Genotype x environment interaction and stability in landraces of cowpea under dryland conditions

Rolim, Rubens R.; do Nascimento, Naysa F. F.; Nascimento, Mayana F.; de Araujo, Helder F. P.

doi:10.1590/1983-21252023v36n211rc

ABSTRACT

Cowpea (Vigna unguiculata (L.) Walp.) is an excellent crop for research in semi-arid regions, due to its tolerance to high temperatures and water deficit, with satisfactory yields in rain-fed cultivation. The objective this work was to evaluate the genotype x environment (G × E) interaction, adaptability and stability of cowpea landraces used in the Cariri, Paraíba, in the semiarid region of Northeast Brazil. The experiment was carried out under rain-fed conditions in two locations of this region. For all traits evaluated, the G × E interaction was simple, which means that the evaluated landraces can be recommended for the different environments tested. The results also suggest that phenotypic selection can be efficient to enhance the yield of cowpea landraces and, therefore, can be practiced by the farmers themselves. The most advantageous landraces were ranked with good stability (qi <5%). Although the performance standards between the cowpea landraces were similar in the different environments, the best values were obtained on the farm with the best environmental conservation history and with higher precipitation. Therefore, the integration between the yield of cowpea landraces, environmental conservation in agricultural landscapes, and strategic planning that considers possible variations in local precipitation is essential in models of sustainable agricultural development in semi-arid zones of Northeast Brazil.

Keywords:
Vigna unguiculata ; Local varieties; Semiarid; Phenotypic selection; Sustainability

RESUMO

O feijão-de-corda (Vigna unguiculata (L.) Walp.) é uma cultura de grande importância nas regiões semiáridas, devido à sua tolerância a altas temperaturas e déficit hídrico, com rendimentos satisfatórios no cultivo de sequeiro. O objetivo deste trabalho foi avaliar a interação genótipo x ambiente (G × A), a adaptabilidade e a estabilidade de variedades crioulas de feijão-de-corda utilizadas no Cariri paraibano, zona semiárida do Nordeste brasileiro. O experimento foi conduzido em regime de sequeiro em duas localidades desta região. Para todas as características avaliadas, a interação foi simples, o que significa que os genótipos avaliados podem ser recomendados para os diferentes ambientes testados. Os resultados também sugerem que a seleção fenotípica pode ser eficiente para aumentar o rendimento de variedades crioulas de feijão-de-corda e esta pode ser praticada pelos próprios agricultores. As variedades crioulas mais vantajosas foram classificadas com boa estabilidade (i <5%). Embora os padrões de desempenho entre as variedades crioulas de feijão-de-corda tenham sido semelhantes nos diferentes ambientes, os melhores valores foram obtidos na fazenda com melhor histórico de conservação ambiental e com menor déficit hídrico. Portanto, a integração entre a produtividade de variedades crioulas de feijão-de-corda, a conservação ambiental nas paisagens agrícolas e um planejamento estratégico que considere possíveis variações nas precipitações locais é fundamental em modelos de desenvolvimento agrícola sustentável em zonas semiáridas do Nordeste brasileiro.

Palavras-chave:
Vigna unguiculata ; Variedades locais; Semiárido; Seleção fenotípica; Sustentabilidade

INTRODUCTION

Dryland regions correspond to approximately 41.5% of the continent and are classified as arid, semi-arid (SAR'S), or dry sub-humid regions, with more than 38% of the world population living in these areas (HUANG et al., 2016;HUANG, J. Y. H. et al. Accelerated dryland expansion under climate change. Nature Climate Change, 6: 166-171, 2016. BASTIN et al., 2017BASTIN, J. F. et al. The extent of forest in dryland biomes. Science, 356: 635-638, 2017.). With a history of continuous inadequate agricultural use, several areas of these regions have become susceptible to desertification with consequences on climate change, loss of biodiversity, soil degradation, cyclical reduction of agricultural areas, decrease in agricultural production, increase in economic losses, and poverty (SÁ et al., 2010;SÁ, I. B. et al. Processos de desertificação no Semiárido brasileiro. In: SÁ, I.; SILVA, P. C. G. (Eds.). Semiárido Brasileiro: pesquisa desenvolvimento e inovação. Petrolina, PE: Embrapa Semiárido, 2010. v. 1, cap. 4, p. 125-158. DANTAS et al., 2019DANTAS, A. P. J. et al. Evaluation of two cowpea (Vigna unguiculata (L.) Walp.) genotypes under rainfed farming with low rainfall. Revista Brasileira de Meio Ambiente, 7: 58-69, 2019.). Although the history of inappropriate land use for agriculture has been one of the main threats to sustainability in these regions, agriculture also plays an essential role in economic development in dry regions around the world (STEWART, 2016STEWART, B. A. Dryland farming. Reference Module in Food Science, 1: 1-10, 2016.).

The success of SAR'S agriculture relies on the water stored in the soil, efficient use of water, prevention of soil degradation, and use of cultivars tolerant to semi-arid conditions (STEWART, 2016STEWART, B. A. Dryland farming. Reference Module in Food Science, 1: 1-10, 2016.). Therefore, the selection of cultivars that profitably meets the universal objective of environmental resources protection is essential in SAR’S.

Cowpea is one of the main food sources in arid, semiarid, and tropical regions of the world (DIAS; BERTINI; FREIRE FILHO, 2016;DIAS, F. T. C.; BERTINI, C. H. D.; FREIRE FILHO, F. R. Genetic effects and potential parents in cowpea. Crop Breeding and Applied Biotechnology, 16: 315-320, 2016. GERRANO et al., 2020GERRANO, A. S. et al. Genotype and genotype × environment interaction effects on the grain yield performance of cowpea genotypes in dryland farming system in South Africa. Euphytica, 216: 1-11, 2020.). This crop is considered an excellent example in SAR'S research due to its tolerance to abiotic factors, such as high temperatures and water deficit, with a minimum precipitation requirement of 300 mm for satisfactory yield in rainfed cultivation (SILVA et al., 2018;SILVA, J. D. L. D. et al. Selection for the development of black eye cowpea lines. Revista Caatinga, 31: 72-79, 2018. DANTAS et al., 2019DANTAS, A. P. J. et al. Evaluation of two cowpea (Vigna unguiculata (L.) Walp.) genotypes under rainfed farming with low rainfall. Revista Brasileira de Meio Ambiente, 7: 58-69, 2019.).

