Reaction of wheat genotypes to soil aluminum differential saturations

Costa, Antonio; Campos, Luís Alberto Cogrossi; Riede, Carlos Roberto

doi:10.1590/S1516-89132003000100004

Abstracts

Ten wheat (Triticum aestivum) genotypes were evaluated in microplots with aluminum saturation of 0, 15, 30 and 45%, during 1994, in Londrina, Paraná, Brazil. The soil was a Distrofic Red Latosol (Typic Haplorthox), with 65% saturation of aluminum, amended with dolomitic lime. Variables evaluated included grain yield and yield components: ears.m-2, grains.ear-1 and the weight of 1000 grains. Genotypes differed in yield and yield components. Increasing aluminum saturation decreased yield, ears.m-2 and grains.ear-1, but did not alter thousand kernel weight. The genotypes reacted differently in relation to the toxic soil aluminum. Anahuac and IAPAR 29 were aluminum sensitive; OCEPAR 16, Trigo BR 18, and Trigo BR 23 were moderately sensitive; IAPAR 6, IAPAR 53, and IAPAR 60 were moderately tolerant; while IAC 5-Maringá and Trigo BR 35 were tolerant.

Triticum aestivum; aluminum tolerance; aluminum soil saturation; yield components

Dez cultivares de trigo foram submetidos à saturações de alumínio (SATAL) de 0, 15, 30 e 45%, para avaliar a tolerância desses materiais à toxidez de alumínio. O experimento foi conduzido em Londrina, PR, em 1994, usando microparcelas, com material de solo de um Latossolo Roxo álico (Haplorthox típico), com 65% de saturação de alumínio, corrigido com calcário dolomítico, para se obter as saturações acima mencionadas. O delineamento experimental foi em blocos ao acaso com distribuição em parcelas subdivididas. As diferenças entre cultivares de trigo foram caracterizadas pela produção de grãos (PGT) e os componentes de rendimento: número de espigas m-2 (NEM), número de grãos espiga-1 (NGE) e massa de mil grãos (MMG). Observou-se diferença na produção de grãos e nos componentes de rendimento entre os cultivares testados. Aumento na SATAL diminuiu a PGT, o NEM e o NGE; não se observou alteração na MMG. Os cultivares de trigo reagiram diferentemente em relação à toxidez de alumínio. 'Anahuac' e 'IAPAR 29' foram os materiais mais sensíveis. Os cultivares 'OCEPAR 16', 'Trigo BR 18' e 'Trigo BR 23' foram considerados moderadamente sensíveis, enquanto o 'IAPAR 6', 'IAPAR 53' e 'IAPAR 60' apresentaram-se como moderadamente tolerantes ao alumínio. O 'IAC 5-Maringá' e o 'Trigo BR 35' foram caracterizadas como cultivares tolerantes à presença de alumínio tóxico no solo.

Reaction of wheat genotypes to soil aluminum differential saturations

Antonio Costa; Luís Alberto Cogrossi Campos; Carlos Roberto Riede

Instituto Agronômico do Paraná; C. P. 481; 86001-970; Londrina - PR - Brazil

^{Correspondence} Correspondence to Antonio Costa E-mail: antcosta@pr.gov.br

ABSTRACT

Ten wheat (Triticum aestivum) genotypes were evaluated in microplots with aluminum saturation of 0, 15, 30 and 45%, during 1994, in Londrina, Paraná, Brazil. The soil was a Distrofic Red Latosol (Typic Haplorthox), with 65% saturation of aluminum, amended with dolomitic lime. Variables evaluated included grain yield and yield components: ears.m^-2, grains.ear^-1 and the weight of 1000 grains. Genotypes differed in yield and yield components. Increasing aluminum saturation decreased yield, ears.m^-2 and grains.ear^-1, but did not alter thousand kernel weight. The genotypes reacted differently in relation to the toxic soil aluminum. Anahuac and IAPAR 29 were aluminum sensitive; OCEPAR 16, Trigo BR 18, and Trigo BR 23 were moderately sensitive; IAPAR 6, IAPAR 53, and IAPAR 60 were moderately tolerant; while IAC 5-Maringá and Trigo BR 35 were tolerant.

