Abstracts

CROP SCIENCE

ARTIGO CIENTÍFICO

Correlation and path analysis in components of grain yield of cowpea genotypes¹ 1 Parte do trabalho de Monografia do primeiro autor apresentado à coordenação do curso de Graduação em Agronomia, da Universidade Federal do Ceará, Projeto apoiado pelo Conselho Nacional de Desenvolvimento Cientifico e Tecnológico/CNPq

Correlação e análise de trilha em componentes de produção de grãos de genótipos de feijão-caupi

Wener Santos de AlmeidaI, ^* * Autor para correspondência ; Francisco Ronaldo Belém Fernandes^II; Elizita Maria Teófilo^III; Cândida Hermínia Campos de Magalhães Bertini^III

^IDepartamento de Fitotecnia, Centro de Ciências Agrárias, Universidade Federal do Ceará, Av. Mister Hull 2977, Campus do Pici, Bloco 847, Fortaleza-CE, Brasil, 60.021-970, weneragronomia@gmail.com

^IIDepartamento de Engenharia Agrícola/CCA/UFC, Fortaleza-CE, Brasil, 60.021-970, ronaldoagroufc@gmail.com

^IIIDepartamento de Fitotecnia/CCA/UFC, Fortaleza-CE, Brasil, 60.021-970, elizita@ufc.br, cândida_bertini@yahoo.com.br

ABSTRACT

This study aimed at verifying the effect of genotype x environment interaction on the relative contribution of yield components and final production of different cowpea genotypes. For this, data of yield components of 22 cowpea genotypes were evaluated in four environments in the State of Ceará. A one-way ANOVA tested the variability between genotypes and the Scott-Knott test compared the mean values of the genotypes. The correlations were estimated by a path analysis. A differentiated response from the genotypes to each environment was observed for all traits examined, indicating the need to perform the test for each situation separately. The number of pods per plant is the yield component with great potential of genetic gain in additional cycles of selection of more productive genotypes. The number of pods per plant and the number of grains per pod were the yield components with greater direct effects on the productivity.

Key words:Vigna unguiculata. Genotype x environment. Direct and indirect effects.

RESUMO

Objetivou-se com esse trabalho verificar o efeito da interação genótipo x ambiente sobre a contribuição relativa dos componentes de rendimento e a produção final em genótipos de feijão-caupi. Foram utilizados dados dos componentes de produção de 22 genótipos de feijão-caupi avaliados em quatro ambientes no estado do Ceará. A análise de variância univariada foi utilizada para a determinação da variabilidade existente entre os genótipos e o teste de Scott-Knott a 5% para a comparação das médias entre os genótipos. As correlações foram estimadas através da análise de trilha. Foi observada resposta diferenciada dos genótipos para cada ambiente testado para todos os caracteres avaliados, indicando a necessidade da realização do teste para cada situação. O número de vagens por planta é o componente de rendimento com grande possibilidade de ganhos genéticos em ciclos adicionais de seleção de genótipos mais produtivos. O número de vagens por planta e número de sementes por vagem são os componentes de rendimento que apresentam maiores efeitos diretos sobre a produtividade.

Palavras-chave:Feijão-Caupi. Interação Genótipo x ambiente. Efeitos diretos e indiretos.

INTRODUCTION

The cowpea (Vigna unguiculata L. Walp) is grown mainly by small farmers, without using technology; thus obtaining low yield levels (BENVINDO et al., 2010). These low levels may be caused by phytotechnical practices, low technological level adopted by the farmer and interaction between genotypes and environments (RIBEIRO et al., 2001).

One goal of cowpea breeding programs is the achievement of more productive genotypes, adapted and stable. However, the yield is a complex trait difficult to measure (CARVALHO et al., 2002) and results from the interaction of several factors, genetic, physiological and environmental, so it cannot be considered separately (GONDIM et al., 2008).

The importance of correlating traits in genetic breeding is the possibility of assessing how the change in one trait could affect others (SANTOS; CARVALHO; SANTOS, 2000), among them the productivity. It is of paramount importance to understanding the relationships between the variables, highlighting for example those variables related to productivity. Allowing the selection of the main variable, characterized by low heritability and/or measurements difficulties, based in other(s), allowing the breeder to achieve faster progresses in the use of direct selection (FERREIRA et al., 2007).