Brazil is the fourth largest world producer of cowpea, according to the cowpea world production of 2020 (FAOSTAT, 2020FAOSTAT – Food and Agriculture Data. Crops and livestock products. Cowpea, dry. 2020. Disponível em: <https://www.fao.org/faostat/en/#data/QCL>. Acesso em: 1 mai. 2022.
https://www.fao.org/faostat/en/#data/QCL... ), with a yield of 530 kg ha^-1 in 2021/2022 agricultural year, and the northeast region yield is 409 kg ha^-1 (CONAB, 2022CONAB - Companhia Nacional de Abastecimento. Acompanhamento da safra brasileira de grãos, V. 9 – Safra 2021/2022. Disponível em: <https://www.conab.gov.br/info-agro/safras/graos/boletim-da-safra-de-graos>. Acesso em: 18 mar. 2022.
https://www.conab.gov.br/info-agro/safra... ), with most of this area located in SAR’S. Despite its great socioeconomic importance in the country, this crop is cultivated in a rudimentary way and the average yield in the semi-arid region is still low, 289 kg ha^-1 (CONAB, 2022CONAB - Companhia Nacional de Abastecimento. Acompanhamento da safra brasileira de grãos, V. 9 – Safra 2021/2022. Disponível em: <https://www.conab.gov.br/info-agro/safras/graos/boletim-da-safra-de-graos>. Acesso em: 18 mar. 2022.
https://www.conab.gov.br/info-agro/safra... ). Although the Northeast is the region responsible for about 61.4% of the national production, the highest yields (>800 kg ha^-1) are recorded in the Midwest and Southeast regions (CONAB, 2022CONAB - Companhia Nacional de Abastecimento. Acompanhamento da safra brasileira de grãos, V. 9 – Safra 2021/2022. Disponível em: <https://www.conab.gov.br/info-agro/safras/graos/boletim-da-safra-de-graos>. Acesso em: 18 mar. 2022.
https://www.conab.gov.br/info-agro/safra... ). Some factors limit this production, such as the occurrence of biotic and abiotic stresses, low use of technology by farmers, and the cultivation of landraces with low yield potential (RODRIGUES et al., 2018;RODRIGUES, E. V. et al. Diallel analysis of tolerance to drought in cowpea genotypes. Revista Caatinga, 31: 40-47, 2018. OWUSU et al., 2018;OWUSU, E. Y. et al. Inheritance of early maturity in some cowpea (Vigna unguiculata (L.) Walp.) genotypes under rain fed conditions in Northern Ghana. Advances in Agriculture, 4: 1-10, 2018. SOUSA et al., 2019SOUSA, T. D. J. F. D. et al. Simultaneous selection for yield, adaptability, and genotypic stability in immature cowpea using REML/BLUP. Pesquisa Agropecuária Brasileira, 54: 1-9, 2019.). However, landraces can maintain a diversity of genotypes that respond favorably to local environmental variations and can contribute to increased yield, if varieties suitable for the regions’ environment and production system are selected. In the selection process for an appropriate genotype for a given environment, it is necessary to understand that the phenotype is the result of the response of the genotype to the influence of the environment. However, environmental variations can promote different interactions between the environment and the genotype (OWUSU et al., 2020OWUSU, E. Y. et al. Genotype× environment interactions of yield of cowpea (Vigna unguiculata (L.) Walp) inbred lines in the Guinea and Sudan savanna ecologies of Ghana. Journal of Crop Science and Biotechnology, 23: 453-460, 2020.). An interaction can be complex when it generates different responses in the performance of genotypes in different environments, influencing the selection progress and the recommendation of cultivars with wide adaptability (TORRES et al., 2015TORRES, F. E. et al. Interação genótipo x ambiente em genótipos de feijão-caupi semiprostrado via modelos mistos. Bragantia, 74: 255-260, 2015.). A simple interaction is observed when a genotype shows the same pattern of responses, although it is influenced by the environment (CRUZ; REGAZZI; CARNEIRO, 2012;CRUZ, C. D.; REGAZZI, A. J.; CARNEIRO, P. C. S. Modelos biométricos aplicados ao melhoramento genético. 4. ed. Viçosa, MG: UFV, 2012. 514 p. SOUSA et al., 2018SOUSA, M. B. E. et al. Genotype by environment interaction in cowpea lines using GGE biplot method. Revista Caatinga, 31: 64-71, 2018.). This type of interaction does not interfere in breeding programs or in the recommendation of cultivars.

The objective of this work was to evaluate the genotype x environment interaction, adaptability and stability of cowpea landraces on the cultivation under different conditions of land use and precipitation in Cariri, Paraíba, situated in the semi-arid zone of Northeast Brazil.

MATERIALS AND METHODS

Area of the experiment

Planting was carried out in Cariri, Paraíba, situated in the semi-arid zone of Northeast Brazil (Figure 1). The region occupies an area of 11.233 km², composed of 30 municipalities, with an estimated population of 199.728, a demographic density of 17.78 habitants / km², and a GDP per capita/year per municipality of R$ 8,022.8181 (IBGE, 2017IBGE - Instituto Brasileiro de Geografia e Estatística. Malha Digital 2017, 2017. Disponível em: <http://www.ibge.gov.br> Acesso em: 20 Jan. 2021.
http://www.ibge.gov.br... ). The regional climate is classified as "Bsh" Semi-arid hot with summer rains, characterized by high temperatures (annual averages around 26 °C) and annual precipitation of approximately 400 mm.

Figure 1
Location of the area under study in the Northeast Brazil. Black dots represent the locations of the farms where the experiment was conducted in Cariri, PB, Brazil (Adapted, (VELLOSO et al. 2002VELLOSO, A. L.; SAMPAIO, E. V. S. B.; PAREYN, F. G. C. Ecorregioes propostas para o bioma caatinga. Recife: Instituto de Conservação Ambiental The Nature Conservancy do Brasil, 2002. 76 p.)).

The experiment was carried out in two areas of different municipalities to show productive indicators under the influence of different environmental conservation and local precipitation conditions: 1) São João do Cariri (SJC), where the vegetation is characterized by a long period of selective or shallow cutting for the production of firewood and native pasture for goats, a region that is one of the desertification hotspots of the Brazilian Semi-arid Region (PEREZ et al., 2012;PEREZ, A. et al. Núcleos de desertificação no semiárido brasileiro: Ocorrência natural ou antrópica?. Parcerias Estratégicas, 17: 87-106, 2012. TRAVASSOS; SOUZA, 2014TRAVASSOS, I. S.; SOUZA, B. Desmatamento e Desertificação no Cariri Paraibano (In Portuguese, with English abstract.). Revista Brasileira de Geografia Física, 7: 103-116, 2014.); 2) São José dos Cordeiros, precisely at Almas Farm (ALMAS), where there is a private preserved environment, with conservation initiatives practiced for over forty years. Planting was performed in February of 2019 and harvest was carried out in May of the same year under total precipitation of 231 mm in São João do Cariri and 426 mm in São José dos Cordeiros (Real-Time Climate Monitoring Program of the Northeast Region-PROCLIMA and pluviometer).

Plant material

Ten cowpea genotypes were pre-selected based on characteristics such as water stress tolerance, grain yield, market value, and use in the region under study (Table 1). They were collected from communities and open markets in the semi-arid region of the Paraíba and Ceará States.

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Table 1
Passport data of cowpea accessions collected from different sites in Paraíba and Ceará States, Brazil.

The preparation for planting was carried out conventionally, with plowing harrow two weeks before sowing in a soil classified as Luvisol, on both locations. Chemical, physical and mineralogical analyses of the soils were made. Mineral fertilization consisted of the application of 350 kg ha^-1 of ammonium sulfate 30 days after sowing.

Preparation of the experimental area

Sowing was performed manually with three seeds per hole, and after 15 days thinning was performed. Harvest was carried out approximately 65 days after planting. A randomized block experimental design with three replications was used in the two locations. The experimental plot consisted of four rows of four meters, with a typical spacing of 0.4 m between plants and 0.7 m between rows, with ten plants per experimental unit to be analyzed.

