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Crop Breeding and Applied Biotechnology

On-line version ISSN 1984-7033

Crop Breed. Appl. Biotechnol. (Online) vol.10 no.3 Viçosa Sept. 2010

http://dx.doi.org/10.1590/S1984-70332010000300003 

ARTICLE

 

Characterization of soybean genotypes for Asian soybean rust reaction

 

Caracterização de linhagens de soja quanto à reação à ferrugem asiática

 

 

Milena Moura de AraujoI,*; Natal Antonio VelloII

IUniversidade de São Paulo (USP), Centro de Energia Nuclear na Agricultura, Av. Centenário, 303, 13.416-000, Piracicaba, SP, Brazil
IIUSP, Escola Superior de Agricultura "Luiz de Queiroz", Departamento de Genética, Av. Pádua Dias, 11, 13.418-900, Piracicaba, SP, Brazil

 

 


ABSTRACT

Our objective was to characterize soybean experimental lines for Asian soybean rust reaction. In the 2004/2005 growing season, three experiments were conducted with middle-cycle and three with late-cycle genotypes, designed in randomized blocks with four replications. Twelve experimental lines and two cultivars of each cycle were used. In each experiment the plant management differs as follows: three applications of carbendazim or three of flutriafol or without applications. The experimental lines with high yield, low notes to the symptoms and resistance to lodging, were selected and tested again in the 2005/2006 growing season. Genotypes with high severity and yield were considered tolerant to rust and the low severity and high yield ones as moderately resistant. Among the medium-cycle genotypes, there was moderate resistance to rust in one line and tolerance in five. Among the late-cycle genotypes, the six lines showed moderate resistance. The line USP 97-08135 is more tolerant to rust.

Key words: Glycine max, Phakopsora pachyrhizi, breeding, genetic resistance.


RESUMO

O objetivo deste trabalho foi caracterizar linhagens de soja quanto à reação à ferrugem asiática. No ano agrícola 2004/2005 conduziu-se três experimentos com genótipos de ciclo médio e três com tardios, delineados em blocos casualizados, com quatro repetições. Utilizou-se 12 linhagens e duas cultivares, para cada ciclo. Em cada experimento, com plantas de mesmo ciclo, o manejo fitossanitário diferiu como segue: três aplicações de carbendazim ou três de flutriafol ou sem fungicida. As linhagens com elevado rendimento, com notas baixas para os sintomas e resistentes ao acamamento, foram selecionadas e novamente testadas em 2005/2006. Genótipos com elevada severidade e rendimento foram considerados tolerantes, os com baixa severidade e elevado rendimento, como moderadamente resistentes. Entre os genótipos com ciclo médio, observou-se resistência moderada em uma linhagem e tolerância em cinco. Entre os de ciclo tardio, as seis linhagens apresentaram resistência moderada. A linhagem USP 97-08135 apresenta maior tolerância à ferrugem.

Palavras-chave: Glycine max, Phakopsora pachyrhizi, melhoramento genético, resistência genética.


 

 

INTRODUCTION

In recent years, the Asian soybean rust (ASR), whose causal agent is the biotrophic fungus Phakopsora pachyrhizi (H. Sydow & P. Sydow) has been a disease of major importance to the soybean-producing countries, affecting even the United States of America in 2004 (Lynch et al. 2006). In Brazil, this disease has caused significant losses, increasing the use of fungicides and reducing the yield.

ASR is considered the most destructive soybean (Glycine max (L.) Merr.) foliar disease (Miles et al. 2003). The main symptom in infected plants is the lesions formation, consisting of pustules reaching 2 to 5 square mm, in which occurs the formation of globular structures called uredias, which produce large numbers of urediniospores. As sporulation proceeds, the leaf tissue around the first uredias acquires a light brown color (tan lesion type - sensitivity) to reddish brown (RB type of injury, reddish brown - resistance) (Bromfield et al. 1980). The ASR is spread by the wind through urediniospores, and may develop rapidly, causing a reduction in leaf area and yield (Bromfield et al. 1980).

The resistant or tolerant cultivars availability is a key component for an ASR integrated control. Genetic resistance of plants to pathogens can be defined as the ability of the host (in this case the plant) to prevent the growth and development of the pathogen (Parlevliet 1997). Parameters such as RB lesions or absence of lesions and symptoms have practical importance for genotypes differentiation for ASR resistance. RB lesions are formed by a controlled cell death process called hypersensitive response. The cells death limits the fungus development. On the other hand, on susceptible plants, the spores and the fungus enlarge their feeding sites, resulting in a clearer lesion (TAN) on the leaf tissue.

In fact, tolerance can be defined as the plant capacity to resist the pathogen development, without significant reduction in yield or quality of the product (Schafer 1970), which results from the action of polygenes with small and cumulative effects. The intensity of sporulation and periodic severity assessment are important parameters for the classification of genotypes into tolerant or susceptible to ASR. Results presented by Santos et al. (2007), showed the presence of minor genes conferring tolerance to ASR in the Brazilian soybean germplasm. This information can be useful to plant breeders and plant pathologists, to group these genes together in different genotypes, with or without the use of molecular markers.

