Adaptability and stability of mungbean genotypes in the Mid-North of Mato Grosso, Brazil

Noleto, Mariano Pereira; Menezes Júnior, José Ângelo Nogueira de; Olibone, Dácio; Gobbi, Simone Daneluz; Pivetta, Laerte Gustavo; Silva, Kaesel Jackson Damasceno e

doi:10.1590/1413-7054202347012222

ABSTRACT

Evaluation of genotype x environment interactions is essential in plant breeding aimed at adapting crops to new settings. Considering the need for research on the adaptation of mungbean to grain-production regions of Brazil, this study evaluated the agronomic performance, adaptability, and stability of mungbean production in the mid-north of Mato Grosso using different genotypes. Two experiments (with and without fertilizer application) were carried out in Sorriso and Sinop in 2019 and 2020, totaling eight environments. The treatments were 10 mungbean lines and the control cultivar BRSMG Camaleão. In general, significant differences among the treatments were observed in the yield, mass of 100 grains, and value for cultivation. The genotype x environment interactions were significant for yield. On average, the yield was in the range of 734-1305 kg ha^-1, the mass of 100 grains was 4.63-6.56 g, and the value for cultivation was 2.08-3.56. Genotypes BRA-08654-1, BRA-000027, BRA-084654-2, and BG3 combined high average yield and mass of 100 grains. These genotypes also showed good adaptability for cultivation in the mid-north of Mato Grosso. The yellow seed-coated genotype BRA-084689 also showed good agronomic performance and adaptability. Genotypes BRA-08654-1, BRA-000027, BRA-084654-2, BRA-084689, and BG3 are promising for further experiments evaluating the value for cultivation and use, the final breeding stage consisting of tests at a national level.

Index terms:
Vigna radiata L.; pulses; genotype x environment interactions.

RESUMO

A avaliação da interação genótipos x ambientes é essencial no melhoramento de plantas visando à adaptação de culturas a novos ambientes de cultivo. Considerando a necessidade de pesquisas para avaliar a adaptação da cultura do feijão-mungo em regiões produtoras de grãos do Brasil, este trabalho foi realizado com o objetivo de avaliar o desempenho agronômico e a adaptabilidade e estabilidade de produção de genótipos de feijão-mungo na região médio-norte de Mato Grosso. Os experimentos foram conduzidos em Sorriso e Sinop em segunda safra nos anos de 2019 e 2020. Dois experimentos foram conduzidos em cada local, sendo um com aplicação de fertilizante e outro sem, totalizando oito ambientes. Foi utilizado o delineamento de blocos casualizados completos, com três repetições e 11 genótipos, incluindo 10 linhagens e a cultivar BRSMG Camaleão. Avaliou-se a produtividade de grãos, a massa de 100 grãos e o valor de cultivo. Em geral, observou-se diferença significativa entre os tratamentos. A interação genótipos x ambientes foi significativa para produtividade de grãos. Em média, a produtividade variou entre 734-1305 kg ha^-1, a massa de 100 grãos entre 4,63-6,56 g e o valor de cultivo entre 2,08-3,56. As linhagens BRA-08654-1, BRA-000027, BRA-084654-2 e BG3 associaram alta média de produtividade e alta massa de 100 grãos, além de apresentarem boa adaptabilidade para cultivo na região médio-norte de Mato Grosso. A linhagem de grãos amarelos, BRA-084689, também apresentou bom desempenho agronômico e boa adaptabilidade. As linhagens BRA-08654-1, BRA-000027, BRA-084654-2, BRA-084689 e BG3 são recomendadas para avaliação nos experimentos de valor de cultivo e uso, etapa final do melhoramento, com avaliação nos ensaios da rede nacional.

Termos para indexação:
Vigna radiata L.; pulses; interação genótipos x ambientes.

INTRODUCTION

Mungbean (Vigna radiata (L.) R. Wilczek) sprouts are occasionally consumed in Brazil, where a relatively small amount of seeds is needed for sprout production (Vieira; Oliveira; Vieira, 2003VIEIRA, R. F.; OLIVEIRA, V. R.; VIEIRA, C. Cultivo do feijão-mungo-verde no verão em Viçosa e em Prudente de Morais. Horticultura Brasileira, 21(1):37-43, 2003.). However, the cultivation of mungbean has intensified in Brazil, particularly in the state of Mato Grosso, to supply the international market (Menezes Júnior; Silva; Rocha, 2019MENEZES JÚNIOR, J. A. N.; SILVA, K. J. D.; ROCHA, M. M. Feijão-mungo como perspectiva para a safrinha em Mato Grosso. In: EMPRESA BRASILEIRA DE PESQUISA AGROPECUÁRIA - EMBRAPA. Embrapa Agrossilvipastoril: Primeiras contribuições para o desenvolvimento de uma agropecuária Sustentável. Brasil, Brasília: Embrapa, p.635-640, 2019.).