Key words :Triticum aestivum, aluminum tolerance, aluminum soil saturation, yield components

RESUMO

Dez cultivares de trigo foram submetidos à saturações de alumínio (SATAL) de 0, 15, 30 e 45%, para avaliar a tolerância desses materiais à toxidez de alumínio. O experimento foi conduzido em Londrina, PR, em 1994, usando microparcelas, com material de solo de um Latossolo Roxo álico (Haplorthox típico), com 65% de saturação de alumínio, corrigido com calcário dolomítico, para se obter as saturações acima mencionadas. O delineamento experimental foi em blocos ao acaso com distribuição em parcelas subdivididas. As diferenças entre cultivares de trigo foram caracterizadas pela produção de grãos (PGT) e os componentes de rendimento: número de espigas m^-2 (NEM), número de grãos espiga^-1 (NGE) e massa de mil grãos (MMG). Observou-se diferença na produção de grãos e nos componentes de rendimento entre os cultivares testados. Aumento na SATAL diminuiu a PGT, o NEM e o NGE; não se observou alteração na MMG.

Os cultivares de trigo reagiram diferentemente em relação à toxidez de alumínio. 'Anahuac' e 'IAPAR 29' foram os materiais mais sensíveis. Os cultivares 'OCEPAR 16', 'Trigo BR 18' e 'Trigo BR 23' foram considerados moderadamente sensíveis, enquanto o 'IAPAR 6', 'IAPAR 53' e 'IAPAR 60' apresentaram-se como moderadamente tolerantes ao alumínio. O 'IAC 5-Maringá' e o 'Trigo BR 35' foram caracterizadas como cultivares tolerantes à presença de alumínio tóxico no solo.

INTRODUCTION

Wheat is cultivated in the State of Paraná in a large diversity of soil types, several of them presenting high acidity, high level of exchangeable aluminum (Al) and low bases saturation. These characteristics contribute to high Al saturation, which restricts the subsoil root development, reducing the normal water and nutrients uptake by the wheat plants (Riede and Campos, 1988; Uexküll and Mutert, 1995). The use of lime and the neutralization of exchangeable Al in the subsoil are practices which present agronomic and/or economic difficulties to be executed, restricting a generalized utilization (Quaggio, 2000). The occurrence of toxic Al is particularly important when associated to water stress. In the North of Paraná the occurrence of drought in the establishment of the crop growth it is frequent, while in the West such phenomenom occurs most frequently in the grain filling period (Caramori et al., 1991). Under these conditions the use of Al sensitive cultivars seriously reduce the wheat yield potential (Okuyama and Costa, 1990). The use of Al tolerant wheat cultivars is a complementary solution to achieve high and stable yields of wheat when cultivated in acid soils of Paraná State. Genetic variability for tolerance to toxic Al exists among different species of plants and among cultivars of the same species which has allowed the selection of tolerant and productive genotypes, for the soil acidity environments (Foy and Brower, 1964; Carver and Ownky, 1995; Baligar and Fageria, 1996; Camargo et al., 1999). Tolerance to Al toxicity is one of criterion for wheat cultivar recommendation in Paraná . The index used for the recommendation of cultivars is the Al saturation (%) of the soil to a depth of 60 cm (Muzilli et al., 1978; IAPAR, 2000). The present work was done to determine the degree of tolerance of wheat cultivars at different levels of Al saturation in the soil.

