Phenotypic correlations and path analysis for plant architecture traits and grain production in three generations of cowpea

Ribeiro, Hugo Leonardo Coelho; Santos, Carlos Antônio Fernandes; Diniz, Laerte da Silva; Nascimento, Layana Alves do; Nunes, Edna Deodato

doi:10.1590/0034-737X201663010005

ABSTRACT

The objective of this study was to analyze the phenotypic correlation and path analysis of traits related to plant architecture, earliness and grain yield in F₂, BC₁ and BC₂ generations, from crosses between cowpea cultivars BRS Carijó and BR14 Mulato. Most phenotypic correlations of the examined traits were concordant in statistical significance, with approximate values among the examined generations. For the trait seed weight, significant and positive phenotypic correlations were observed in the three generations only for the trait number of secondary branches. The values of the direct effects were in agreement with the values of the phenotypic correlations, which indicate true association by the phenotypic correlation among the traits of grain yield examined. Path analysis indicated that the selection of productive plants will result in early plants and an increased number of secondary branches. In F_2, plants with shorter length of the main branch and shorter length of secondary branches can be obtained. The causal model explained 15 to 30% of the total variation in grain weight in relation to the traits examined. The analyses indicated the possibility of selecting plants with a higher and early grain yield, shorter length of primary branches and lower number of nodes, which are important variables for mechanical or semi-mechanical harvesting.

Key words:
Vigna unguiculata; Mechanical harvesting; Plant habits

RESUMO

O objetivo desse trabalho foi analisar correlações fenotípicas e análise de trilha de caracteres relacionados à arquitetura da planta, precocidade e produção de grãos em gerações F₂, BC₁ e BC₂, provenientes do cruzamento entre as cultivares de feijão caupi BRS Carijó e BR14 Mulato. A maioria das correlações fenotípicas dos caracteres avaliados foi concordante em significância, com valores aproximados nas gerações avaliadas. Para o caráter peso de grãos, foram observadas correlações fenotípicas significativas e positivas nas três gerações apenas com o caráter número de ramos secundários. Os valores dos efeitos diretos concordaram com os valores das correlações fenotípicas, indicando verdadeira associação entre os caracteres avaliados com peso de grãos. A análise de trilha indicou que a seleção de plantas produtivas resultará em plantas precoces e de maior número de ramos secundários. Em F₂, plantas com menor comprimento de ramo principal e comprimento de ramos secundários poderão ser obtidas. O modelo causal explicou de 15 a 30% da variação total de peso de grãos em relação aos caracteres avaliados. As análises indicaram a possibilidade de selecionar plantas com maior produção de grãos, precoces, com menor comprimento de ramos primários e menor número nós, que são variáveis importantes para a colheita mecânica ou semi-mecânica.

Palavras-chave:
Vigna unguiculata; Colheita mecânica; Porte da planta

INTRODUCTION

Cowpea (Vigna unguiculata (L.) Walp.) is one of the most adapted, versatile and nutritious legumes among the cultivated species, constituting an important food stuff and essential production component in dry climate regions of the tropics, covering part of Asia, the United States, the Middle East and Central and South America (Singh et al., 2002Singh BB, Ehlers JD, Sharma B & Freire Filho FR (2002) Recent progress in cowpea breeding. In: Fatokim CA, Tarawali SA, Singht BB, Kormama PM & Tamo M (Eds.) Challenges and opportunities for enhancing sustainable cowpea production. Ibadan, IITA. p.22-38.). In Brazil, cowpea is grown mainly in the semiarid northeast, where it is adapted to the climatological and soil conditions, contributing to 35.6% of the planted area and 15% of the total bean production (cowpea + common bean) in the country (Silva, 2009Silva KJD (2009) Estatística da Produção de feijão caupi. Disponível em: <Disponível em: http://www.portaldoagronegocio.com.br/conteudo.php?id=34241 >. Acessado em: 22 de abril de 2011.
http://www.portaldoagronegocio.com.br/co... ).