Evaluated traits

The varieties were evaluated for growth, flowering, yield, and environmental adaptation. The quantitative traits evaluated were: number of days to flowering and maturity days after sowing taken until more than 50% of the plot showed inflorescence and green pods, respectively; plant height (cm): measured from the plant collar to the apical bud of the highest branch or greatest distance from the plant collar; stem diameter (cm): measured two centimeters above the plant collar; number of leaves: count of all leaves with a minimum length of 3.0 cm; leaf water content (%): determined from the weight of fresh leaves (FW) and their weight after drying (DW) in an oven at 45 °C until they reached a constant weight. With these values, the following formula was applied:

L W C (%) = \frac{F W - D W}{F W} \times 100

Number of pods per plant: determined by counting all pods of an individual plant; number of grains per pod: determined by counting the number of grains in three pods for each individual; pod length (cm): mean of three pods of each plant in the stage that allows manual threshing to obtain green grains; weight of 100 green grains (g): after manually threshing the pods, 100 grains were counted and weighed on a precision scale; green (approximately 60 to 70% moisture) and dry (moisture content around 13%) (kg ha^-1) grain yield: determined from the production of grains per plant, per m² and estimated for ha, with eight replicates per plot collected for each grain type; aerial part biomass (g): eight replicates per plot were collected, cut close to the soil surface, weighed on a precision scale, and then the value per ha was estimated.

Individual and joint analysis of variance

Before the G x E interaction study, it is essential to perform the analysis of variance for each location to assess the existence of genetic variability between the genotypes under study. The relative production of each experiment and the homogeneity of the residual variances should also be investigated (CRUZ; REGAZZI; CARNEIRO, 2012CRUZ, C. D.; REGAZZI, A. J.; CARNEIRO, P. C. S. Modelos biométricos aplicados ao melhoramento genético. 4. ed. Viçosa, MG: UFV, 2012. 514 p.). After conducting the individual analysis of variance for each location and checking the existence of the above-mentioned assumptions, a joint analysis was carried out. The joint analysis aimed to analyze the effects of genotypes, environments, and G x E interaction, considering the two locations. The variation component of the G x E interaction was quantified considering genotypes and environments as fixed effects (CRUZ; REGAZZI; CARNEIRO, 2012CRUZ, C. D.; REGAZZI, A. J.; CARNEIRO, P. C. S. Modelos biométricos aplicados ao melhoramento genético. 4. ed. Viçosa, MG: UFV, 2012. 514 p.).

Estimates of genetic parameters

Based on the means and variances values, estimates of variance components were obtained to assess the potential of populations for breeding purposes and to establish effective selection strategies. The mathematical formula proposed by Cruz, Regazzi and Carneiro (2012)CRUZ, C. D.; REGAZZI, A. J.; CARNEIRO, P. C. S. Modelos biométricos aplicados ao melhoramento genético. 4. ed. Viçosa, MG: UFV, 2012. 514 p. was used to estimate the phenotypic (rf) and genotypic (rg) correlation coefficients between environments.

Phenotypic correlation coefficient (r_f)

r_{f} = \frac{C O V f (x, y)}{\sqrt{σ_{f x}^{2} \cdot σ_{f y}^{2}}}

Genotypic correlation coefficient (r_ɡ)

r_{g} = \frac{C O V g (x, y)}{\sqrt{σ_{g x}^{2} \cdot σ_{g y}^{2}}}

Where: COV f (X, Y) and COV g (X, Y) correspond to the estimates of phenotypic and genotypic covariance between environments, respectively;

$σ_{f x}^{2}$ and $σ_{g x}^{2}$ correspond to the estimates of phenotypic and genotypic variances in environment 1;

$σ_{f y}^{2}$ and $σ_{g y}^{2}$ correspond to the estimates of phenotypic and genotypic variances in environment 2;

The significance of the phenotypic, genotypic, and environment correlation coefficients was assessed by the t-test (p <0.05).

When the significant G × E interaction was observed, the decomposition of the mean square of the interaction into simple parts (provided by the difference in variance between genotypes in the environments) and complex parts (generated by the low correlation between locations, due to the irregular performance of the genotypes) was estimated using the formula proposed by Cruz and Castoldi (1991)CRUZ, C. D.; CASTOLDI, F. L. Decomposição da interação genótipos x ambientes em partes simples e complexa. Ceres, 38: 422-430, 1991.:

C = \sqrt{{(1 - r)}^{3} Q_{1} Q_{2}}

Where r is the correlation between the means of genotypes in the two environments; and Q1 and Q2 are the mean squares between genotypes in environments 1 and 2, respectively.

Another relevant aspect, depending on the G × E interaction, is the gain prediction to be obtained by a given improvement strategy. In this study, the genetic gains were predicted for each environment using, for the selection differential, an intensity of 30% of the individuals with the best performance and the coefficient of genotypic determination of the target trait.

Adaptability and stability analysis

To obtain information on the performance of each genotype under the variations in both locations, adaptability and stability were estimated using the method proposed by Plaisted and Perterson (1959)PLAISTED, R. L.; PETERSON, L. C. A technique for evaluating the ability of selections to yield consistently in different locations or seasons. American Potato Journal, 36: 381-385, 1959.. Subsequently, a ranking of genotypes was carried out based on the genotype-ideotype distance selection index proposed by Wricke and Weber (1986)WRICKE, G.; WEBER, E. W. Quantitative genetics and selection in plant breeding. Berlin: Walter de Gruyter, 1986. 406 p.. All statistical analyses were performed using the computer software Genes (CRUZ, 2013CRUZ, C. D. Genes: a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum, 35: 271-276, 2013.).

RESULTS AND DISCUSSION

It was possible to verify a significant effect of genotypes, environments, and of the G x E interaction (Table 2). The estimates and the significance of the genotypes mean squares showed significant effects (p <0.01) for the following traits: number of days to flowering, plant height, stem diameter, number of leaves, number of days to maturity, pod length, number of grains per pod, weight of 100 grains, green and dry grain yield, and aerial part biomass. The experimental variation coefficients of the analyzed traits provided good data confidence.

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Table 2
Summary of the joint analysis of variance for 13 traits observed in 10 cowpea landraces, evaluated in two regions of Cariri, PB, in Northeast Brazil.

The success in the development of high-yielding varieties is a consequence of the genetic variability level and diversity of the breeding population (DIAS et al., 2015;DIAS, F. T. C. et al. Variabilidade genética de feijão-caupi de porte ereto e ciclo precoce analisada por marcadores RAPD e ISSR. Revista Ciência Agronômica, 46: 563-572, 2015. MEENA et al., 2017MEENA, S. S. et al. Interpretation of genotype x environment interaction and grain yield stability in some advance lines of pigeon pea (Cajanus cajan (L.) Millsp.) grown at different altitudes. Chemical Science Review and Letters, 6: 1113-1119, 2017.). Cowpea landraces exhibit a wide range of phenotypic variability, which has enabled their production under different climatic and soil conditions (GERRANO et al., 2020GERRANO, A. S. et al. Genotype and genotype × environment interaction effects on the grain yield performance of cowpea genotypes in dryland farming system in South Africa. Euphytica, 216: 1-11, 2020.) attributed to inherent genetic properties and/or environmental influence, which can be exploited for improvement through selection and/or hybridization of individuals with desired traits (ALIYU et al., 2019ALIYU, O. M. et al. Evaluation of advanced breeding lines of cowpea (Vigna unguiculata L. Walp) for high seed yield under farmers’ field conditions. Plant Breeding and Biotechnology, 7: 12-23, 2019.).