MATERIAL AND METHODS

The experiment was conducted during 1994, in microplots containing a Typic Haplorthox (latossolo roxo), collected at the Experiment Station of IAPAR, in Londrina, PR. The results of the original soil analysis indicated the values of: pH 3.6 in CaCl₂ 0.01 M (1:2.5); Al³⁺ 25.5 mmol(+) dm^-3; H⁺+Al³⁺ 121.3 mmol(+) dm^-3; Ca²⁺ 3.3 mmol(+) dm^-3; Mg²⁺ 2.5 mmol(+) dm^-3; K⁺ 0.17 mmol(+) dm^-3; CEC 128.8 mmol(+) dm^-3 and 5.82% and 65.27% for bases and Al saturations, respectively. The experiment was set in randomized blocks, with sub-plots and three replications. The amount of lime used in the plots was determined by the incubation of soil with dolomitic lime, for 45 days, and defined by the regression equation Y = 67.52 63.55X + 15.11X², where (Y) represents the estimated Al saturation as a function of the lime levels (X). To reach the Al saturations of 45, 30, 15, and 0%, doses of 0.39; 0.71; 1.33 and 2.75 g of lime l^-1of soil were applied. The dolomitic lime used contained 202.02 g kg^-1 of Ca²⁺, 121.78 g kg^-1 of Mg²⁺, and effective neutralization power of 20.08 mol(+) kg^-1. The subplots consisted of 10 wheat cultivars, sowed in two rows of l m per cultivar, spaced in 0.20 m and each microplot had 0.40 m². The evaluated genotypes were: 'Trigo BR 23', 'IAPAR 29', 'IAPAR 60', 'OCEPAR 16', 'Trigo BR 35', 'IAPAR 6', 'IAPAR 53', 'Trigo BR 18', 'IAC 5-Maringá', and 'Anahuac'. Plots were irrigated when necessary. Grain yield and yield components, number of heads.m^-2, number of kernels per head, and thousand kernel weight were determined. The results were submitted to an analysis of variance, being the means of qualitative parameters compared by grouping of Scott-Knott to 5% of probability. The quantitative parameters were adjusted by exponential, quadratic, and quadratic base of square root models of linear regression, and it was chosen as a selection criterion of the more adequated models to the magnitude and significance of the coeficient of determination. The equations were adjusted by the means of the observed values to each determination.

RESULTS AND DISCUTION

Grain yield

The average grain yield of wheat cultivars increased significantly with a reduction of the soil Al saturation (Table 1). With the neutralization of exchangeable Al, 0% de aluminum saturation, the average yield of the evaluated cultivars were superior in 48, 29, and 16% to the yields obtained with 45, 30, and 15% Al saturations, respectively.

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This means that liming was a necessary practice in the management of acid soils for wheat production. Among tested genotypes 'Anahuac' was the least productive genotype, confirming its non adaptation to the acidity conditions (Camargo and Oliveira, 1981; Baier et al., 1995). The most tolerant genotypes based on average yield across Al saturation were: 'Trigo BR 35', 'IAC 5-Maringá', 'IAPAR 60', and 'IAPAR 53' (Table1).

In the absence of toxic Al in the soil, there were no yield differences among wheat genotypes. At the other levels of Al saturation, significative differences among cultivars were observed, and the differences were higher with the increased level of Al in the soil. This fact indicated that productive genotypes had their yields reduced with the elevation of the element in the soil, and demonstrated variability for aluminum tolerance among the evaluated wheat cultivars.

Yield components

No significant interaction between cultivars and Al saturation for the evaluated yield components were observed. On average the reduction of soil Al saturation promoted an increase on the number of heads m^-2 (NHM) and the number of kernels per head (NKH), with no alteration on the thousand kernel weight (TKW) (Table 2). The increase in the observed grain yield (Table 1) with the reduction and neutralization of exchangeable Al was associated with an increase in the two first yield components.

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Among the evaluated cultivars, 'Anahuac' was the least productive in the aluminum presence, showing a reduced number of kernels per head (NKH) in the presence of higher levels of toxic Al. The higher grain yield of 'Trigo BR 35', 'IAC 5-Maringá, and 'IAPAR 60' was due to the association of high values of NHM and NKH, while 'IAPAR 53' was more productive due to increased TKW and elevated NHM. In the group of intermediate grain yield genotypes, 'IAPAR 6' and 'Trigo BR 23' presented high NHM, but had limited TKW and/or reduced NHM. 'Trigo BR 18' had yield reduced by low NKH, while 'OCEPAR 16' and 'IAPAR 29' had their potential reduced by low NHM. (Tables 1 and 2).

The grain yield of the evaluated wheat cultivars had a negative correlation with saturation of exchangeable soil Al and positive with NHM and NKH, while TKW did not present significative correlation with the yield of grains. The correlation analysis reinforced that the presence of soil exchageable Al reduced the grain yield through a reduction of NHM and NKH. The negative correlation between NKH and TKW indicated a competition in the formation of these two yield components and would justify the absence of interference of TKW in the wheat grain yield (Table 3).

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Considering the average of evaluated parameters, which significantly affected grain yield, a mathematical model was calculated to estimate wheat grain yield (GY), in kg.ha^-1 in function of the yield components NHM, NKH, and the soil Al saturation (ALSAT) in %.

GY = 4.57 NHM + 63.00 NKH 11.81 ALSAT

(R² = 0.992**)

Aluminum tolerance of wheat genotipes

Considering the evidence of variability, the wheat genotypes were characterized for Al tolerance through an adjustment of regression equation between the GY of each cultivar and the ALSAT (Table 4). From the equations, an estimation of GY at 45% Al saturation for each genotype was calculated.