The cowpea crop, traditionally explored in family farming systems, in rainfed agriculture and with a low level of technology, has been researched more intensively over the past few decades (Xavier, et al., 2005Xavier GR, Martins LMV, Rumjanek NG & Freire Filho FR (2005) Variabilidade genética em acessos de caupi analisada por meio de marcadores RAPD., Pesquisa Agropecuária Brasileira 40:353-359.). This has led to an improvement in yield, which, among other factors, has attracted the attention of medium and large producers (Bezerra et al., 2008Bezerra AA de C, Távora FJAF, Freire Filho FR & Ribeiro VQ (2008) Morfologia e produção de grãos em linhagens modernas de feijão caupi submetidas a diferentes densidades populacionais. Revista de Biologia e Ciências da Terra, 8:85-93.; Freire Filho et al., 2005Freire Filho FR (2005) Melhoramento Genético. In: Freire Filho FR, Lima JA de A & Ribeiro VQ (Eds.) Feijão caupi: avanços tecnológicos. Brasília, Embrapa Informação Tecnológica. p.29-75.), with emphasis in the region of the 'Cerrados', to use it in crop rotation with major crops, like corn and soybean. Thus, these facts have generated a demand for cultivars to meet the requirements of management and handling in technified systems.

Plant habits and growth have direct influence on the response of cowpea to population management because of the observed decrease in grain production per plant, as a consequence of the increased plant population per hectare, which occurs to a lesser degree in the erect than in the climbing genotypes (Cardoso et al., 1997Cardoso MJ, Melo F de B & Andrade Júnior AS de (1997) Densidade de plantas de caupi em regime irrigado., Pesquisa Agropecuária Brasileira 32:399-405.; Nangju et al., 1975Nangju D, Little TM & Anjorinohu A (1975) Effect of plant density and spatial arrangement on seed yield of cowpea (Vigna unguiculata (L.) Walp). Journal of the American Society for Horticultural Science, 100:467-470.). Bezerra et al. (2005Bezerra AA de C (2005) Efeitos de arranjos populacionais na morfologia e produtividade de feijão caupi de crescimento determinado e porte ereto Tese de doutorado. Universidade Federal do Ceará, Fortaleza. 123p.) state that the plant architecture and the production system have an influence in determining the arrangement of more adequate plant number to efficiently take advantage of the production factors and maximize the production potential of the cultivar.

In this sense, the intrinsic characteristics of ideotypes for cowpea that allow mechanized or semi-mechanized harvesting should be incorporated into the plant aiming at obtaining genotypes that resemble the common bean plant (Phaseolus vulgaris L.), facilitating commercial exploitation on a large scale. According to Adams (1982Adams MW (1982) Plant architecture and yield breeding. Iowa Journal of Research, 56:225-254.) and Matos Filho et al. (2009Matos Filho CHA, Gomes RLF, Rocha MM, Freire Filho FR & Lopes AC de A (2009) Potencial produtivo de progênies de feijão-caupi com arquitetura ereta de planta., Ciência Rural 39:348-354.) features such as length and number of nodes of the main stem and number of leaves should be taken into account because the size of the plant should allow penetration and light interception, be resistant to damping and lodging, facilitate mechanical harvesting, have length and number of nodes of reasonable business and physiological efficiency in the conversion of metabolic products in grain production.

The estimates of the correlation coefficients permit to foresee the alterations in a specific trait that is caused by the selection pressure imposed on other traits (Coimbra et al., 1999Coimbra JLM, Guidolin AF, Meroto Júnior A, Sangoi L, Ender M & Carvalho FIF de (1999) Estabilidade fenotípica em genótipos de canola no planalto catarinense. Ciência Rural, 4:74-82.). This analysis is of great relevance because in breeding programs, apart from improving a specific trait, other traits of the plant are usually improved (Cruz et al., 2006Cruz CD, Regazzi AJ & Carneiro PCS (2006) Modelos biométricos aplicados ao melhoramento genético. 2ª ed.. Viçosa, Editora UFV 585p.).