Five genes for ASR resistance have already been identified, as Rpp1 - PI 200492 (McLean and Byth 1980), Rpp2 - PI 230970 (Bromfield and Hartwig 1980), Rpp3 - PI 462312 (Bromfield and Hartwig 1980, 1983), Rpp4 - PI 459025 (Hartwig 1986) and Rpp5 (Parker et al. 1993, Grant et al. 2000, Hayes et al. 2000, Graham et al. 2002, Garcia et al. 2008, Morceli et al. 2008). All these genes confer vertical resistance for only some races of P. pachyrhizi and the resistance conferred by these genes has already been broken in most soybean crop regions in Brazil. However, it was shown that the markers linked to gene Rpp5 are useful in the assisted selection, in early stages of plant development and pathogen absence, which streamlines the most promising genotypes selection (Morceli et al. 2008).

Many studies have been conducted with the purpose of identifying the most promising genotypes for use as an ASR resistance source. Koga et al. (2008) used multivariated analysis, Costa et al. (2008) used markers and Santos et al. (2007) evaluated the genotypes partial resistance through epidemiologic and cluster analysis.

This job aims to perform the soybean genotypes characterization for ASR resistance in order to facilitate the work of breeders in the selection of promising genotypes for the use in breeding programs.

 

MATERIAL AND METHODS

This study was conducted during the 2004/2005 and 2005/2006 growing seasons in the Department of Genetics of Escola Superior de Agricultura Luiz de Queiroz, Piracicaba, SP. In the 2004/2005 growing season, 24 experimental lines and four soybean commercial cultivars (control) were tested; they were divided into two maturity groups (middle-cycle and late-cycle). In experiments with middle-cycle experimental lines, the cultivars 'BR-16' and 'IAS-5' were used as controls. In experiments with late-cycle experimental lines, 'FT-2000' and 'Conquista' were used as controls (Table 1).

 

 

The middle-cycle experimental lines comprised 12 lines with cycles between 120 and 140 days and two controls (BR-16 and IAS-5). These lines were selected in the 2003/2004 growing season for yields of 4% to 221% higher than the best control ('Conquista', 1755 kg ha-1) in the presence of the disease. The late-cycle experimental lines comprised 12 lines with cycles between 141 and 157 days and yields 87% to 177% higher than the best control ('Conquista', 1755 kg ha-1) in the presence of ASR.

Besides the cycle and yield, it was also considered, in the selection of the 24 experimental lines, the presence of an ASR-tolerant ancestor in their genealogy, which may have contributed as sources of genes for ASR resistance or tolerance, especially: FT-2 (Godoy and Arias 2003, Yorinori et al. 2003), IAC - PL1 (Godoy and Arias 2003, Yorinori et al. 2003), Tainung 4 and PI 230970 (Taiwan - Rpp2) (Bromfield and Hartwig 1980).

To better characterize the genotypes for ASR reaction, the experiments were separated in different cycles, allocated in adjacent areas in the experimental field but separated by borders, in order to avoid the drift of fungicide to another experiment: i) Experiment I: three applications of Impact (flutriafol, 125 g L-1, Cheminova) - effective fungicide for late-cycle diseases (DFC) and ASR control; ii) Experiment II: three applications of Derosal (carbendazim, 500 g L-1, Bayer) - effective fungicide for the DFC, except ASR control; iii) Experiment III: control - without fungicides application. Fungicides were applied at the recommended dosages on the same dates, with the first application being held at the R2 stage respecting the residual products period (21 days).

Carbendazim and flutriafol treatment were opted for to provide the isolation of the ASR effect, because in the region where the experiments were held, the DFCs frequently occur, which could mask or even bring the results into question. With the adopted method, contrasting experiments carbendazim x flutriafol in yield trials, the ASR reaction effect was isolated, because in the carbendazim experiment only ASR occurs and in the flutriafol no diseases occur. On the other hand, contrasting the flutriafol with the control experiment we would simultaneously have the ASR and DFC effect, therefore the contrast between carbendazim and flutriafol were prioritized.

By the ASR reaction, comparisons were made between the carbendazim and control experiments, because in the flutriafol experiment ASR does not occur, while in the carbendazim experiment only ASR occurs, which makes the assessment more accurate.

The experiments were designed as randomized blocks with four replications of each genotype per experiment. The experimental plots were represented by four rows of 5 m x 0.5 m, and the useful plot consisted of the central rows, eliminating 0.5 m in each end of the plot, ie, 4 m2.

Evaluations were made about the ASR reaction and yield of genotypes. The ASR reaction was measured using a diagrammatic scale (Amorim 1995), in three weekly evaluations, starting at the R2 stage (first note to the ASR reaction ASR1; second note to the ASR reaction ASR2; and third note to the ASR reaction ASR3), with scores ranging from 1 (0.2% leaf area affected) to 9 (78.5% or more of leaf area affected). Within this range of 1 to 9, genotypes with scores between 1-2 were considered resistant; between 3-5 moderately resistant, between 6-7 moderately susceptible and between 8-9 susceptible. We decided to create this large scale, due to its greater efficiency in assessing the ASR reaction of genotypes, because it promotes a better subdivision, allowing an appropriate classification of the genotypes during the phenotypic evaluation. The yield of each genotype was estimated by weighing the useful plot.

