Protective effect of divalent cations against aluminum toxicity in soybean

Silva, Ivo Ribeiro da; Corrêa, Tarcísio Fernando Côrtes; Novais, Roberto Ferreira; Gebrim, Fabrício de Oliveira; Nunes, Flancer Novais; Silva, Eulene Francisco da; Smyth, Thomas J.

doi:10.1590/s0100-06832008000500027

Cited by 6 publications

(3 citation statements)

References 36 publications

(42 reference statements)

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“…Simple determination of the exchangeable Al contents in the soil or the total Al in the soil solution is not a sufficient indicator to evaluate the toxicity of this element to plants. To make this evaluation, quantification of the chemical species considered toxic becomes necessary, mainly the labile species of Al, such as Al 3+ , Al(OH) 2+ , and Al(OH) 2 + , as well as non-toxic species, especially the complexes of Al with organic and inorganic molecules that alter the proportion and activity of the toxic forms of Al (Ferro-Vásquez et al, 2014;Hagvall et al, 2015;Nolla et al, 2015) and, furthermore, the elements that can reduce Al toxicity, such as Ca 2+ and Mg 2+ (Silva et al, 2008;Hashimoto et al, 2010;Auxtero et al, 2012). In general, Al 3+ activity, rather than measurements of the soluble or exchangeable forms, is the best indicator of toxicity potential in acid soils (Ferrufino et al, 2000;Spera et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Chemical Species and Aluminum Concentration in the Solution of Acid Soils Cultivated with Soybean and Corn under Liming

Cunha

Almeida

Ernani

et al. 2018

Rev. Bras. Ciênc. Solo

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Section: Introductionmentioning

confidence: 99%

Chemical Species and Aluminum Concentration in the Solution of Acid Soils Cultivated with Soybean and Corn under Liming

Cunha

Almeida

Ernani

et al. 2018

Rev. Bras. Ciênc. Solo

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“…On the contrary, the binding of Al 3+ to negative charges and the precipitation of Al in the apoplast may decrease the loading of Mg 2+ ions (Bose et al, 2011). The effect of Mg is ion-specific and is not only associated to an electrostatic protection mechanism (da Silva et al, 2008). Being a cation, K can also potentially decrease Al toxicity.…”

Section: Introductionmentioning

confidence: 99%

Nutrient uptake of soybean genotypes under aluminum toxicity

Kuswantoro

2014

Ital J Agronomy

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The objective of this research was to study the nutrient uptake of soybean exposed to aluminium (Al) toxicity. The factorial design consisted of two treatments arranged in a randomized block design with three replications. Liming was the first factor which consisted of four levels, i.e. i) without liming; ii) liming with 0.5×Al(exchangeable/ec); iii) liming with 1×Al(ec); and iv) liming with 1.5×Al(ec). Five genotypes were used as second factor, i.e. three tolerant genotypes (W3898-14-3, Wilis, and Kawi), and two sensitve genotypes (MLG 3209 and MLG 3083). It was found that two tolerant genotypes, W3898-14-3 and Kawi, had a higher potassium (K) and sodium (Na) uptake than susceptible genotypes. Liming affected significantly the ratio of Al/[calcium (Ca) + magnesium (Mg)] in roots and leaves, the content of Ca and Mg in the roots and the content of Mg in the leaves. The K content in the roots and the content of Ca, K, and Na in the leaves were unresponsive to the alteration of pH and Al saturation. IntroductionAmong the earth's crust minerals, aluminum (Al) is the third most abundant after oxygen and silicon (Bhalerao and Prabu, 2013). It can have a toxic effect on plants under specific soil conditions, especially when the soil is acid. The root is the plant organ most affected by Al toxicity, before the upper part organs (Meriño-Gergichevich et al., 2010). However, some plants can tolerate Al toxicity, whereas other cannot tolerate it at all. This suggests that there is a specific mechanism associated with Al toxicity tolerance. Al-tolerant plants can be classified in three groups according to the plant tissues that accumulate Al (Foy, 1984). The first group includes plants in which the Al concentration in the leaves is not always different from that of sensitive plants and remains at lower levels. The second group includes plants with no Al in the leaves and/or Al trapped in the roots. The third group includes plants in which Al tolerance is directly related to Al accumulation in the upper part of the plant. These plants have therefore a high internal tolerance towards Al. In principle, the mechanisms of Al tolerance facilitate Al exclusion from the root and/or confer the plant the ability to tolerate it in its organs (Vardar and Unal, 2007). Watanabe and Osaki (2002) proposed other Al toxicity tolerance mechanisms by classifying plant into two groups. The first group includes the Al excluders, i.e. plants that exclude Al from their organs. The second group includes the Al accumulators, i.e. the plants that inactivate Al in their organs. Al accumulator plants present specific mechanisms involved in tolerance, such as the immobilization of Al in the cell wall, cytoplasmic Al complexation by organic acids, vacuolar isolation of Al tolerant enzymes, and isolation of Al in the vacuoles (Sopandie et al., 2000). Inorganic nutrients are also involved in this mechanism due to the interaction of Al with other nutrients to form inactive molecules. When Al concentration increases, the concentrations of magnesium ...

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“…Em razão dos baixos teores de cálcio (Ca) e magnésio (Mg) nos solos, não só a quantidade aplicada visando à correção é importante, mas também a relação entre esses nutrientes, visto que competem pelos sítios de troca no solo e na absorção pelas raízes (MOREIRA et al, 2003;SILVA et al, 2008).…”

Section: Introductionunclassified

Crescimento e estado nutricional da soja influenciados pela relação Ca:Mg em solo do cerrado paraense

Silva¹,

Sena²,

Matos³

et al. 2012

RCA

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KEYWORDS Glicyne max Liming Dry matter Macronutrients MicronutrientsRESUMO: Em solos com acidez elevada, a calagem é essencial; entretanto, deve-se atentar para as relações de cálcio (Ca) e magnésio (Mg) fornecidas. Avaliou-se o efeito da relação Ca e Mg do corretivo de acidez do solo na produção de matéria seca e no teor de N, P, K, Ca, Mg, Fe, Mn Cu e Zn na parte aérea de plantas de soja [Glicine max (L.) Merril] cv Sambaíba. O delineamento experimental utilizado foi inteiramente casualizado e os tratamentos foram constituídos de quatro relações molares entre Ca e Mg (1:1; 2:1; 4:1 e 8:1), com cinco repetições. A matéria seca da parte aérea da soja reduziu-se com o incremento da relação Ca:Mg, quando comparada àquela 1:1. Houve incremento dos teores de N e Ca acompanhados por decréscimo dos teores de P, K, Mg, Fe e Zn, quando se elevou a relação Ca:Mg. A relação Ca:Mg de 1:1 proporcionou a maior produção de matéria seca e o aumento dessa relação aumentou os teores de Ca e N na parte aérea da soja. (Glicine max (L.) ABSTRACT: In soils with high acidity, the liming is essential, however attention should be paid for Ca and Mg rates provided. The increase of limestone Ca:Mg ratio on the dry matter production and N, P, K, Ca e Mg, Fe, Mn Cu e Zn contents in soybean plants

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Protective effect of divalent cations against aluminum toxicity in soybean

Cited by 6 publications

References 36 publications

Chemical Species and Aluminum Concentration in the Solution of Acid Soils Cultivated with Soybean and Corn under Liming

Chemical Species and Aluminum Concentration in the Solution of Acid Soils Cultivated with Soybean and Corn under Liming

Nutrient uptake of soybean genotypes under aluminum toxicity

Crescimento e estado nutricional da soja influenciados pela relação Ca:Mg em solo do cerrado paraense

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