The path analysis method that was developed by Wright (1921Wright S (1921) Correlation and causation. Journal of Agricultural Research, 20:557-585.) allows the participation of the correlation coefficients in direct and indirect effects. Cruz et al. (2006Cruz CD, Regazzi AJ & Carneiro PCS (2006) Modelos biométricos aplicados ao melhoramento genético. 2ª ed.. Viçosa, Editora UFV 585p.) define the path coefficient or cause and effect analysis as a standardized regression coefficient because path analysis is composed of an expansion of multiple regression when complex interrelationships are involved.

Studies of contrasting populations of cowpea plants and progeny resulting from crossings and backcrossings, using methods such as phenotypic correlation and path analysis, maximize knowledge about the characters involved in the formation of the plant. The use of F₂ populations, BC₁ and BC₂ in these studies help in a positive way the understanding of genetic interactions, its causes and effects in the environment in which these populations were tested.

Some studies have been carried out to examine correlations between traits and path analysis. Brothers and Kelly (1993Brothers ME & Kelly JD (1993) Interrelationship of plant architecture and yield components in pinto bean ideotype. Crop Science, 33:1234-1238.) observed a negative correlation in common bean in the values obtained for architecture and secondary branch angle. Collicchio et al. (1997Collicchio E, Ramalho MAP & Abreu A de FB (1997) Associação entre o porte da planta de feijoeiro e o tamanho dos grãos., Pesquisa Agropecuária Brasileira 32:97-304.) quoted a non-association between the plant habit and the weight of 100 seeds, which makes it possible to select erect common bean plants of any seed size. Oliveira et al. (1990Oliveira FJ de, Silva MAV & Gomes MJ (1990) Seleção de caracteres agronômicos do feijão caupi usando coeficientes de caminhamento., Pesquisa Agropecuária Brasileira 25:1055-1064.) observed positive correlations in cowpea between the length of the main branch, number of lateral branches and number of nodes with leaves per plant. They also quoted the positive indirect effect between grain production with length and number of nodes of the main branch, foliar area and number of lateral branches by number of pods per plants. Bezerra et al. (2001Bezerra AA de C, Assunção Filho CJ, Freire Filho FR & Ribeiro VQ (2001) Inter-relação entre caracteres de caupi de porte ereto e crescimento determinado. Pesquisa Agropecuária Brasileira, 36:137-142.) observed the negative direct effect of the number of nodes of the main branch on grain yield (-0.52) and a genetic correlation of 0.32.

The goal of this was to analyze the phenotypic correlations and path analysis of three segregating generations of the same cross of cowpea with the objective of developing adequate genotypes for mechanical or semi-mechanical harvesting.

MATERIAL AND METHODS

Individual plants of the following populations were examined: F₂, BC₁((BRS Carijó x BR14 Mulato) x BRS Carijó) and BC₂((BRS Carijó x BR14 Mulato) x BR14 Mulato) with 186, 102 and 90 individuals, respectively, derived from the cross between BRS Carijó, which shows erect stature, determinate growth and a cycle of 58 days from planting to the first harvest, and BR14 Mulato, which shows climbing stature, indeterminate growth and a cycle of 75 days from planting to the first harvest.

Crosses and backcrosses were carried out at flower initiation of the plants, according to Rachie et al. (1975Rachie KO, Rawal KM & Franckowiak JD (1975) A rapid method for hand crossing cowpea. Ibadan, IITA. 5p. (Techinical Bulletin, 2).). Backcrosses were carried out between F₁(BRS Carijó x BR14 Mulato) x P₂, abbreviated as BC₁, and F₁(BRS Carijó x BR14 Mulato) x P₁, abbreviated as BC₂. Besides the seeds of the backcrosses, seeds were obtained from the parents and the F₂, through self-fertilization of the latter and the F₁, respectively.