On the other hand, there may be mistakes when interpreting the correlations, since according to Gondim et al. (2008), they do not determine the direct and indirect influences of the traits that compound the yield. With regard to this, Cruz and Carneiro (2003) reported that the high correlation between the traits that compound the yield may be result of the effect of a third or a group of traits.

Aiming to better understand the associations between the different traits, Wright (1921) proposed a method of unfolding the estimated correlations, into direct and indirect effects of the variables on a basic variable as the grain yield, whereby the estimates of effects are obtained by regression equations where the variables are previously standardized. This method is called path analysis or path coefficient analysis.

The path coefficient method allows the visualization of the direct effect that a trait caused on another, and the indirect effects of the other related traits, thus supporting the breeder (PAIVA; ROSSETTI; GONÇALVES, 1982).

The main components of cowpea yield are: number of pods per plant, grains number per pod, pod length and mass of 100 grains. Several authors have reported the importance of these yield components in cowpea crops.

Nevertheless, when the genotypes are exposed to different environments, the relationship between yield components is affected (GONDIM et al., 2008). Therefore, this study verified the effect of the interaction genotypes x environments on the relative contribution of yield components and the final production in cowpea genotypes.

MATERIAL AND METHODS

Initially, a pre-selection was carried out among 500 genotypes, resulting in 22 genotypes with superior traits as for yield components, important for the production of grains. In this study, 22 cowpea genotypes (CE-03, CE-25, CE-31, CE-46, CE-73, CE-77, CE-104, CE-113, CE-596, CE-790, CE-796, CE-798, CE-930, CE-933, CE-937, CE-939, CE-940, CE-946, CE-947, CE-949, CE-956 and CE-957), all from the cowpea Germplasm Bank (BAGCaupi) of the Center of Agrarian Sciences (CCA/UFC), were evaluated for grain yield and its components in four environments at State of Ceará. Most of these genotypes have differences in plant size, flower color, and grains color.

The four experiments considered in the present study were conducted in different periods (rainy and dry of the crop year of 2010) and locations (Cascavel, Fortaleza, Quixadá and Pentecoste). At municipalities of Cascavel and Quixadá, the sowings were performed on April (rainy period). The experiment consisted of a randomized blocks design with four replicates in plots of 2.8 m x 4.0 m. In order to remove the edge effect, the useful working area was comprised of two central rows (5.6 m²), adding up to 20 plants/plot.

The NPK fertilization was conducted according to the soil analysis and applied to the foundation at sowing. The weeding and pest control were performed according to the crop´s need, and the thinning at 15 days after sowing, resulting in one plant per hole and a population of 35,714 plants ha^-1 in the two locations.

At municipalities of Pentecoste and Fortaleza, the experiments were conducted on September and October (dry period). The experiment design consisted of a randomized blocks with four replicates in plots of 4.0 x 4.0 m (Pentecoste) and 2.0 x 3.0 m (Fortaleza), totaling a working area of 8 m² (Pentecoste) and 3 m² (Fortaleza). Crops handling were done according to the needs, and the thinning at 15 days after sowing, resulting in two plants per hole (Pentecoste) and one plant per hole (Fortaleza), adding up to a population of 50,000 plants ha^-1 and 66.666 plants ha^-1, respectively. Irrigations were undertaken by furrow in Pentecoste and by micro-sprinklers in Fortaleza.

The genotypes were evaluated after harvesting, regarding the number of pods per plant (NPP), pod length (PL), grains number per pod (SNP), mass of 100 grains (MHG), and productivity (PROD), estimated in kg ha^-1, given by the grain yield per plant in the working area of each plot.

Afterwards, a one-way analysis of variance was run to test the variability between analyzed genotypes, performing the correct stand by the method of covariance, by using the model defined by the equation Υ_ij = µ + g_i +b_j + β(X_ij - Ẍ) + Ԑ_ij, where Υ_ij = observation of the genotype i of the repetition j, µ = overall mean of the experiment, g_i = effect of the genotype i, b_j = effect of the block j, (X_ij - Ẍ) = deviation observed in the stand and Ԑ_ij = random error. The comparisons between the mean values of each examined variable in the different genotypes at each experimental site were performed by the Scott-Knott's test. Then, it was obtained the estimates of heritability in the broad sense, genetic coefficient of variation, genetic and environmental variances, for each study environment.