Considering the source of variation in the environments, a significant difference at 1% probability level by the F test was observed, for most of the traits evaluated, which indicates the existence of variability for the environment’s conditions between the test locations, except for the weight of 1020 grains and leaf water content, for which no significant variation was observed (Table 2). The existence of G x E interaction also demonstrated significant differences for the relative performance of the cowpea landraces for each descriptor in the two environments: number of days to flowering, plant height, number of leaves, number of days to maturity, number of pods per plant, pod length, number of grains per pod, and green and dry grain yield (Table 2).

This interaction indicates that the performance of the genotypes was not consistent in the two locations evaluated, which reflects the different behaviors of the genotypes under the environmental conditions to which they were subjected (GUERRA et al., 2017GUERRA, J. V. S. et al. Agronomic performance of erect and semi-erect cowpea genotypes in the north of Minas Gerais, Brazil. Revista Caatinga, 30: 679-686, 2017.). In Brazil and more seriously in the Northeast region, genetically improved cultivars that showed good performance in other regions are recommended for cultivation without considering the edaphoclimatic peculiarities of the semi-arid region (TEIXEIRA et al., 2010TEIXEIRA, I. R. et al. Desempenho agronômico e qualidade de sementes de cultivares de feijão-caupi na região do cerrado. Revista Ciência Agronômica, 41: 300-307, 2010.). This problem occurs with several crops and is aggravated in situations where cultivation occurs under weather conditions, e.g., in cowpea cultivation. It is known that water deficit in some stages of the plant causes a loss of cell turgor that causes physiological changes, restricting cell elongation and division, causing disturbances in photosynthesis that affect development and yield (FREITAS et al., 2017FREITAS, R. et al. Physiological responses of cowpea under water stress and rewatering in no-tillage and conventional tillage systems. Revista Caatinga, 30: 559-567, 2017.).

Estimate of genetic parameters

The magnitudes of the genotypic variability (ø²G) were higher than the estimates of the interaction quadratic component ( $\emptyset_{G \times E}^{2}$ ). The only traits that did not show similar results were earliness (days to flowering and maturity) and yield (number of pods per plant) (Table 3). The coefficient of genotypic determination for the traits evaluated in study is considered of high magnitude (> 75%), which indicates greater confidence when performing phenotypic selection based on these traits (Table 3). This estimate was below 75% only for the number of pods per plant (49.81%). High values of h² are extremely important for confidence in the selection of genotypes (SOUZA et al., 2018SOUZA, V. B. D. et al. Agronomic performance of cowpea elite lines in the states of Minas Gerais and Mato Grosso, Brazil. Revista Caatinga, 31: 90-98, 2018.), but it should not be considered alone when the objective is to assess the potential of genotypes.

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Table 3
Estimation of the quadratic, genotypic (ø ²G) and genotype x environment (ø ²GE) interaction components; genotypic determination (h²) and genetic (CVg) and environmental (CVe) coefficients; intraclass (r), phenotypic (r_F) and genotypic (r_G) correlation among environments, percentages of the simple (% S) and complex part of the interaction (% C) in cowpea landraces, in two regions of Cariri, PB, in Northeast Brazil.

Intraclass correlation coefficients above 50% were observed for the number of days to flowering, number of days to maturity, plant height, pod length, number of grains per pod, and green grain yield (Table 3), which indicates the stability of the phenotypic superiority of the cowpea landraces, in the different evaluated environments (CRUZ; REGAZZI; CARNEIRO, 2012CRUZ, C. D.; REGAZZI, A. J.; CARNEIRO, P. C. S. Modelos biométricos aplicados ao melhoramento genético. 4. ed. Viçosa, MG: UFV, 2012. 514 p.).

These same traits also showed a ratio between the coefficients of genetic and environmental variation (CVg/ CVe) above one, which confirms that the selection can be made based on the phenotype. In this study, earliness and yield of green grains had the highest h² and CVg/CVe ratio above one, which indicates that the additive gene action was predominant (RODRIGUES et al., 2018RODRIGUES, E. V. et al. Diallel analysis of tolerance to drought in cowpea genotypes. Revista Caatinga, 31: 40-47, 2018.), and with experimental quality, as well as safety and reliability in the selection of superior genotypes (SOUSA et al., 2019SOUSA, T. D. J. F. D. et al. Simultaneous selection for yield, adaptability, and genotypic stability in immature cowpea using REML/BLUP. Pesquisa Agropecuária Brasileira, 54: 1-9, 2019.) for these traits. Therefore, the phenotypic selection is efficient to enhance the yield of cowpea landrace, and this can be practiced by farmers, under rainfed conditions. Aramendiz-Tatis, Espitia and Cardona (2019)ARAMENDIZ-TATIS, H.; ESPITIA, C. M.; CARDONA, A. C. Adaptation and stability of cowpea ('Vigna unguiculata' (L.) Walp) bean cultivars in the tropical dry forest of Colombia. Australian Journal of Crop Science, 13: 1009-1016, 2019. highlight that the successful selection and development of new cultivars is associated with the participation of farmers in breeding programs, helping to choose new genotypes that respond to their conditions and meet their requirements and needs.

The phenotypic and genotypic correlation coefficients among environments was estimated. The number of grains per pod showed high and significant (p<0.05) phenotypic and genotypic correlations among evaluated environments (Table 3), which means that, for this trait, the performance of the superior genotypes did not change according to the evaluated environment. Although the grain yield trait is not suitable for phenotypic selection, as it is considered quantitative, controlled by several genes, with a strong influence of the environment on their expression, the results obtained here indicate genes with an additive effect and h² above 80%. In this case, phenotypic selection can be made, and we can advantageously indicate the use of the most productive genotypes with acceptable stability (ALVES et al., 2019ALVES, G. F. et al. Stability of the hypocotyl length of soybean cultivars using neural networks and traditional methods. Ciência Rural, 49: 1-7, 2019.).

The estimates of the G × E interaction showed a preponderance of the simple type (Table 3). This confirms the influence of the environment on the phenotypic response of cowpea landraces, with no changes in the genotype performance pattern between environments, which does not imply major selection problems (GUERRA et al., 2017GUERRA, J. V. S. et al. Agronomic performance of erect and semi-erect cowpea genotypes in the north of Minas Gerais, Brazil. Revista Caatinga, 30: 679-686, 2017.). In this case, the same genotype can be recommended for different environments (GERRANO et al., 2020GERRANO, A. S. et al. Genotype and genotype × environment interaction effects on the grain yield performance of cowpea genotypes in dryland farming system in South Africa. Euphytica, 216: 1-11, 2020.), with no need for regionalization of breeding programs, and it reduces costs associated with breeding.