Mungbeans are widely used worldwide, especially in Asian cuisine (Nair et al., 2019NAIR, R. M. et al. Biotic and abiotic constraints in mungbean production-progress in genetic improvement. Frontieres in Plant Science, 10:1340, 2019.), and belong to a subgroup of leguminous plants known as pulses whose dry seeds are used for human nutrition (Kumar et al., 2021KUMAR, S. et al. Next generation breeding in pulses: Present status and future directions. Crop Breeding and Applied Biotechnology, 21(S):e394221S13, 2021.). Pulses are important sources of protein and benefit the soil through nitrogen fixation (Cheng et al., 2019CHENG, A. et al. In search of alternative proteins: Unlocking the potential of underutilized tropical legumes. Food Security, 11(6):1205-1215, 2019.; Kumar et al., 2021KUMAR, S. et al. Next generation breeding in pulses: Present status and future directions. Crop Breeding and Applied Biotechnology, 21(S):e394221S13, 2021.).

The rapid global population growth, combined with changing patterns of food consumption and the effects of climate change, has posed a challenge to sustainably achieving worldwide food security (Kumar et al., 2021KUMAR, S. et al. Next generation breeding in pulses: Present status and future directions. Crop Breeding and Applied Biotechnology, 21(S):e394221S13, 2021.). In this scenario, pulses are considered key crops for achieving the UN Sustainable Development Goals concerning food security, improving protein consumption, and promoting sustainable agriculture by 2030 (Cheng et al., 2019CHENG, A. et al. In search of alternative proteins: Unlocking the potential of underutilized tropical legumes. Food Security, 11(6):1205-1215, 2019.; Kumar et al., 2021KUMAR, S. et al. Next generation breeding in pulses: Present status and future directions. Crop Breeding and Applied Biotechnology, 21(S):e394221S13, 2021.). Therefore, research attention and investment in pulse crops have grown considerably in recent years (Cheng et al., 2019CHENG, A. et al. In search of alternative proteins: Unlocking the potential of underutilized tropical legumes. Food Security, 11(6):1205-1215, 2019.; Menezes Júnior; Silva; Rocha, 2019MENEZES JÚNIOR, J. A. N.; SILVA, K. J. D.; ROCHA, M. M. Feijão-mungo como perspectiva para a safrinha em Mato Grosso. In: EMPRESA BRASILEIRA DE PESQUISA AGROPECUÁRIA - EMBRAPA. Embrapa Agrossilvipastoril: Primeiras contribuições para o desenvolvimento de uma agropecuária Sustentável. Brasil, Brasília: Embrapa, p.635-640, 2019.; Nair et al., 2019NAIR, R. M. et al. Biotic and abiotic constraints in mungbean production-progress in genetic improvement. Frontieres in Plant Science, 10:1340, 2019.; Sequeros et al., 2020SEQUEROS, T. et al. Impact and returns on investment of mungbean research and development in myanmar. Agriculture & Food Security, 9:5, 2020.).

In Sub-Saharan Africa and South America, the cultivation of mungbean as a short-cycle crop with efficient nitrogen-fixing capacity has increased over the past 20 years. However, in these regions, biotic and abiotic factors along with other production restrictions represent major challenges for the genetic improvement of this species (Nair et al., 2019NAIR, R. M. et al. Biotic and abiotic constraints in mungbean production-progress in genetic improvement. Frontieres in Plant Science, 10:1340, 2019.). In Mato Grosso, mungbean is cultivated extensively without appropriate management practices. Thus, the establishment and adaptation of this crop remain to be improved for this region (Menezes Júnior; Silva; Rocha, 2019MENEZES JÚNIOR, J. A. N.; SILVA, K. J. D.; ROCHA, M. M. Feijão-mungo como perspectiva para a safrinha em Mato Grosso. In: EMPRESA BRASILEIRA DE PESQUISA AGROPECUÁRIA - EMBRAPA. Embrapa Agrossilvipastoril: Primeiras contribuições para o desenvolvimento de uma agropecuária Sustentável. Brasil, Brasília: Embrapa, p.635-640, 2019.).