The experimental lines selection was conducted under severe infestation of the disease in the field, casting aside the most susceptible genotypes to ASR. To accomplish this selection mainly the yield, the plant ASR reaction, according to the diagrammatic scale, and other traits of interest such as, lodging, plant height and agronomic value was considered. Plants with high yield in the presence of the disease, with low scores for ASR symptoms (below 6.0) and lodging (below 3.0) and high agronomic value (above 3.5) were selected for 2005/2006 growing season (Table 1).

In the 2005/2006 experiment the same design, fungicides (each fungicide was considered a separate experiment) and plot size of the previous year was used, however, 12 experimental lines were selected among the 24 tested in 2004/2005 growing season to compose these experiments. There was not a division of the experiments in two distinct cycles (middle and late), because the selected lines were in the range of transition between these two cycles, then it was not necessary to allocate the genotypes in different experiments.

It was extremely important to conduct this experiment to verify if the genotypes performance was consistent from one year to another or if there would be changes in the ASR response.

We performed the analysis of variance for the traits: yield and ASR reaction (Tables 2 and 3). For this last trait there was not a normal distribution of data, requiring the verification of the homogeneity of variances. Through the test Fmax, it was found that there was homogeneity of variances for all assessments of ASR reaction, allowing the analysis of variance, since the F test is robust to the lack of normality in cases where there is homogeneity of variances.

With the detection of significant differences between genotypes, the Scott-Knott (SK) comparison test of averages at the significance level of 5% was accomplished because this test is very efficient in the averages grouping (Bhering et al. 2008).

 

RESULTS AND DISCUSSION

The yield obtained in the experiments followed the region's pattern yield. As was expected, the average experimental lines yield in the flutriafol experiment was higher than in the carbendazim and control experiments in middle-cycle lines of the 2004/2005 and the lines of the 2005/2006 growing season, since this fungicide promoted the ASR and DFC efficient control (Table 4).

However, in the late-cycle genotypes of the 2004/2005 growing season, the yield in the flutriafol experiment did not differ statistically at 5% probability of the control experiment, and the yield in the carbendazim experiment was lower (Table 4). This is not a normal condition, as indicated by the data of the 2005/2006 growing season. Thus, physiological reactions of incompatibility between fungicides and the different genotypes may have been more significant than the effects of the fungicides in disease control in the 2005/2006 growing season.

The main characteristics of the ASR moderately resistant genotypes is the occurrence of few symptoms (notes below 6.0) and high yield, which mainly takes place in the middle-cycle genotype USP 97-08.135 (2004/2005), which remained moderately resistant to ASR over the three assessments of severity, besides presenting a lower reduction in yield. The late-cycle lines that presented ASR moderate resistance were USP 191-102-03, USP 191-103-12, USP 191-108-05, USP 98-13035, USP 98-13049 and USP 98-13.102 (2004/2005) (Tables 4 and 5).

The tolerance is characterized as the genotype ability to keep the yield, despite the plant showing severe symptoms of disease (Schafer 1970), the tolerant genotypes can be characterized for showing the yield in the flutriafol experiment approximately equal to the carbendazim experiment, and at the same time, high notes to ASR, that is, despite the tolerant plants perhaps presenting many disease symptoms, they have no significant drop in yield. On the other hand, the genotypes with higher yields in the flutriafol experiment than in the carbendazim and low notes to ASR reaction can be classified as intolerant because although they do not display many symptoms they have a decrease in the performance. But the genotypes, which have the yield in the flutriafol experiment higher than in carbendazim, which decreases yield in the presence of the disease, and have high notes, they can be characterized as susceptible.

Given the above, tolerance to ASR was verified, especially in the middle-cycle experimental line USP 04-18.029 (2004/2005). In that, among the late-cycle genotypes none were ASR tolerant.

In the 2005/2006 growing season there was no moderate resistance in the genotypes tested; however, the genotype USP 191-108-05 was closer to the tolerant behavior (Table 5). In this light, the best genotypes for a breeding program aimed at getting ASR tolerance and productive genotypes are: USP 04-18029 and USP 191-108-05. These genotypes can be used in recurrent selection cycles for the introgression of minor genes that provide ASR tolerance.

The late-cycle genotypes that showed ASR moderate resistance in the 2004/2005 growing season (USP 191-102-03, USP 191-103-12, USP 191-108-05, USP 98-13035, USP 98-13049 and USP 98-13102), could be used by farmers because they have few symptoms and high yield, however, they present a higher risk of having their resistance broken in a short term.

 

ACKNOWLEDGMENTS

he authors wish to thank CNPq and CAPES for the Master's grant to the first author and for the research assistance.

 

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Received 20 May 2009
Accepted 8 April 2010

 

 

* E-mail: mmaraujo_07@hotmail.com.

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