In order to obtain the estimates of heritability in the broad sense, the following equation was used:

Where:

V(G): genetic variance;

V(F): phenotypic variance.

The genetic variance was obtained as follows:

Where:

QMT: mean square treatments;

QMR: mean square residual;

r = number of blocks.

The phenotypic variance was obtained as follows:

Where:

QMT: mean square treatments;

r = number of blocks.

The genetic coefficient of variation was obtained as follows:

Where:

V(G): genetic variance;

: mean of the trait.

Conduct the study of path analysis, first was diagnosis made multicollinearity. The path analysis was performed according to Li (1975), to determine the direct and indirect effects of the primary components of yield. This analysis was based on the estimate of matrix of coefficients of genetic correlations. For all tests we adopted the minimum significance level of 5%.

Genetic and phenotypic variances, heritability, genetic coefficient of variation, and the path analyses were run using the software Genes (CRUZ, 2006).

RESULTS AND DISCUSSION

Significant differences were found at 0.01 probability, according to the F test for genotypes, environments, and interaction genotypes x environments for the evaluated variables, evidencing the genetic variability and different behavior of the genotypes in the environments, therefore, indicating the path analysis for each environment (Table 1). Cruz and Regazzi (2004) stated that the environment influences the effects of the primary components on the production, being important the number of environments tested.

The changes in direct and indirect effects of the yield components are caused by the effect of the interaction genotypes x environments. In this sense, Ribeiro et al. (2003), evaluating the common bean in two crops, suggested, due to the presence of significant interaction for genotypes x years, the accomplishment of path analysis for each situation.

Working with different periods of soybean sowing, Carvalho et al. (2002), also found significant interactions between genotypes and sowing times, indicating the performance of this study for each combination of effects.

The coefficient of variation ranged from 3.52% (MHG) in Quixadá to 37.79% (NPP) in Cascavel (Table 2). Bertini; Teófilo and Dias (2009), studying cowpea, have registered coefficients of variation close to the ones reported in this study, varying between 4.89% and 38.91%, for pod length and productivity, respectively, being considered low-medium values, pointing out a good experimental accuracy for all evaluated traits.

Regarding the productivity (Table 3), the genotypes that stood out in Pentecoste were CE-03, CE-31, CE-73, CE-77, CE-104, CE-596, CE-796, CE-939, CE-949, CE-956 and CE-957, with means above 900 kg ha^-1. In Fortaleza, stood out CE-31, CE-104, CE-596, CE-796, CE-939, CE-940 and CE-956, with means higher than 450 kg ha^-1; in Quixadá, the genotypes CE-31, CE-73, CE-77 and CE-940, with means above 800 kg ha^-1, and in Cascavel, CE-957, with mean productivity of 680 kg ha^-1 (Table 3).

The different productivities between genotypes within each environment are due to genetic, physiological and morphological traits intrinsic of each genotype evaluated (SANTOS et al., 2009).

Freire Filho et al. (2005) studying cowpea genotypes in Teresina (State of Piauí), have obtained results similar to found herein, where the genotypes responded differently to variation in the environment. This reinforces the need for path analysis for each environment.

In relation to the yield components, in general, it was observed a variation as function of the environment, standing out the mean values of Pentecoste (Tables 3, 4 and 5).

For the trait pod length, in Cascavel and Quixadá, had highlighted the genotypes CE-940 (22.55 and 21.32 cm, respectively), in Fortaleza and Pentecoste, the CE-940 (25.37 cm) and CE-104 (27.42 cm), respectively (Table 4).

Considering the grains number per pod, the genotypes that stood out in Cascavel (CE-31, CE-73, CE-77, CE-796, CE-930 and CE-933) presented more than 12 grains per pod. In Fortaleza, stood out the genotypes CE-25, CE-31, CE-73, CE-77, CE-930 and CE-933 (SNP>16). The genotypes CE-25, CE-31, CE-73, CE-77, CE-104, CE-113, CE-796, CE-930, CE-933 and CE-939 had been prominent in Pentecoste (SNP>15), and in Quixadá, the genotypes CE-25, CE-31 and CE-77 (SNP>14) (Table 4).