The F₂, BC₁ and BC₂ generations were planted in the Bebedouro Experimental Field of Embrapa Semiárido, Petrolina, PE. Each row was 30m long with spacing of 1.5m x 0.2m between the lines and the holes, respectively. External lateral borders for the experiment were realized by planting cowpea seeds of the 'Canapu' type.

The examined traits were days to maturity of the pod (DPM), which was the number from sowing to maturity of approximately 50% of the pods; length of the main branch (LMB), which consisted of length, in cm, between the stem base and the apex of the main branch; length of the largest secondary branch (LSB), which was measured, in cm, from the beginning to the apex of the largest secondary branch; numbers of secondary branches (NSB), which was the number of secondary branches inserted into the stem of the plant; number of nodes of the main branch (NOD), which was the number of nodes from the insertion node of the unifoliar leaves until the last node of the main branch and the weight of the grains (GW),which consisted of the total weight, in grams (g), of grains with 13% of humidity, produced individually per plant of each examined generation.

The estimates of the phenotypic correlation coefficients between the pairs of traits were calculated based on the estimates of the variances and covariances according to Kempthorne (1973Kempthorne O (1973) An introduction to genetic statistics. Ames, The State University Press. 454p.).

, so: . In which V(X + Y): variance of the sum of the traits X and Y; V(X) and V(Y): variance of the traits X and Y, respectively; COV(X,Y): covariance between the traits X and Y.

The phenotypic correlation (r_F) is given by .

The path analysis was represented by the cause-effect diagram in Figure 1 and shows the interrelationships between GW, dependent variable and the non dependent variables DPM, LMB, LSB, NSB and NOD. In the cause-effect diagram (Figure 1), the unidirectional arrows represent the direct influence of each of the explanatory traits on the main trait, measured by the path coefficient (Pjn), while the bidirectional arrows indicate correlation between the traits, which is measured by the coefficient (rij). The direct influence is measured by the sum total of the products of the correlation coefficients by the path coefficients. All the analyses were performed with the GENES software (Cruz, 2006Cruz CD (2006) Programa Genes - Biometria. Viçosa, Editora UFV. 382p.).

Figure 1:
Causal diagram of the direct and indirect effects of the explanatory variables 2, 3, 4, 5 and 6 correlated (r) with the main variable grain weight (1) and with the residual, non-correlated variable X.

RESULTS AND DISCUSSION

Concordant phenotypic correlations were obtained with statistical significance and approximate values in the three generations analyzed, namely LMB x LSB, CPR x NOD, LSB x NOD and NSB x GW (Table 1). Apart from the correlation between traits being specific to a population (Santos & Gilmara, 2004Santos CAF & Gilmara MS (2004) Correlações fenotípicas em dois cruzamentos de feijão caupi nas gerações F2, F3, F4 e F5. Horticultura Brasileira, 22. CD-ROM.), not serving as reference relation between two traits for a given species, a large concordance was expected because the three examined generations resulted from the same cross. Kurer (2010Kurer S, Gangaprasad S, Uma MS, Shanthakumar G & Salimath PM (2010) Genetic variability studies in F2 and F3 generations of cowpea (Vigna unguiculata (L.) Walp)., Electronic Journal of Plant Breeding 1:1344-1346.) found similar data when evaluating two generations of a cowpea cross and reported a phenotypic correlation of 0.044 (F₂) and a significant value of 0.357 (F₃) between plant height and weight of 100 grains, and significant and similar correlations of 0.462 and 0.392 in F₂ and F₃, respectively, between the number of branches and pods per plant.

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Table 1:
Estimates of the phenotypic correlation coefficient between the traits days to maturity of the pod (DPM), length of the main branch (LMB), length of the secondary branch (LSB), number of secondary branches (NSB), number of nodes of the main branch (NOD) and grain weight (GW) in the F₂, BC₁ and BC₂ generations of the cross between BRS Carijó x BR14 Mulato.