The gains of selection (GS) were satisfactory in both environments and ranged from -10.39 to 61.37% (Table 3). However, the largest GS was observed in the SJC environment. The expected gain from selection is related to the difference between the phenotypic means of a trait and expresses the advancement of the next generation relative to the original population, resulting from the selection performed (BALDISSERA et al., 2014BALDISSERA, J. N. C. et al. Fatores genéticos relacionados com a herança em populações de plantas autógamas. Revista de Ciências Agroveterinárias, 13: 181-189, 2014.). In this location, the cowpea landraces had the highest mean variation for the traits analyzed, where some genotypes had very good mean values and others very low, which leads to a greater selection differential and, consequently, a high estimate in the GS.

When the two environments are compared, the genotypes developed better in Almas Farm (Figure 2), except for the number of days to maturity. In the SJC, the Manteiguinha and Roxinho genotypes did not reach dry grain yield due to plant attack by ants. Cowpea landraces showed a better response pattern in the location with a better environmental history of land use and higher precipitation. Producers and plant breeders are interested in selecting genotypes that show an ideotype of interest (SILVA et al., 2018SILVA, J. D. L. D. et al. Selection for the development of black eye cowpea lines. Revista Caatinga, 31: 72-79, 2018.), that is, highly productive, resilient to current climatic challenges (OWUSU et al., 2020OWUSU, E. Y. et al. Genotype× environment interactions of yield of cowpea (Vigna unguiculata (L.) Walp) inbred lines in the Guinea and Sudan savanna ecologies of Ghana. Journal of Crop Science and Biotechnology, 23: 453-460, 2020.), early with good grain quality, resistance to water deficit, in addition to stable yield. According to the traits analyzed, the genotypes Cariri, Canapu, Corujinha, Macaíba, and Roxinho are superiority in terms of earliness, plant architecture, and yield (Figure 2).

Figure 2
Performance of 10 cowpea landraces, for production and earliness traits evaluated in two locations (SJC and ALMAS) in the Cariri, Paraíba State, Northeast Brazil. The cowpea landraces that stood out according to trait performance are cited and positioned in the respective graph.

Adaptability and stability

The most stable cowpea landraces were not the earliest and most productive, according to the lowest values for the estimate θi (%) (Table 4). Among the evaluated cowpea landraces, with satisfactory stability (<5%) and high yield, Cariri and Roxinho, with green grain yields above 800 kg ha^-1, and Cariri, Canapu, and Macaíba, with dry grain yields above 420 kg ha^-1 are indicated. These values are above the average dry grain yield recorded in the state of Paraíba (289 kg ha^-1) and throughout the Northeast region of Brazil (409 kg ha^-1) (CONAB, 2022CONAB - Companhia Nacional de Abastecimento. Acompanhamento da safra brasileira de grãos, V. 9 – Safra 2021/2022. Disponível em: <https://www.conab.gov.br/info-agro/safras/graos/boletim-da-safra-de-graos>. Acesso em: 18 mar. 2022.
https://www.conab.gov.br/info-agro/safra... ).

Thumbnail

Table 4
Estimates of adaptability and stability parameters according to the Plaisted and Peterson (1959)PLAISTED, R. L.; PETERSON, L. C. A technique for evaluating the ability of selections to yield consistently in different locations or seasons. American Potato Journal, 36: 381-385, 1959. and Wricke and Weber (1986)WRICKE, G.; WEBER, E. W. Quantitative genetics and selection in plant breeding. Berlin: Walter de Gruyter, 1986. 406 p. methodologies, obtained in analysis with 10 cowpea landraces, in two locations in the Cariri, PB State, Northeast Brazil.

Among the ten cowpea landraces used in our study, the ranking through the selection index based on the distance between the genotype and the ideotype indicated the top five varieties: Canapu, Cariri, Macaíba, Rabo de Tatu, and Roxinho (Table 4). For selection, it would be more advantageous to use the most productive genotypes for which stability is acceptable and that are in a good position in the Rank (ALVES et al., 2019ALVES, G. F. et al. Stability of the hypocotyl length of soybean cultivars using neural networks and traditional methods. Ciência Rural, 49: 1-7, 2019.). Thus, the landraces Canapu, Cariri, and Macaíba are the most suitable, with the highest green and dry grain yields. Cowpea landraces need to be valued and used to maintain local diversity, strengthen small-farm agriculture in the Brazilian semi-arid region and guarantee food sovereignty in this region (FERNANDES, 2017FERNANDES, G. B. Sementes crioulas, varietais e orgânicas para a agricultura familiar: da exceção legal à política pública. In: SAMBUICHI, R. H. R. et al. (Eds.). A política nacional de agroecologia e produção orgânica no Brasil. Brasilia, DF: Instituto de Pesquisa Aplicada, 2017. v. 1, cap. 11, p. 327-357). One way to increase grain yield in cowpea landraces is through selection (DIAS; BERTINI; FREIRE-FILHO, 2016DIAS, F. T. C.; BERTINI, C. H. D.; FREIRE FILHO, F. R. Genetic effects and potential parents in cowpea. Crop Breeding and Applied Biotechnology, 16: 315-320, 2016.) and adaptation to environmental conditions. Based on our results, it is possible to invest in cowpea landraces research with a focus on yield and water deficit (DANTAS et al., 2019DANTAS, A. P. J. et al. Evaluation of two cowpea (Vigna unguiculata (L.) Walp.) genotypes under rainfed farming with low rainfall. Revista Brasileira de Meio Ambiente, 7: 58-69, 2019.).

CONCLUSIONS

Phenotypic selection can be efficient to enhance the yield of cowpea landraces and this selection can be practiced by the farmers themselves, for the landraces Cariri, Canapu, Macaíba, and Roxinho for use and development in the production of dry or green grains, and for the landraces Canapu, Manteguinha, and Roxinho to produce aerial biomass, regardless of the conservation history or even the precipitation variation.

Although the performance standards between the cowpea landraces were similar in the different environments, the best values were obtained on the farm with the best environmental conservation history and with higher precipitation during the cultivation. Therefore, the integration among yield, environment conservation in agricultural landscapes, and strategic planning that considers possible variations in local precipitation is essential in sustainable agricultural development models in the semi-arid region of Northeast Brazil, mainly to assist in the eradication of current and future desertification problems.

ACKNOWLEDGMENTS

This research study was funded by the Brazilian National Council for Scientific and Technological Development (CNPq) [grant number 441436/2017-0 and 405298/2021-8].