The mass of 100 grains was the most stable component when compared the four environments; with highlight the genotype CE-940 with 28.02, 28.13, 27.47 and 23.83 for Pentecoste, Cascavel, Quixadá and Fortaleza, respectively.

In the Table 6 are listed the values of genetic and statistic parameters for the variables, number of pods per plant, pod length, grains number per pod, mass of 100 grains, and productivity of the 22 cowpea genotypes evaluated in Cascavel, Fortaleza, Pentecoste and Quixadá.

The genetic coefficient of variation ranged from 14.16% (PL) to 68.51% (NPP) in Cascavel; and from 16.94% (MHG) to 33.41% (NPP) in Fortaleza. In Pentecoste this variation was between 16.75% (MHG) and 45.82% (NPP). For Quixadá, between 19.01% (MHG) and 21.84 (NPP). The values indicate the genetic variability in cowpea genotypes in the evaluated traits, indicating the possibility of selection.

Of the yield components, the number of pods per plant presented the highest genetic coefficient of variation for all tested environments, ranging from 21.84 to 68.51%. These high estimations, according to Teixeira et al. (2007), are due to genetic variability of the genotypes, once each contributes to a distinct genetic identity.

The variables that contributed most to genetic coefficient of variation were the number of pods per plant and productivity. Several studies have found results similar to the present study. Andrade et al. (2010), studying the genetic variability in cowpea, registered a maximum genetic coefficient of variation for the grain production of 31.62%.

Examining the genetic variability and correlations in cowpea on the production of green bean, Souza et al. (2007), also recorded genetic coefficients of variation higher for the number of pods per plant (22.65%) and production (20.86%). Also investigating genetic parameters in cowpea for the production of green beans, Andrade et al. (2010) verified higher estimates of genetic coefficient of variation for the production of green pods, indicating this trait as the one with highest variability for the conduction of selection.

The ratio CVg/CVe ranged from 0.88 (PROD) to 5.41 (MHG). Values below unity have occurred in Fortaleza, Pentecoste and Quixadá for the productivity, underlining that this variable has influence from the environment, hindering thus the selection process. Souza et al. (2007) found similar results, with values between 0.66 and 1.68, and affirmed that values above unity imply in situations favorable to selection, since the genetic factor is superior to environmental.

For the heritability, the pod length, grains number per pod, and mass of 100 grains presented values above 90% in all studied environments, except the grains number per pod in Cascavel (89.98%). However, the number of pods per plant and productivity ranged from 75.62 to 95.38%.

Given the heritability estimates in the evaluated environments, the productivity had the highest variation. This is probably because it is a trait controlled by several genes, pointing out that the grain productivity is strongly influenced by environmental conditions of more difficult management (LANA; CARDOSO; CRUZ, 2003).

In relation to the heritability, Kurek et al. (2001) working with common bean, affirmed that the traits with low heritability tend to hinder the selection process, maybe because they are under environmental influence. On the other hand, if an auxiliary trait has high heritability and is correlated with the interest trait with low heritability, it is more advantageous to perform the selection indirectly through the auxiliary trait.

In the diagnosis of multicollinearity, this was classified as low multicollinearity, according to the criteria proposed by Montgomery and Peck cited by Cruz and Carneiro (2003). Several authors emphasizes the importance of this study when it has aimed to carry out analyzes regression, of path, of index selection, and others. Cruz and Carneiro (2003) report that estimates of the parameters under multicollinearity, can take values absurdities or no consistency with the biological phenomena studied.

In the Table 7 are expressed the direct and indirect effects and the coefficients of genetic correlation between the traits pod length, number of pods per plant, grains number per pod, mass of 100 grains with the productivity of 22 cowpea genotypes evaluated in four environments.

The coefficient of determination (R²) and the residual effect indicate how much the explanatory variables determine the productivity. The coefficient of determination was 0.905; 0.756; 0.868 and 0.776 and the residual effect was 0.309; 0.494; 0.363 and 0.472 for Cascavel, Fortaleza, Pentecoste and Quixadá, respectively.

Analyzing the correlation coefficient in Cascavel, it was possible to observe that the productivity is positively correlated with the number of pods per plant (0.864) and mass of 100 grains (0.169), indicating that increases in these traits are positively reflected in productivity, and negatively with the grains number per pod (-0.200), pointing out that the higher the number of grains per pod the lower the productivity, and the pod length had no relationship (-0.007) with the productivity.