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An index of toxic Al tolerance, for each genotype, through the relation between estimated yield by the equation of 45% Al saturation and the average yield of the 10 cultivars tested in this level of saturation was established.

These index were distributed in four frequency classes, corresponding to sensitive, moderately sensitive, moderately tolerant, and tolerant cultivars. The cultivars 'Anahuac' and 'IAPAR 29' were considered sensitive having grain yield at least 20% lower than the mean of 10 wheat cultivars evaluated in the 45% Al saturation. The cultivars 'OCEPAR 16', 'Trigo BR 18', and 'Trigo BR 23' were moderately sensitive and their yield means were up to 20% lower to the cultivar group mean, when evaluated in the highest level of exchangeable Al in the soil. The moderately tolerant cultivars 'IAPAR 6', 'IAPAR 53', and 'IAPAR 60' yielded up to 20% above the mean, while the considered tolerant 'IAC 5-Maringá', and 'Trigo BR 35' yielded between 21% to 40% above the mean of the 10 evaluated cultivars in the 45% Al saturation. The used criteria to separate wheat genotypes into different tolerance classes allowed the effective placement of tested cultivars (Camargo and Oliveira, 1981; Baier et al.,1995).

To the means of each tolerance group defined previuosly regression equations were adjusted (Figure 1). In the soil exchangeable Al tolerance of 45%, the genotypes considered tolerant such as 'IAC 5-Maringá', and 'Trigo BR 35', presented mean grain yield equivalent to the estimated in the 23.5% Al saturation for the moderately tolerant group, to 9.5% for the moderately sensitive, and 7.8% for the sensitive genotypes (Figure 1).

It could be concluded that the use of Al tolerant cultivars was a fundamental component for the successful cultivation of wheat in acid soils.

CONCLUSIONS

The grain yield of wheat was reduced by the elevation of soil Al saturation. Differences among evaluated genotypes indicated the existence of genetic variability for Al tolerance. The yield components, number of heads.m^-2 and number of kernels per head, were negatively correlated with soil Al saturation and positively with grain yield. The same did not happen with thousand kernel weight. The wheat genotypes had a different response to the toxic soil Al. In the sensitive group were Anahuac and IAPAR 29. OCEPAR 16, Trigo BR 18, and Trigo BR 23 were moderately sensitive; IAPAR 6, IAPAR 53, and IAPAR 60 were moderately tolerant; while IAC 5-Maringá and Trigo BR 35 were tolerant.

Received: May 16, 2001

Revised: July 27, 2001

Accepted: January 18, 2002

Baier, A. C.; Somers, D. and Gustafson, J. (1995), Aluminum tolerance in wheat: correlating hydroponic evaluations with field and soil performances. Plant Breeding, 114, 291-294.
Baligar, V. C. and Fageria, N. K. (1996), Nutrient use efficiency in acid soils: nutrient manegement and plant use efficiency. In: Moniz A.C. et al. (ed.). Plant-Soil Interactions at Low pH Belo Horizonte. Proceedins... Viçosa/Campinas, Brazilian Soil Science Society, 1997. pp.75-95.
Camargo, C. E. O.; Ramos, L. C. S.; Ferreira Filho, A. W. P.; Felício, J. C.; Pettinelli Júnior, A.; Castro, J. L. and Yohoo, E. Y. (1999), Linhagens diplóide de trigo: produção de grãos, características agronômicas e tolerância à toxicidade de alumínio Bragantia, 58 : (2), 235-46.
Caramori, P. H.; Oliveira, D. and Farias, R. T. (1991), Freqüência de ocorrência de períodos com deficiência hídrica (veranicos) no Estado do Paraná. Boletim técnico IAPAR, (36), 1-40.
Carver, B. F. and Ownby Y. J. D. (1995), Acid soil tolerance in wheat. Adv. Agron., 54, 117-73.
Foy, C. D. and Brower, J. C. (1964), Toxic factors in acid soils II Diferencial aluminum tolerance of plants species. Soil Sci. Soc. Am. Proc, 28, 27-32.
IAPAR (2000), Informações técnicas para a cultura do trigo no Paraná. IAPAR Circular, 109, 1-152.
Muzilli, O.; Santos, D.; Palhano, J. B.; Manetti Filho, J.; Lantmann, A. F.; Garcia, A. and Cataneo, A. (1978), Tolerância de cultivares de soja e de trigo a acidez do solo. R. bras. Ci. Solo, 2, 34-40.
Okuyama, L. A. and Costa, A. (1990), Avaliação de genótipos de trigo para resistência à seca em solo com saturação de alumínio. Informe da Pesquisa IAPAR, 94, 37-41.
Quaggio, J. A. (2000), Acidez e Calagem em Solos Tropicais. Campinas : Instituto Agronômico. 111 pp.
Riede, C. R. and Campos, L. A. C. (1988), Development of wheat cultivars with higher yield and adaptation to different agroclimatic conditions of Paraná. In: Kohli, M. M.and Rajaram, S. (eds.). Wheat breeding for acid soils: Review of Brazilian/CIMMYT collaboration, 1974-1986. CIMMYT, México. pp. 26-38.
Uexküll, H. R. von and Mutert, E. (1995), Global extent, development and economic impact of acid soils. Plant and Soil, 17 : (1), 5-19.