With regard to grain weight (GW), significant and positive phenotypic correlations were observed for the trait number of secondary branches (NSB) that was examined in the three generations, significant and negative for days to maturity (DPM) in the F₂ and BC₂ generations, while a significant and positive estimate was found for the length of the secondary branch in the BC₂ generation, whereas for the other variables the values were non-significant (Table 1). Kurer (2010Kurer S, Gangaprasad S, Uma MS, Shanthakumar G & Salimath PM (2010) Genetic variability studies in F2 and F3 generations of cowpea (Vigna unguiculata (L.) Walp)., Electronic Journal of Plant Breeding 1:1344-1346.) and Souza et al. (2007Souza CLC de, Lopes AC de A, Gomes RLF, Rocha M de M & Silva EM (2007) Variability and correlations in cowpea populations for green-grain production., Crop Breeding and Applied Biotechnology 7:262-269.) also reported significant and positive results between grain productivity and number of secondary branches. Benvindo et al. (2010Benvindo RN, Silva JAL da, Freire Filho FR, Almeida ALG de, Oliveira JTS & Bezerra AA de C (2010) Avaliação de genótipos de feijão caupi de porte semi-prostrado em cultivo de sequeiro e irrigado. Comunicata Scientiae, 1:23-28.), who examined cowpea genotypes, reported a non-significant and negative phenotypic correlation between initial flowering and productivity, which differs from the observations in the present study.

The values of the phenotypic correlations suggest a difficulty for the selection of productive plants with a smaller number of secondary branches because the correlations were positive and significant for these traits in the three generations examined (Table 1). The data of the phenotypic correlations indicate, however, the possibility of selecting productive plants with smaller, shorter secondary branches, earliness to grain production, with smaller main branches and a smaller number of nodes because the values were non-significant or negatively significant in the generations examined, except for the number of secondary branches in the BC₂ generation whose values for the three generations analyzed were positive and significant, indicating the possibility of obtaining biased plants to damping (Table 1).

The highest positive values of phenotypic correlations were observed between LMB x NOD, LMB x LSB and LSB x NOD (Table 1) in the examined generations, which indicates that the positive selection of one of these traits will result in increases in the other two traits, in other words, the negative selection should be performed to obtain plants with an architecture that is suitable for mechanical or semi-mechanical harvesting.

The direct values of the causal effect of the plant architecture traits and days to maturity in the grain production were in agreement in the three generations examined for the majority of the variables studied, except for the length of the main branch and the secondary branches (Figure 2). The values of the direct effects were in agreement with the values of the estimates of the phenotypic correlations, which indicate that they explain the true association that exists between the traits of plant architecture and earliness of grain production (Table 1 and Figure 2). Bezerra et al. (2001Bezerra AA de C, Assunção Filho CJ, Freire Filho FR & Ribeiro VQ (2001) Inter-relação entre caracteres de caupi de porte ereto e crescimento determinado. Pesquisa Agropecuária Brasileira, 36:137-142.) reported similarities between path analysis and genetic correlations for initial flowering traits and weight of 100 grains in relation to grain yield. On the other hand, Peksen and Artik (2004Peksen E & Artik C (2004) Comparison of some Cowpea (Vigna unguiculata L. Walp) Genotypes from Turkey for Seed Yield and Yield Related Characters. Journal of Agronomy, 3:137-140.) reported different values between the direct effect (0.195) and significant simple correlation (0.509) for the trait weight of 100 grains in relation to grain yield.

Figure 2:
Diagram of the system between causes and effects showing the direct effect of the five explanatory variables days to maturity (DPM), length of the main branch (LMB), length of the secondary branch (LSB), number of secondary branches (NSB) and number of nodes of the main branch (NOD) correlated with the main variable grain weight (GW) examined in the F₂, BC₁ and BC₂ generations that were obtained from a cross between BRS Carijó x BR14 Mulato cowpea.