REFERENCES

ALIYU, O. M. et al. Evaluation of advanced breeding lines of cowpea (Vigna unguiculata L. Walp) for high seed yield under farmers’ field conditions. Plant Breeding and Biotechnology, 7: 12-23, 2019.
ALVES, G. F. et al. Stability of the hypocotyl length of soybean cultivars using neural networks and traditional methods. Ciência Rural, 49: 1-7, 2019.
ARAMENDIZ-TATIS, H.; ESPITIA, C. M.; CARDONA, A. C. Adaptation and stability of cowpea ('Vigna unguiculata' (L.) Walp) bean cultivars in the tropical dry forest of Colombia. Australian Journal of Crop Science, 13: 1009-1016, 2019.
BALDISSERA, J. N. C. et al. Fatores genéticos relacionados com a herança em populações de plantas autógamas. Revista de Ciências Agroveterinárias, 13: 181-189, 2014.
BASTIN, J. F. et al. The extent of forest in dryland biomes. Science, 356: 635-638, 2017.
BRASIL - Instrução normativa nº 12, de 28 de março de 2008. Regulamento técnico do feijão Diário Oficial [da] República Federativa do Brasil, 2008.
CONAB - Companhia Nacional de Abastecimento. Acompanhamento da safra brasileira de grãos, V. 9 – Safra 2021/2022 Disponível em: <https://www.conab.gov.br/info-agro/safras/graos/boletim-da-safra-de-graos>. Acesso em: 18 mar. 2022.
» https://www.conab.gov.br/info-agro/safras/graos/boletim-da-safra-de-graos
CRUZ, C. D. Genes: a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum, 35: 271-276, 2013.
CRUZ, C. D.; CASTOLDI, F. L. Decomposição da interação genótipos x ambientes em partes simples e complexa. Ceres, 38: 422-430, 1991.
CRUZ, C. D.; REGAZZI, A. J.; CARNEIRO, P. C. S. Modelos biométricos aplicados ao melhoramento genético 4. ed. Viçosa, MG: UFV, 2012. 514 p.
DANTAS, A. P. J. et al. Evaluation of two cowpea (Vigna unguiculata (L.) Walp.) genotypes under rainfed farming with low rainfall. Revista Brasileira de Meio Ambiente, 7: 58-69, 2019.
DIAS, F. T. C. et al. Variabilidade genética de feijão-caupi de porte ereto e ciclo precoce analisada por marcadores RAPD e ISSR. Revista Ciência Agronômica, 46: 563-572, 2015.
DIAS, F. T. C.; BERTINI, C. H. D.; FREIRE FILHO, F. R. Genetic effects and potential parents in cowpea. Crop Breeding and Applied Biotechnology, 16: 315-320, 2016.
FAOSTAT – Food and Agriculture Data. Crops and livestock products. Cowpea, dry 2020. Disponível em: <https://www.fao.org/faostat/en/#data/QCL>. Acesso em: 1 mai. 2022.
» https://www.fao.org/faostat/en/#data/QCL
FERNANDES, G. B. Sementes crioulas, varietais e orgânicas para a agricultura familiar: da exceção legal à política pública. In: SAMBUICHI, R. H. R. et al. (Eds.). A política nacional de agroecologia e produção orgânica no Brasil Brasilia, DF: Instituto de Pesquisa Aplicada, 2017. v. 1, cap. 11, p. 327-357
FREIRE FILHO, F. R. et al. Melhoramento genético. Feijãocaupi: avanços tecnológicos Brasília, DF: Embrapa Informação Tecnológica, 2005. 84 p.
FREITAS, R. et al. Physiological responses of cowpea under water stress and rewatering in no-tillage and conventional tillage systems. Revista Caatinga, 30: 559-567, 2017.
GERRANO, A. S. et al. Genotype and genotype × environment interaction effects on the grain yield performance of cowpea genotypes in dryland farming system in South Africa. Euphytica, 216: 1-11, 2020.
GUERRA, J. V. S. et al. Agronomic performance of erect and semi-erect cowpea genotypes in the north of Minas Gerais, Brazil. Revista Caatinga, 30: 679-686, 2017.
HUANG, J. Y. H. et al. Accelerated dryland expansion under climate change. Nature Climate Change, 6: 166-171, 2016.
IBGE - Instituto Brasileiro de Geografia e Estatística. Malha Digital 2017, 2017. Disponível em: <http://www.ibge.gov.br> Acesso em: 20 Jan. 2021.
» http://www.ibge.gov.br
MEENA, S. S. et al. Interpretation of genotype x environment interaction and grain yield stability in some advance lines of pigeon pea (Cajanus cajan (L.) Millsp.) grown at different altitudes. Chemical Science Review and Letters, 6: 1113-1119, 2017.
OWUSU, E. Y. et al. Inheritance of early maturity in some cowpea (Vigna unguiculata (L.) Walp.) genotypes under rain fed conditions in Northern Ghana. Advances in Agriculture, 4: 1-10, 2018.
OWUSU, E. Y. et al. Genotype× environment interactions of yield of cowpea (Vigna unguiculata (L.) Walp) inbred lines in the Guinea and Sudan savanna ecologies of Ghana. Journal of Crop Science and Biotechnology, 23: 453-460, 2020.
PEREZ, A. et al. Núcleos de desertificação no semiárido brasileiro: Ocorrência natural ou antrópica?. Parcerias Estratégicas, 17: 87-106, 2012.
PLAISTED, R. L.; PETERSON, L. C. A technique for evaluating the ability of selections to yield consistently in different locations or seasons. American Potato Journal, 36: 381-385, 1959.
RODRIGUES, E. V. et al. Diallel analysis of tolerance to drought in cowpea genotypes. Revista Caatinga, 31: 40-47, 2018.
SÁ, I. B. et al. Processos de desertificação no Semiárido brasileiro. In: SÁ, I.; SILVA, P. C. G. (Eds.). Semiárido Brasileiro: pesquisa desenvolvimento e inovação Petrolina, PE: Embrapa Semiárido, 2010. v. 1, cap. 4, p. 125-158.
SILVA, J. D. L. D. et al. Selection for the development of black eye cowpea lines. Revista Caatinga, 31: 72-79, 2018.
SOUSA, M. B. E. et al. Genotype by environment interaction in cowpea lines using GGE biplot method. Revista Caatinga, 31: 64-71, 2018.
SOUSA, T. D. J. F. D. et al. Simultaneous selection for yield, adaptability, and genotypic stability in immature cowpea using REML/BLUP. Pesquisa Agropecuária Brasileira, 54: 1-9, 2019.
SOUZA, V. B. D. et al. Agronomic performance of cowpea elite lines in the states of Minas Gerais and Mato Grosso, Brazil. Revista Caatinga, 31: 90-98, 2018.
STEWART, B. A. Dryland farming. Reference Module in Food Science, 1: 1-10, 2016.
TEIXEIRA, I. R. et al. Desempenho agronômico e qualidade de sementes de cultivares de feijão-caupi na região do cerrado. Revista Ciência Agronômica, 41: 300-307, 2010.
TORRES, F. E. et al. Interação genótipo x ambiente em genótipos de feijão-caupi semiprostrado via modelos mistos. Bragantia, 74: 255-260, 2015.
TRAVASSOS, I. S.; SOUZA, B. Desmatamento e Desertificação no Cariri Paraibano (In Portuguese, with English abstract.). Revista Brasileira de Geografia Física, 7: 103-116, 2014.
VELLOSO, A. L.; SAMPAIO, E. V. S. B.; PAREYN, F. G. C. Ecorregioes propostas para o bioma caatinga Recife: Instituto de Conservação Ambiental The Nature Conservancy do Brasil, 2002. 76 p.
WRICKE, G.; WEBER, E. W. Quantitative genetics and selection in plant breeding Berlin: Walter de Gruyter, 1986. 406 p.