Correspondence to

Antonio Costa

E-mail:

antcosta@pr.gov.br

Publication Dates

Publication in this collection
19 May 2003
Date of issue
Jan 2003

History

Accepted
18 Jan 2002
Reviewed
27 July 2001
Received
16 May 2001

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Baier, A. C.; Somers, D. and Gustafson, J. (1995), Aluminum tolerance in wheat: correlating hydroponic evaluations with field and soil performances. Plant Breeding, 114, 291-294.

[2] Baligar, V. C. and Fageria, N. K. (1996), Nutrient use efficiency in acid soils: nutrient manegement and plant use efficiency. In: Moniz A.C. et al. (ed.). Plant-Soil Interactions at Low pH Belo Horizonte. Proceedins... Viçosa/Campinas, Brazilian Soil Science Society, 1997. pp.75-95.

[3] Camargo, C. E. O.; Ramos, L. C. S.; Ferreira Filho, A. W. P.; Felício, J. C.; Pettinelli Júnior, A.; Castro, J. L. and Yohoo, E. Y. (1999), Linhagens diplóide de trigo: produção de grãos, características agronômicas e tolerância à toxicidade de alumínio Bragantia, 58 : (2), 235-46.

[4] Caramori, P. H.; Oliveira, D. and Farias, R. T. (1991), Freqüência de ocorrência de períodos com deficiência hídrica (veranicos) no Estado do Paraná. Boletim técnico IAPAR, (36), 1-40.

[5] Carver, B. F. and Ownby Y. J. D. (1995), Acid soil tolerance in wheat. Adv. Agron., 54, 117-73.

[6] Foy, C. D. and Brower, J. C. (1964), Toxic factors in acid soils II Diferencial aluminum tolerance of plants species. Soil Sci. Soc. Am. Proc, 28, 27-32.

[7] IAPAR (2000), Informações técnicas para a cultura do trigo no Paraná. IAPAR Circular, 109, 1-152.

[8] Muzilli, O.; Santos, D.; Palhano, J. B.; Manetti Filho, J.; Lantmann, A. F.; Garcia, A. and Cataneo, A. (1978), Tolerância de cultivares de soja e de trigo a acidez do solo. R. bras. Ci. Solo, 2, 34-40.

[9] Okuyama, L. A. and Costa, A. (1990), Avaliação de genótipos de trigo para resistência à seca em solo com saturação de alumínio. Informe da Pesquisa IAPAR, 94, 37-41.

[10] Quaggio, J. A. (2000), Acidez e Calagem em Solos Tropicais. Campinas : Instituto Agronômico. 111 pp.

[11] Riede, C. R. and Campos, L. A. C. (1988), Development of wheat cultivars with higher yield and adaptation to different agroclimatic conditions of Paraná. In: Kohli, M. M.and Rajaram, S. (eds.). Wheat breeding for acid soils: Review of Brazilian/CIMMYT collaboration, 1974-1986. CIMMYT, México. pp. 26-38.

[12] Uexküll, H. R. von and Mutert, E. (1995), Global extent, development and economic impact of acid soils. Plant and Soil, 17 : (1), 5-19.

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Reaction of wheat genotypes to soil aluminum differential saturations

Abstracts

Correspondence to

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