The path analysis indicates that the selection of productive plants will result in early plants (DPM) and in an increased number of secondary branches (NSB) (Figure 2). Plants with a shorter length of the main branch (LMB) in the F₂ and BC₁ generations and with shorter branches in the F₂ generation can be obtained during the selection because they show negative direct values in relation to grain production. Kumari et al. (2010Kumari RU, Usharani KS, Suguna R & Anandakumar CR (2010) Relationship between the yield contributing characters in cowpea for grain purpose [vigna unguiculata (L). Walp]. Electronic Journal of Plant Breeding, 1:882-884.) reported the negative direct effect of days to maturity and number of branches in relation to grain yield, which indicates the possibility of selecting early, productive plants with shorter branches. Bezerra et al. (2001Bezerra AA de C, Assunção Filho CJ, Freire Filho FR & Ribeiro VQ (2001) Inter-relação entre caracteres de caupi de porte ereto e crescimento determinado. Pesquisa Agropecuária Brasileira, 36:137-142.), as well as Peksen and Artik (2004Peksen E & Artik C (2004) Comparison of some Cowpea (Vigna unguiculata L. Walp) Genotypes from Turkey for Seed Yield and Yield Related Characters. Journal of Agronomy, 3:137-140.), reported similar negative direct effects (-0.188 and -0.134, respectively) in relation to cowpea grain yield.

The determination coefficients of the causal model, considering the five explanatory variables, were 0.1590, 0.2260 and 0.2992 of the F₂, BC₁ and BC₂ generations, respectively (Figure 2), which indicates that the adopted model explains a small fraction of the primary grain weight variable and that new variables should be included in the causal model to explain the quasi-totality of the variation of the grain production. This low determination was expected because variables such as number of pods per plant, number of seeds per pod and weight of a grain were not included in the present model. Taking these variables into consideration, Bezerra et al. (2001Bezerra AA de C, Assunção Filho CJ, Freire Filho FR & Ribeiro VQ (2001) Inter-relação entre caracteres de caupi de porte ereto e crescimento determinado. Pesquisa Agropecuária Brasileira, 36:137-142.), who evaluated cowpea and Santos et al. (1995Santos CAF, Reis MS, Cruz CD, Sediyama CS & Sediyama T (1995) Adequação de Modelos no Estudo do Coeficiente de Trilha dos Componentes Primários e Secundários de Progênies F6 de Soja (Glycine Max (L.) Merrill). Revista Ceres, 42:111-121.) who evaluated soybean, reported a determination coefficient of 84.32% and 100%, respectively. Gonçalves et al. (2003Gonçalves MC, Correa AM, Destro D, Souza LCF de & Sobrinho T (2003) A Correlations and path analysis of common bean grain yield and its primary components. Crop Breeding and Applied Biotechnology, 3:217-222.) showed a determination coefficient of 97.5%, which is similar to that found by Cabral et al. (2011Cabral PDS, Soares TCB, Lima ABP, Soares YJB & Silva JAD de (2011) Análise de trilha do rendimento de grãos de feijoeiro (Phaseolus vulgaris L.) e seus componentes. Revista Ciência Agronômica, 42:132-138.) (R² = 95.9%), which indicates that the variables almost completely explained the basic variable in common beans.

CONCLUSION

In general, the information of the phenotypic correlations and of the direct effects of the plant architecture variables and days to maturity indicated that it is possible to select plants with an increased grain production and with a smaller number of days to harvest and with a shorter length of the main branch and shorter length of the secondary branch, which are important characteristics for mechanical or semi-mechanical harvesting. Similarly, the results show difficulties for the selection of plants with a smaller number of secondary branches, which is an important variable for mechanical or semi-mechanical harvesting.

ACKNOWLEDGMENT

The authors thank FAPESB for granting the scholarship.