In Fortaleza, the traits pod length (0.309), number of pods per plant (0.271), grains number per pod (0.289) and mass of 100 grains (0.102) had positive correlation with productivity, but of low magnitude.

Furthermore, in Pentecoste the productivity had positive correlation with the number of pods per plant (0.799) and mass of 100 grains (0.042). The low correlation between pod length (-0.092) and mass of 100 grains (0.042) and productivity indicated lack of association between these variables.

In Quixadá, the pod length (0.402), number of pods per plant (0.235), grains number per pod (0.511) and mass of 100 grains (0.125) showed positive correlation with productivity.

Therefore, the yield component with greater effect on the productivity in the evaluated environments was the number of pods per plant. Divergent results were verified by Ramos Júnior; Lemos and Silva (2005), which observed greater influence from the mass of 100 grains and grains number per pod on the productivity.

Given the above, it was observed that the yield components and productivity, for each environment, had been correlated with different magnitudes. In relation to the different magnitudes of correlations, Ribeiro et al. (2001) have ascribed to the fact that they were estimated in different environments. With this, Santos and Vencovsky (1986) affirmed that new correlations should be estimated to aid in the conduct of the study.

Nevertheless, Cabral et al. (2011) commented that the study of correlations is a measure of association and does not allow concluding about the cause-effect relationship. Silva et al. (2005) added that the path analysis provides details of direct and indirect effects of the involved traits, thus complementing the information given by the correlation.

Considering the direct effects on productivity, in Cascavel, the number of pods per plant had the highest effect (1.089), followed by the grains number per pod (0.451) and mass of 100 grains (0.322). The pod length (-0.062) had negative effect with productivity and of low magnitude.

In Fortaleza, the grains number per pod (1.368) presented the highest direct effect on the productivity, followed by the number of pods per plant (1.255) and mass of 100 grains (0.396). The pod length (-0.072), in Fortaleza, was equal to Cascavel, whose effect was negative and of low magnitude.

The component with the highest direct effect on productivity in Pentecoste was the number of pods per plant (1.223), followed by the grains number per pod (0.670) and mass of 100 grains (0.473). The pod length (-0.151) was similar to the other environments, that is, the effect was low and negative.

Differently from the other environments, in the municipality of Quixadá, all the yield components had direct and positive effects, including the pod length (0.158). The component with the greatest direct effect was the grains number per pod (0.913), followed by the number of pods per plant (0.819) and mass of 100 grains (0.421).

These results show that the direct effects of yield components on the productivity varied according to the environment. However, stress the importance of performing these evaluations in the different environments, since it prevent mistakes when selecting the materials. Searches developed by Ribeiro et al. (2003) with common bean from two crops, found variations in the direct effects as function of the genotypes, locations and years.

In turn, the indirect effects had relatively low and negative results. In this way, Kurek et al. (2001) also found a trend of indirect negative effects, implying in a negative correlation, i.e., the increase in one corresponds to the decrease in the other. The same authors stated that this can be attributed to intrinsic competition of the plant for photoassimilates and to environmental factors.

In general, in this study the selection through traits with indirect effects among yield components seems not to be a good strategy for genetic improvement, once in the most studied components, the indirect effects were low and negative. However, Cabral et al. (2011) indicated the indirect selection, since the indirect effects were high, being thus an indicative of the feasibility of indirect selection for achieving gains for the trait with higher primary importance.

With regard to the direct effect on the yield, the number of pods per plant and grains number per pod presented good strategy to enhance the productivity. On the other hand, the number of pods per plant is the most important trait, among those evaluated herein, because associated with a high direct effect, it has a high genetic coefficient of variation, ratio CVg/CVe higher than unity, and high heritability, favoring the genotype selection.

CONCLUSIONS

1. The environment influenced on the intensity with which the yield traits explained the productivity;

2. The number of pods per plant is the yield component most likely of genetic gains in additional cycles of selection of more productive genotypes;

3. The number of pods per plant and the grains number per pod are the yield components with higher direct effects on productivity.

Recebido para publicação em 04/12/2012

Aprovado em 18/05/2014

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