Effect of Waterlogging on Element Concentrations, Growth and Yield of Wheat Varieties Under Farmer’s Sodic Field Conditions

Singh, Surendra Pratap; Setter, Tim L.

doi:10.1007/s40011-015-0607-9

Cited by 21 publications

(23 citation statements)

References 23 publications

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“…Waterlogging decreases P content because of oxygen deficiency and impaired root functioning (Trought and Drew, 1980) and lack of energy for ion uptake (Barrett-Lennard et al, 1990). Similar to our results, decline in P content have been reported for waterlogged wheat and sensitive varieties of wheat have lower P content than tolerant varieties (Huang et al,1995;Singh and Setter, 2017). The leaf K content under waterlogging dropped below the critical ( ) deficiency level (Anderson and Bowen, 1990;McCray and Mylavarapu, 2010), except for varieties CoLk 94184, CoS 767 and CoLk 12202 (Fig.…”

Section: O N L I N E C O P Ysupporting

confidence: 90%

“…Thus, high leaf K content may be an important selection indices for waterlogging tolerance. Decrease in K in sugarcane varieties under waterlogging is in agreement with the previous report on wheat (Singh and Setter, 2017). It is also suggested that application of potassium along with N and P improves the tolerance to waterlogging (Cong et al, 2009).…”

Section: O N L I N E C O P Ysupporting

confidence: 89%

“…Increased activity of antioxidant enzymes and levels of antioxidant metabolites have been correlated with tolerance to wide varieties of environmental stress. Nutrient uptake is badly affected under waterlogging; the availability of major elements like N, P, K, Ca and Mg decreases while elements like Fe, Mn and Al increases in the plant above critical toxicity limit (Gilbert et al, 2007;Singh and Setter, 2017). Waterlogging induced nutrient deficiency/toxicity adversely affects physiological processes like photosynthesis, respiration and growth, causing chlorosis and necrosis and ultimately death of plant (Dodd et al, 2013;Bailey-Serres and Colmer, 2008).…”

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confidence: 99%

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Assessment of waterlogging induced physio-biochemical changes in sugarcane varieties and its association with waterlogging tolerance

Singh¹,

Singh²,

Pathak³

et al. 2019

JEB

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Section: O N L I N E C O P Ysupporting

confidence: 90%

Section: O N L I N E C O P Ysupporting

confidence: 89%

mentioning

confidence: 99%

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Assessment of waterlogging induced physio-biochemical changes in sugarcane varieties and its association with waterlogging tolerance

Singh¹,

Singh²,

Pathak³

et al. 2019

JEB

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“…Moreover, decreasing molecular oxygen prompts a sequence of changes in the physico-chemical properties of the soil (Ponnamperuma, 1984). Many of these also change soil chemical and electro chemicals by decreasing redox potential and excess electron changes, such as Fe 3+ and Mn 4+ to Fe 2+ and Mn 2+ , correspondingly (Ponnamperuma, 1984; Jackson and Colmer, 2005; Singh and Setter, 2017). Thus, solubility of iron and manganese rises to toxic levels, which are potentially damaging to plant roots (Jones and Etherington, 1970; Aldana et al, 2014; Marashi, 2018; Sharma et al, 2018).…”

Section: Waterlogging Effect On Soil and Plant Growthmentioning

confidence: 99%

Soil and Crop Management Practices to Minimize the Impact of Waterlogging on Crop Productivity

et al. 2019

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Waterlogging remains a significant constraint to cereal production across the globe in areas with high rainfall and/or poor drainage. Improving tolerance of plants to waterlogging is the most economical way of tackling the problem. However, under severe waterlogging combined agronomic, engineering and genetic solutions will be more effective. A wide range of agronomic and engineering solutions are currently being used by grain growers to reduce losses from waterlogging. In this scoping study, we reviewed the effects of waterlogging on plant growth, and advantages and disadvantages of various agronomic and engineering solutions which are used to mitigate waterlogging damage. Further research should be focused on: cost/benefit analyses of different drainage strategies; understanding the mechanisms of nutrient loss during waterlogging and quantifying the benefits of nutrient application; increasing soil profile de-watering through soil improvement and agronomic strategies; revealing specificity of the interaction between different management practices and environment as well as among management practices; and more importantly, combined genetic, agronomic and engineering strategies for varying environments.

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“…According to Marschner (2012) soil with redox potential <300 mV has no free O2 and in <250 mV has no NO3available. In saturated water, Singh and Setter (2017) noted the increase in the availability of toxic elements such as Fe, Mn, and Al. Although Sagala et al (2011) noted that continuous flooding inactive Fe toxicity.…”

Section: Plasticity Characters and Its Usefulness In The Cultivation mentioning

confidence: 99%

Phenotypic plasticity of eddoe and dasheen taro genotypes in response to saturated water and dryland cultivations

et al. 2020

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Abstract. Hidayatullah CSR, Santosa E, Sopandie D, Hartono A. 2020. Phenotypic plasticity of eddoe and dasheen taro genotypes in response to saturated water and dryland cultivations. Biodiversitas 21: 4550-4557. The phenotypic plasticity of dasheen and eddoe taro genotypes was evaluated based on growth and yield characters to select proper genotypes in response to climate change. The study was conducted at the Leuwikopo Experimental Farm, Bogor, Indonesia from May to October 2019. Dasheen (Talas Sutra and Talas Bentul) and eddoe genotypes (S28 and S19) were planted in saturated water cultivation (SWC) and dryland cultivation (DC). DC relied on rainwater, and SWC was manipulated dryland by flooding. SWC promoted vigorous growth and tuber weight, irrespective of genotypes. Increasing taro biomass production in SWC was supported by higher photosynthetic rate, leaf number, and size. Dasheen genotypes produced higher tuber weight than the eddoe in SWC, conversely, the eddoe tended to produced heavier tuber than the dasheen in DC; indicating phenotypic plasticity is strongly affected by soil moisture and genotype. The dasheen had more plastic growth and yield characters to soil moisture than the eddoe genotypes, with plasticity level, ranging from low to very high. Taro had high resiliency to multiple abiotic stresses, e.g. flood, and drought. Considering the marketable value of the yield, dasheen and eddoe genotypes are recommended in flooding and drought-prone areas, respectively.

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Effect of Waterlogging on Element Concentrations, Growth and Yield of Wheat Varieties Under Farmer’s Sodic Field Conditions

Cited by 21 publications

References 23 publications

Assessment of waterlogging induced physio-biochemical changes in sugarcane varieties and its association with waterlogging tolerance

Assessment of waterlogging induced physio-biochemical changes in sugarcane varieties and its association with waterlogging tolerance

Soil and Crop Management Practices to Minimize the Impact of Waterlogging on Crop Productivity

Phenotypic plasticity of eddoe and dasheen taro genotypes in response to saturated water and dryland cultivations

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