REFERENCES

Adams MW (1982) Plant architecture and yield breeding. Iowa Journal of Research, 56:225-254.
Benvindo RN, Silva JAL da, Freire Filho FR, Almeida ALG de, Oliveira JTS & Bezerra AA de C (2010) Avaliação de genótipos de feijão caupi de porte semi-prostrado em cultivo de sequeiro e irrigado. Comunicata Scientiae, 1:23-28.
Bezerra AA de C (2005) Efeitos de arranjos populacionais na morfologia e produtividade de feijão caupi de crescimento determinado e porte ereto Tese de doutorado. Universidade Federal do Ceará, Fortaleza. 123p.
Bezerra AA de C, Assunção Filho CJ, Freire Filho FR & Ribeiro VQ (2001) Inter-relação entre caracteres de caupi de porte ereto e crescimento determinado. Pesquisa Agropecuária Brasileira, 36:137-142.
Bezerra AA de C, Távora FJAF, Freire Filho FR & Ribeiro VQ (2008) Morfologia e produção de grãos em linhagens modernas de feijão caupi submetidas a diferentes densidades populacionais. Revista de Biologia e Ciências da Terra, 8:85-93.
Brothers ME & Kelly JD (1993) Interrelationship of plant architecture and yield components in pinto bean ideotype. Crop Science, 33:1234-1238.
Cabral PDS, Soares TCB, Lima ABP, Soares YJB & Silva JAD de (2011) Análise de trilha do rendimento de grãos de feijoeiro (Phaseolus vulgaris L.) e seus componentes. Revista Ciência Agronômica, 42:132-138.
Cardoso MJ, Melo F de B & Andrade Júnior AS de (1997) Densidade de plantas de caupi em regime irrigado., Pesquisa Agropecuária Brasileira 32:399-405.
Coimbra JLM, Guidolin AF, Meroto Júnior A, Sangoi L, Ender M & Carvalho FIF de (1999) Estabilidade fenotípica em genótipos de canola no planalto catarinense. Ciência Rural, 4:74-82.
Collicchio E, Ramalho MAP & Abreu A de FB (1997) Associação entre o porte da planta de feijoeiro e o tamanho dos grãos., Pesquisa Agropecuária Brasileira 32:97-304.
Cruz CD (2006) Programa Genes - Biometria. Viçosa, Editora UFV. 382p.
Cruz CD, Regazzi AJ & Carneiro PCS (2006) Modelos biométricos aplicados ao melhoramento genético. 2ª ed.. Viçosa, Editora UFV 585p.
Freire Filho FR (2005) Melhoramento Genético. In: Freire Filho FR, Lima JA de A & Ribeiro VQ (Eds.) Feijão caupi: avanços tecnológicos. Brasília, Embrapa Informação Tecnológica. p.29-75.
Gonçalves MC, Correa AM, Destro D, Souza LCF de & Sobrinho T (2003) A Correlations and path analysis of common bean grain yield and its primary components. Crop Breeding and Applied Biotechnology, 3:217-222.
Kempthorne O (1973) An introduction to genetic statistics. Ames, The State University Press. 454p.
Kumari RU, Usharani KS, Suguna R & Anandakumar CR (2010) Relationship between the yield contributing characters in cowpea for grain purpose [vigna unguiculata (L). Walp]. Electronic Journal of Plant Breeding, 1:882-884.
Kurer S, Gangaprasad S, Uma MS, Shanthakumar G & Salimath PM (2010) Genetic variability studies in F₂ and F₃ generations of cowpea (Vigna unguiculata (L.) Walp)., Electronic Journal of Plant Breeding 1:1344-1346.
Matos Filho CHA, Gomes RLF, Rocha MM, Freire Filho FR & Lopes AC de A (2009) Potencial produtivo de progênies de feijão-caupi com arquitetura ereta de planta., Ciência Rural 39:348-354.
Nangju D, Little TM & Anjorinohu A (1975) Effect of plant density and spatial arrangement on seed yield of cowpea (Vigna unguiculata (L.) Walp). Journal of the American Society for Horticultural Science, 100:467-470.
Oliveira FJ de, Silva MAV & Gomes MJ (1990) Seleção de caracteres agronômicos do feijão caupi usando coeficientes de caminhamento., Pesquisa Agropecuária Brasileira 25:1055-1064.
Peksen E & Artik C (2004) Comparison of some Cowpea (Vigna unguiculata L. Walp) Genotypes from Turkey for Seed Yield and Yield Related Characters. Journal of Agronomy, 3:137-140.
Rachie KO, Rawal KM & Franckowiak JD (1975) A rapid method for hand crossing cowpea. Ibadan, IITA. 5p. (Techinical Bulletin, 2).
Santos CAF & Gilmara MS (2004) Correlações fenotípicas em dois cruzamentos de feijão caupi nas gerações F₂, F₃, F₄ e F₅ Horticultura Brasileira, 22. CD-ROM.
Santos CAF, Reis MS, Cruz CD, Sediyama CS & Sediyama T (1995) Adequação de Modelos no Estudo do Coeficiente de Trilha dos Componentes Primários e Secundários de Progênies F6 de Soja (Glycine Max (L.) Merrill). Revista Ceres, 42:111-121.
Silva KJD (2009) Estatística da Produção de feijão caupi. Disponível em: <Disponível em: http://www.portaldoagronegocio.com.br/conteudo.php?id=34241 >. Acessado em: 22 de abril de 2011.
» http://www.portaldoagronegocio.com.br/conteudo.php?id=34241
Singh BB, Ehlers JD, Sharma B & Freire Filho FR (2002) Recent progress in cowpea breeding. In: Fatokim CA, Tarawali SA, Singht BB, Kormama PM & Tamo M (Eds.) Challenges and opportunities for enhancing sustainable cowpea production. Ibadan, IITA. p.22-38.
Souza CLC de, Lopes AC de A, Gomes RLF, Rocha M de M & Silva EM (2007) Variability and correlations in cowpea populations for green-grain production., Crop Breeding and Applied Biotechnology 7:262-269.
Wright S (1921) Correlation and causation. Journal of Agricultural Research, 20:557-585.
Xavier GR, Martins LMV, Rumjanek NG & Freire Filho FR (2005) Variabilidade genética em acessos de caupi analisada por meio de marcadores RAPD., Pesquisa Agropecuária Brasileira 40:353-359.

