the resilience capacity of chestnut plants growing under high air temperature conditions and their recovery capacity after a turnover to adequate temperatures. Castanea sativa plants were supplied with 0 mM, 5 mM, 7.5 mM, and 10 mM SiK® and exposed sequentially to 25°C, 32°C, and 25°C for 1 month each. Data suggested that silicon are involved in increasing the heat tolerance of chestnut plants by reducing the oxidative damage and improving the antioxidant enzymes and metabolites. Under heat stress (32°C), there was an increase in the catalase, ascorbate peroxidase, and peroxidase activities, as well as in the phenol content of supplemented plants, which consequently reduced the electrolyte leakage, lipid peroxidation, and hydrogen peroxide content. Additionally, a lower proline content was measured inside the leaves' tissues of Si-treated plants. Besides the resilience against heat stress, after exposure to 32°C, the recovery was also quick.

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Section: Antioxidant Activitysupporting

confidence: 93%

Section: Antioxidant Activitymentioning

confidence: 99%

Stress Oxidative Evaluation on SiK®-Supplemented Castanea sativa Mill. Plants Growing Under High Temperature

Carneiro-Carvalho

Anjos

Pinto

et al. 2020

J Soil Sci Plant Nutr

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“…Water deficit and suboptimal temperature are adverse environmental factors that impose drastic effects on crop plants [ 2 , 22 ]. Maize is comparatively more sensitive to water scarcity and low temperature conditions particularly at the early stages of plant growth [ 2 , 25 , 26 , 27 ]. The present study indicated that all the maize shoot growth attributes were severely hampered by drought, chilling, and combination of drought + chilling stresses ( Figure 1 and Figure 2 ).…”

Section: Discussionmentioning

confidence: 99%

“…Both chilling and drought stresses have been reported to cause the oxidative damage in plants by the overproduction of ROS in cells [ 2 , 9 , 18 , 32 , 33 ]. However, plants have developed a complex antioxidative defense system, which consists of non-enzymatic and enzymatic components to overcome the excessive production of ROS [ 19 , 26 , 34 , 35 ]. The balance between ROS generation and antioxidants (enzymatic and non-enzymatic) is critical in all plant species under stress conditions [ 12 , 29 , 33 , 34 , 36 ].…”

Section: Discussionmentioning

confidence: 99%

Maize Tolerance against Drought and Chilling Stresses Varied with Root Morphology and Antioxidative Defense System

Hussain

Men

Hussain

et al. 2020

Plants

Self Cite

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Maize belongs to a tropical environment and is extremely sensitive to drought and chilling stress, particularly at early developmental stages. The present study investigated the individual and combined effects of drought (15% PEG-Solution) and chilling stress (15/12 °C) on morpho-physiological growth, osmolyte accumulation, production of reactive oxygen species (ROS), and activities/levels of enzymatic and non-enzymatic antioxidants in two maize hybrids (i.e., “XD889” and “XD319”) and two inbred cultivars (i.e., “Yu13” and “Yu37”). Results revealed that individual and combined exposure of drought and chilling stresses hampered the morpho-physiological growth and oxidative status of maize cultivars, nevertheless, the interactive damage caused by drought + chilling was found to be more severe for all the studied traits. Between two individual stress factors, chilling-induced reductions in seedling length and biomass of maize cultivars were more compared with drought stress alone. Greater decrease in root length and biomass under chilling stress ultimately decreased the volume and surface area of the root system, and restricted the shoot growth. All the stress treatments, particularly chilling and drought + chilling, triggered the oxidative stress by higher accumulation of superoxide anion, hydrogen peroxide, hydroxyl ion, and malondialdehyde contents compared with the control. Variations in response of maize cultivars were also apparent against different stress treatments, and XD889 performed comparatively better than the rest of the cultivars. The better growth and greater stress tolerance of this cultivar was attributed to the vigorous root system architecture, as indicated by higher root biomass, root surface area, and root volume under drought and chilling stresses. Moreover, efficient antioxidant defense system in terms of higher total antioxidant capability, superoxide dismutase, peroxidase, catalase, and glutathione reductase activities also contributed in greater stress tolerance of XD889 over other cultivars.

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“…In several species, Si appears to increase the level of soluble sugars under salt and drought stress (rice: Yang et al, 2019;wheat: Alzahrani et al, 2018;okra: Abbas et al, 2015;tobacco: Hajiboland et al, 2017), however, Kang et al (2016) reported decreased soluble sugar content in osmotically-stressed Zygophyllum xanthoxylum. Although in general Si appears to increase glycine betaine levels (Abbas et al, 2015;Saleh et al, 2017;Ahmad et al, 2019;Al-Huqail et al, 2019), decreases have been reported for drought-stressed maize (Parveen et al, 2019) and salt-stressed borage (Torabi et al, 2015). There is a trend for Si to increase polyamine levels under drought and salt-stress Yin et al, 2016;Ali et al, 2018;Yin et al, 2019).…”

Section: Water Statusmentioning

confidence: 96%

Is Silicon a Panacea for Alleviating Drought and Salt Stress in Crops?

2020

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Salinity affects around 20% of all arable land while an even larger area suffers from recurrent drought. Together these stresses suppress global crop production by as much as 50% and their impacts are predicted to be exacerbated by climate change. Infrastructure and management practices can mitigate these detrimental impacts, but are costly. Crop breeding for improved tolerance has had some success but is progressing slowly and is not keeping pace with climate change. In contrast, Silicon (Si) is known to improve plant tolerance to a range of stresses and could provide a sustainable, rapid and cost-effective mitigation method. The exact mechanisms are still under debate but it appears Si can relieve salt stress via accumulation in the root apoplast where it reduces "bypass flow of ions to the shoot. Si-dependent drought relief has been linked to lowered root hydraulic conductance and reduction of water loss through transpiration. However, many alternative mechanisms may play a role such as altered gene expression and increased accumulation of compatible solutes. Oxidative damage that occurs under stress conditions can be reduced by Si through increased antioxidative enzymes while Si-improved photosynthesis has also been reported. Si fertilizer can be produced relatively cheaply and to assess its economic viability to improve crop stress tolerance we present a cost-benefit analysis. It suggests that Si fertilization may be beneficial in many agronomic settings but may be beyond the means of smallholder farmers in developing countries. Si application may also have disadvantages, such as increased soil pH, less efficient conversion of crops into biofuel and reduced digestibility of animal fodder. These issues may hamper uptake of Si fertilization as a routine agronomic practice. Here, we critically evaluate recent literature, quantifying the most significant physiological changes associated with Si in plants under drought and salinity stress. Analyses show that metrics associated with photosynthesis, water balance and oxidative stress all improve when Si is present during plant exposure to salinity and drought. We further conclude that most of these changes can be explained by apoplastic roles of Si while there is as yet little evidence to support biochemical roles of this element.

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Silicon Priming Regulates Morpho-Physiological Growth and Oxidative Metabolism in Maize under Drought Stress

Cited by 123 publications

References 52 publications

Stress Oxidative Evaluation on SiK®-Supplemented Castanea sativa Mill. Plants Growing Under High Temperature

Stress Oxidative Evaluation on SiK®-Supplemented Castanea sativa Mill. Plants Growing Under High Temperature

Maize Tolerance against Drought and Chilling Stresses Varied with Root Morphology and Antioxidative Defense System

Is Silicon a Panacea for Alleviating Drought and Salt Stress in Crops?

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