Publication Dates

Publication in this collection
22 May 2023
Date of issue
Apr-Jun 2023

History

Received
02 Dec 2021
Accepted
05 Jan 2023

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ALIYU, O. M. et al. Evaluation of advanced breeding lines of cowpea (Vigna unguiculata L. Walp) for high seed yield under farmers’ field conditions. Plant Breeding and Biotechnology, 7: 12-23, 2019.

[2] ALVES, G. F. et al. Stability of the hypocotyl length of soybean cultivars using neural networks and traditional methods. Ciência Rural, 49: 1-7, 2019.

[3] ARAMENDIZ-TATIS, H.; ESPITIA, C. M.; CARDONA, A. C. Adaptation and stability of cowpea ('Vigna unguiculata' (L.) Walp) bean cultivars in the tropical dry forest of Colombia. Australian Journal of Crop Science, 13: 1009-1016, 2019.

[4] BALDISSERA, J. N. C. et al. Fatores genéticos relacionados com a herança em populações de plantas autógamas. Revista de Ciências Agroveterinárias, 13: 181-189, 2014.

[5] BASTIN, J. F. et al. The extent of forest in dryland biomes. Science, 356: 635-638, 2017.

[6] BRASIL - Instrução normativa nº 12, de 28 de março de 2008. Regulamento técnico do feijão Diário Oficial [da] República Federativa do Brasil, 2008.

[7] CONAB - Companhia Nacional de Abastecimento. Acompanhamento da safra brasileira de grãos, V. 9 – Safra 2021/2022 Disponível em: <https://www.conab.gov.br/info-agro/safras/graos/boletim-da-safra-de-graos>. Acesso em: 18 mar. 2022.
» https://www.conab.gov.br/info-agro/safras/graos/boletim-da-safra-de-graos

[8] CRUZ, C. D. Genes: a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum, 35: 271-276, 2013.

[9] CRUZ, C. D.; CASTOLDI, F. L. Decomposição da interação genótipos x ambientes em partes simples e complexa. Ceres, 38: 422-430, 1991.

[10] CRUZ, C. D.; REGAZZI, A. J.; CARNEIRO, P. C. S. Modelos biométricos aplicados ao melhoramento genético 4. ed. Viçosa, MG: UFV, 2012. 514 p.

[11] DANTAS, A. P. J. et al. Evaluation of two cowpea (Vigna unguiculata (L.) Walp.) genotypes under rainfed farming with low rainfall. Revista Brasileira de Meio Ambiente, 7: 58-69, 2019.

[12] DIAS, F. T. C. et al. Variabilidade genética de feijão-caupi de porte ereto e ciclo precoce analisada por marcadores RAPD e ISSR. Revista Ciência Agronômica, 46: 563-572, 2015.

[13] DIAS, F. T. C.; BERTINI, C. H. D.; FREIRE FILHO, F. R. Genetic effects and potential parents in cowpea. Crop Breeding and Applied Biotechnology, 16: 315-320, 2016.

[14] FAOSTAT – Food and Agriculture Data. Crops and livestock products. Cowpea, dry 2020. Disponível em: <https://www.fao.org/faostat/en/#data/QCL>. Acesso em: 1 mai. 2022.
» https://www.fao.org/faostat/en/#data/QCL

[15] FERNANDES, G. B. Sementes crioulas, varietais e orgânicas para a agricultura familiar: da exceção legal à política pública. In: SAMBUICHI, R. H. R. et al. (Eds.). A política nacional de agroecologia e produção orgânica no Brasil Brasilia, DF: Instituto de Pesquisa Aplicada, 2017. v. 1, cap. 11, p. 327-357

[16] FREIRE FILHO, F. R. et al. Melhoramento genético. Feijãocaupi: avanços tecnológicos Brasília, DF: Embrapa Informação Tecnológica, 2005. 84 p.

[17] FREITAS, R. et al. Physiological responses of cowpea under water stress and rewatering in no-tillage and conventional tillage systems. Revista Caatinga, 30: 559-567, 2017.

[18] GERRANO, A. S. et al. Genotype and genotype × environment interaction effects on the grain yield performance of cowpea genotypes in dryland farming system in South Africa. Euphytica, 216: 1-11, 2020.

[19] GUERRA, J. V. S. et al. Agronomic performance of erect and semi-erect cowpea genotypes in the north of Minas Gerais, Brazil. Revista Caatinga, 30: 679-686, 2017.

[20] HUANG, J. Y. H. et al. Accelerated dryland expansion under climate change. Nature Climate Change, 6: 166-171, 2016.

[21] IBGE - Instituto Brasileiro de Geografia e Estatística. Malha Digital 2017, 2017. Disponível em: <http://www.ibge.gov.br> Acesso em: 20 Jan. 2021.
» http://www.ibge.gov.br

[22] MEENA, S. S. et al. Interpretation of genotype x environment interaction and grain yield stability in some advance lines of pigeon pea (Cajanus cajan (L.) Millsp.) grown at different altitudes. Chemical Science Review and Letters, 6: 1113-1119, 2017.

[23] OWUSU, E. Y. et al. Inheritance of early maturity in some cowpea (Vigna unguiculata (L.) Walp.) genotypes under rain fed conditions in Northern Ghana. Advances in Agriculture, 4: 1-10, 2018.

[24] OWUSU, E. Y. et al. Genotype× environment interactions of yield of cowpea (Vigna unguiculata (L.) Walp) inbred lines in the Guinea and Sudan savanna ecologies of Ghana. Journal of Crop Science and Biotechnology, 23: 453-460, 2020.

[25] PEREZ, A. et al. Núcleos de desertificação no semiárido brasileiro: Ocorrência natural ou antrópica?. Parcerias Estratégicas, 17: 87-106, 2012.

[26] PLAISTED, R. L.; PETERSON, L. C. A technique for evaluating the ability of selections to yield consistently in different locations or seasons. American Potato Journal, 36: 381-385, 1959.

[27] RODRIGUES, E. V. et al. Diallel analysis of tolerance to drought in cowpea genotypes. Revista Caatinga, 31: 40-47, 2018.

[28] SÁ, I. B. et al. Processos de desertificação no Semiárido brasileiro. In: SÁ, I.; SILVA, P. C. G. (Eds.). Semiárido Brasileiro: pesquisa desenvolvimento e inovação Petrolina, PE: Embrapa Semiárido, 2010. v. 1, cap. 4, p. 125-158.

[29] SILVA, J. D. L. D. et al. Selection for the development of black eye cowpea lines. Revista Caatinga, 31: 72-79, 2018.

[30] SOUSA, M. B. E. et al. Genotype by environment interaction in cowpea lines using GGE biplot method. Revista Caatinga, 31: 64-71, 2018.

[31] SOUSA, T. D. J. F. D. et al. Simultaneous selection for yield, adaptability, and genotypic stability in immature cowpea using REML/BLUP. Pesquisa Agropecuária Brasileira, 54: 1-9, 2019.

[32] SOUZA, V. B. D. et al. Agronomic performance of cowpea elite lines in the states of Minas Gerais and Mato Grosso, Brazil. Revista Caatinga, 31: 90-98, 2018.

[33] STEWART, B. A. Dryland farming. Reference Module in Food Science, 1: 1-10, 2016.