Publication Dates

Publication in this collection
Jan-Feb 2016

History

Received
25 Feb 2014
Accepted
21 Oct 2015

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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» http://www.portaldoagronegocio.com.br/conteudo.php?id=34241

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[29] Xavier GR, Martins LMV, Rumjanek NG & Freire Filho FR (2005) Variabilidade genética em acessos de caupi analisada por meio de marcadores RAPD., Pesquisa Agropecuária Brasileira 40:353-359.

Brasil

Brasil

Phenotypic correlations and path analysis for plant architecture traits and grain production in three generations of cowpea¹ Extracted from the first author's Masters thesis..

Correlações fenotípicas e análise de trilha para caracteres da arquitetura da planta e produção de grãos em três gerações de feijão caupi

ABSTRACT

RESUMO

INTRODUCTION

MATERIAL AND METHODS

RESULTS AND DISCUSSION

CONCLUSION

ACKNOWLEDGMENT

REFERENCES

Publication Dates

History

Brasil

Brasil

Phenotypic correlations and path analysis for plant architecture traits and grain production in three generations of cowpea1 Extracted from the first author's Masters thesis..

Correlações fenotípicas e análise de trilha para caracteres da arquitetura da planta e produção de grãos em três gerações de feijão caupi

ABSTRACT

RESUMO

INTRODUCTION

MATERIAL AND METHODS

RESULTS AND DISCUSSION

CONCLUSION

ACKNOWLEDGMENT

REFERENCES

Publication Dates

History

Phenotypic correlations and path analysis for plant architecture traits and grain production in three generations of cowpea¹ Extracted from the first author's Masters thesis..