Silicon Supplementation Alleviates Ammonium Toxicity in Sugar Beet (Beta vulgaris L.)

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The efficiency of silicon (Si) foliar spraying in sorghum plants can be increased with new sources that may enhance the uptake of the beneficial element with reflexes in physiology. This study investigated the effect of foliar application of Si on different sources of absorption, gas exchange, and growth in sorghum plants, based on the hypothesis that there is a differential response to specific sources and concentrations of Si. An experiment was conducted in a completely randomized design with three replicates (in triplicate). The treatments consisted of five Si sources (nanosilica, silicic acid, stabilized sodium, potassium silicate, and potassium silicate) and four concentrations of Si (0, 0.5, 1.0, and 1.5 g L −1 of Si). Foliar spraying of Si on sorghum plants was effective at increasing the absorption of the beneficial element and the gas exchange of the plant. Nanosilica stood out as an alternative source of Si, and a promising option for foliar spraying in sorghum crops, as it promoted high uptake of the element by the plant. This source also promoted a high photosynthetic rate for both potassium silicate and alkaline silicate. In this study, spraying of 0.88 g L −1 (Si-alkali) and 0.84 g L −1 (Si-potassium) on sorghum at the phenological stages V 4 and V 8 (four and eight fully expanded leaves respectively) and R 1 (beginning of flowering) was promising because it increased plant growth, reduced water loss through transpiration, and had a positive impact on gas exchange.

Section: Introductionmentioning

confidence: 99%

Different Sources of Silicon by Foliar Spraying on the Growth and Gas Exchange in Sorghum

Oliveira

Prado

Felisberto

et al. 2019

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“…Si induced increase in grain yield was mainly attributed to the increased number of grains per panicle with little contributions of 1000 grain weight and panicle numbers per plant (Deren et al 1994). Si application could not only improve the grain yield of rice but also helps to induce multiple biotic and abiotic stress tolerance in plants (Ma 2004;Viciedo et al 2019). For example, Si improves resistance in rice against diseases such as rice blast (Datnoff et al 1997).…”

Section: Introductionmentioning

confidence: 99%

Effects of Silicon and Phosphatic Fertilization on Rice Yield and Soil Fertility

Wang

Ashraf

Chang

et al. 2019

A pot experiment was conducted to investigate the effects of silicon and phosphatic fertilization on rice yield and soil fertility. Three levels of silicon (Si) fertilization i.e., SiO 2 : 45, 135, and 225 kg hm −2 and the two phosphatic fertilizer i.e., P 2 O 5 : 15 and 45 kg hm −2 for each of calcium superphosphate (CS) and combined calcium-magnesium phosphate (FCMP) (used as phosphatic fertilizer source) were applied to a rice cultivar "II you 128". The treatment applied with P 2 O 5 45 kg hm −2 CS and without Si fertilization was taken as control (CK). The grain yield was improved with increasing Si fertilizer application, whereas phosphatic fertilization also affected the grain yield significantly. The FCMP showed better grain yield than CS whereas the interactive effect of Si and CS fertilizer showed higher Si contents in stem sheath, available Si in soil, water-soluble Si contents in soil and soil active Si contents but lower available phosphorus in soil and soil phosphatase activity than the Si and FCMP fertilizer interaction. Moreover, the grain yield showed significant positive correlation with aboveground dry weight (r = 0.9951) and harvest index (r = 0.8364). Overall, Si fertilization improved rice yield, whereas FCMP was found better than CS regarding grain yield improvement. The grain yield increased with increasing Si fertilizer application whereas the FCMP was found better than CS regarding grain yield improvement of rice. The supplementation of Si and phosphatic fertilizers substantially improved available Si and P contents of soil.

“…The beneficial role of Si has been documented to alleviate toxicity of metals including Cd in rice (Tripathi et al 2012a), Cr in rice (Tripathi et al 2012b), Al in wheat (Zsoldos et al 2003), Mn in cowpea (Führs et al 2009), As in rice (Tripathi et al 2013), Pb in cotton (Bharwana et al 2013), Fe in rice (Dufey et al 2014), Zn in maize (Kaya et al 2009) and Cu in rice (Kim et al 2014). Recent studies also indicated that Si fertilisation can alleviate ammonium toxicity in sugar beet (Viciedo et al 2019). Additionally, the effect of Si on nutrient imbalances was shown for other plants by Brackhage et al (2013) and Neu et al (2017).…”

Section: Nutrient Toxicitymentioning

confidence: 99%

An Overview on the Potential of Silicon in Promoting Defence Against Biotic and Abiotic Stresses in Sugarcane

Majumdar

Prakash

2020

Although silicon (Si) is ubiquitous in the earth's crust, its essentiality for growth of higher plants is still under discussion. By recognising the overwhelming potential of Si in alleviating a wide range of biotic and abiotic stresses, the Association of American Plant Food Control Officials and the International Plant Nutrition Institute, Georgia, USA, have designated Si as a plant 'beneficial substance' in 2014 and 2015, respectively. Sugarcane is a Si-accumulating crop which strongly responds to Si fertilisation especially in Si-deficient soil. Due to intensive weathering prevailing in humid and sub-humid regions, most of the soil-available Si, taken up by plants in the form of monosilicic acid (H 4 SiO 4), is lost through leaching. If the concentration of monosilicic acid is being maintained at a fixed level by soil reserves, the highly weathered soils of humid and sub-humid regions tend to become depleted in Si if continuously cultivated with sugarcane. Hence, leaching of Si from the soil coupled with plant uptake is an important factor in determining Si concentrations in soil. Consequently, it can be said that the intensive cultivation of sugarcane depletes the existing low available Si content in soil, resulting in necessity for Si fertilisation. Moreover, the uptake of Si by sugarcane (500-700 kg Si ha −1) sometimes surpasses those of the macronutrients (especially N, P and K). At the same time, due to change in global climate and monoculture system followed in sugarcane, it is affected by a wide range of biotic and abiotic stresses in field condition which calls for external Si supplementation to achieve sustainable growth and yield of sugarcane. The beneficial effects of Si in sugarcane include improvement of photosynthesis and lodging, enhancement of growth and development, regulation of reactive oxygen species, protection from soil salinity, reduction in metal toxicity, alleviation of freeze damage, mitigation of water stress and suppression of diseases and pests. In this review, we made an effort to compile the existing literature describing the potential of Si in promoting defence against various biotic and abiotic stresses in sugarcane and suggested possible future research perspectives.