[34] TEIXEIRA, I. R. et al. Desempenho agronômico e qualidade de sementes de cultivares de feijão-caupi na região do cerrado. Revista Ciência Agronômica, 41: 300-307, 2010.

[35] TORRES, F. E. et al. Interação genótipo x ambiente em genótipos de feijão-caupi semiprostrado via modelos mistos. Bragantia, 74: 255-260, 2015.

[36] TRAVASSOS, I. S.; SOUZA, B. Desmatamento e Desertificação no Cariri Paraibano (In Portuguese, with English abstract.). Revista Brasileira de Geografia Física, 7: 103-116, 2014.

[37] VELLOSO, A. L.; SAMPAIO, E. V. S. B.; PAREYN, F. G. C. Ecorregioes propostas para o bioma caatinga Recife: Instituto de Conservação Ambiental The Nature Conservancy do Brasil, 2002. 76 p.

[38] WRICKE, G.; WEBER, E. W. Quantitative genetics and selection in plant breeding Berlin: Walter de Gruyter, 1986. 406 p.

Landrace	City	State	Geographic coordinates	Class¹	Subclass²	Grain shape
Canapu	Aurora	CE	6° 56' 4''S 38° 57' 51''W	Colors	Canapu	Round
Cariri	Remígio	PB	6° 53' 30''S 35° 49' 51''W	White	Fradinho	Oval
Corujinha	Prata	PB	7° 42' 4'' S 37° 6' 33''W	Colors	Corujinha	Round
Macaíba	Alagoa Grande	PB	7° 4' 56''S 35° 35' 57''W	White	Fradinho	Oval
Manteiguinha	Pocinhos	PB	7° 4' 26''S 36° 3' 40''W	White	Manteiga	Oval
Quebra Cadeira	Areia	PB	6° 57' 42''S 35° 41' 43''W	White	Fradinho	Reniform
Pata De Vaca	Areia	PB	6° 57' 42''S 35° 41' 43''W	White	Olho Marrom	Reniform
Rabo De Tatu	Pocinhos	PB	7° 4' 26''S 36° 3' 40''W	Colors	Mulato Liso	Rhomboid
Roxinho	Prata	PB	7° 42' 4'' S 37° 6' 33''W	Colors	Mulato Liso	Oval
Sempre Verde	Alagoa Grande	PB	7° 4' 56''S 35° 35' 57''W	Colors	Sempre-verde	Rhomboid

Mean Squares
SV	DFr	DF	PH	SD	NL	LWC	DM	NPP
Block	2	9.86	0.76	0.08	277.48	136.81	0.81	2.10
Genotype	9	59.97**	365.52**	0.08**	537.77**	207.55^ns	124.65**	11.19 ^ns
Environment	1	1075.23**	5192.19**	0.53**	8450.25**	218.30 ^ns	160.06**	488.26**
G × E	9	36.22**	159.14**	0.02^ns	273.98*	188.41 ^ns	111.88**	12.83*
CV (%)		4.63	18.50	16.33	24.82	19.22	2.80	22.57
Error		0.78	1.82	0.02	2.42	0.78	0.82	0.51
Mean		50.06	38.35	0.89	43.75	83.58	65.46	10.50
	DFr	PL	NGP	W100G	GGY		APB	DGY
Block	2	1.87	2.06	36.62	64.371.53		5051.15	38.648.40
Genotype	9	11.08 **	33.16**	236.95**	247555.75**		24942.07**	65526.51**
Environment	1	126.81**	201.41**	51.18 ^ns	2982812.39**		514500.41**	3589108.77**
G × E	9	4.90**	5.32*	67.88 ^ns	75033.49*		6513.22 ^ns	62.47.76**
CV(%)		7.02	14.05	22.70	33.27		34.94	28.91
Error		0.30	0.42	1.16	45.17		16.48	38.70
Mean		16.81	10.57	31.16	536.47		182.26	388.83

Traits	ø ²_G	ø ²_GE	r	h ²	GS(%)¹	GS(%)²	CVg/CVe	r_F	r_G	%S	%C
DF	9.09	10.27	62.77	91.00	-10.39	-3.7	1.29	0.31	0.40	57.45	42.54
PH	52.52	36.25	51.03	86.21	22.25	21	1.02	0.39	0.48	77.74	22.25
NL	69.96	51.99	37.22	78.06	39.57	10.04	0.77	0.32	0.47	82.02	17.97
DM	20.21	36.16	85.68	97.29	-8.09	-10.47	2.44	0.05	0.05	95.93	4.06
NPP	0.92	2.40	14.19	49.81	15.39	8.71	0.40	-0.07	-0.13	93.37	6.62
PL	1.61	1.17	53.66	87.42	7.71	6.95	1.07	0.38	0.46	78.02	21.97
NGP	5.15	1.03	70.01	93.33	24.4	13.72	1.52	0.72*	0.80*	52.51	47.48
GGY	35948.79	14390.16	53.01	87.12	56.77	26.27	1.06	0.58	0.72*	51.76	48.23
DGY	8813.75	16.734	41.07	80.70	61.37	23.4	0.83	0.02	0.03	79.06	20.93

Genotypes	DF	PH	NL	DM	NPP	PL	NGP	PGY	DGY	Rank
	θi(%)	θi(%)	θi(%)	θi(%)	θi(%)	θi(%)	θi(%)	θi(%)	θi(%)	GI
Canapu	4.32	3.36	6.12	7.86	20.41	7.30	11.12	5.56	5.94	2°
Cariri	26.66	11.16	1.71	14.82	18.84	3.75	6.63	4.39	5.16	3°
Corujinha	22.00	16.07	1.55	17.29	6.94	3.46	1.50	9.25	3.85	6°
Macaíba	4.32	6.79	10.83	6.46	36.66	4.87	3.66	1.91	38.19	1°
Manteguinha	8.89	2.69	19.82	11.43	1.60	44.54	21.64	1.39	8.18	9°
Quebra Cadeira	4.70	2.70	4.78	5.28	1.81	9.25	2.38	8.69	13.85	7°
Pata De Vaca	6.34	5.67	4.30	19.04	2.09	3.44	4.95	4.04	7.49	10°
Rabo De Tatu	5.85	3.75	1.36	4.84	2.45	10.78	36.40	17.34	3.78	4°
Roxinho	5.43	43.31	38.38	7.99	3.78	4.36	9.97	4.86	9.38	5°
Sempre Verde	11.43	4.45	11.10	4.93	5.37	8.22	1.70	42.52	4.13	8°

Brasil

Brasil

Genotype x environment interaction and stability in landraces of cowpea under dryland conditions

Interação genótipo x ambiente e estabilidade em variedades crioulas de feijão de corda em terras secas

ABSTRACT

RESUMO

INTRODUCTION

MATERIALS AND METHODS

Area of the experiment

Plant material

Preparation of the experimental area

Evaluated traits

Individual and joint analysis of variance

Estimates of genetic parameters

Adaptability and stability analysis

RESULTS AND DISCUSSION

Estimate of genetic parameters

Adaptability and stability

CONCLUSIONS

ACKNOWLEDGMENTS

REFERENCES

Publication Dates

History