One of the major problems faced by mungbean farmers in Mato Grosso is the limited number of cultivars available. Registered cultivars are recommended for other regions of the country, such as the state of Minas Gerais (Vieira et al., 2002VIEIRA, R. F et al. Ouro Verde MG2: Nova cultivar de mungo verde para-Minas Gerais. Horticultura Brasileira, 20(1):119-120, 2002.; Vieira et al., 2008VIEIRA, R. F et al. MGS esmeralda: New large seed mungbean cultivar. Pesquisa Agropecuária Brasileira, 43(6):781-782, 2008.; Vieira et al., 2022), VIEIRA, R. F et al. BRSMG camaleão: New mungbean cultivar with large, shiny, green seeds. Crop Breeding and Applied Biotechnology , 22(2):e32732227, 2022.but they are not commonly used in Mato Grosso. This, allied to the lack of information on management practices, led to farmers having uneven grains and lower harvest yield than desired.

Evaluation of the genotype × environment interactions is essential for plant improvement and breeding, helping to develop cultivars more adaptable to diverse environments. In the case of mungbean, the evaluation of the agronomic performance, adaptability, and stability of production has advanced knowledge and adaptation of the culture in different regions (Sayão; Brioso; Duque, 1991SAYÃO, F. D. A; BRIOSO, P. S. T.; DUQUE, F. F. Comportamento de linhagens de mungo verde em condições de campo em Itaguí, RJ. Pesquisa Agropecuária Brasileira , 26(5):669-664, 1991.; Lin; Alves, 2002LIN, S. S.; ALVES, A. C. Comportamento de linhagens de feijão-mungo (Vigna radiata L.) em Santa Catarina. Ciência Rural, 32(4):553-558, 2002. ; Thangavel; Anandan; Eswaran, 2011THANGAVEL, P.; ANANDAN, A.; ESWARAN, R. AMMI analysis to comprehend genotype-by-environment (G×E) interactions in rainfed grown mungbean (Vigna radiata L.). Australian Journal of Crop Science, 5(13):1767-1775, 2011.; Vieira et al., 2011VIEIRA, R. F. et al. Desempenho de genótipos de feijão-mungo-verde semeados no inverno na Zona da Mata de Minas Gerais. Revista Ceres, 58(3):402-405, 2011.; Asfaw et al., 2012ASFAW, A. et al. Analysis of multi-environment grain yield trials in mung bean Vigna radiata (L.) Wilczek based on GGE biplot in Southern Ethiopia. Journal of Agricultural Science and Technology, 14(2):389-398. 2012.; Win et al., 2018WIN, K. S. et al. Genotype by environment interaction and stability analysis of seed yield, agronomic characters in mungbean (Vigna radiata L. Wilczek) genotypes. International Journal Advanced Research, 6(3):926-934, 2018.; Kumar et al., 2020KUMAR, S. et al. Study on genotype x environment interactions and AMMI analysis for agronomic traits in mungbean (Vigna radiata L. Wilczek.) under rainfed conditions. Indian Journal of Genetics and Plant Breeding, 80(3):354-358. 2020.; Samyuktha et al., 2020SAMYUKTHA, S. M. et al. Delineation of genotype × environment interaction for identification of stable genotypes to grain yield in mungbean. Frontiers in Agronomy, 2:577911, 2020.). The objective of this study was to evaluate these same parameters in mungbean genotypes in the mid-north of Mato Grosso, Brazil.

MATERIAL AND METHODS

The experiments involved eight environments and 10 mungbean genotypes (lineages) developed in Northeastern Brazil by the Plant Breeding Program of Embrapa Meio-Norte (Teresina, PI, Brazil). In addition, the commercial cultivar BRSMG Camaleão (Vieira et al., 2022VIEIRA, R. F et al. BRSMG camaleão: New mungbean cultivar with large, shiny, green seeds. Crop Breeding and Applied Biotechnology , 22(2):e32732227, 2022.) was used as a control (Table 1). The seed teguments of the evaluated genotypes were green except for the yellow seed-coated G6.

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Table 1:
Mungbean genotypes and experimental environments.

Evaluations were performed in 2019 and 2020 in areas around the cities of Sinop and Sorriso, state of Mato Grosso, Brazil. In Sinop, the experiments were carried out at the experimental fields of the Regional Center for Research and Technology Transfer/ Mato Grosso Research, Assistance, and Rural Extension Company (EMPAER, Brazilian acronym) located at 11º51’02.97’’S; 55º31’03.33’’W (altitude 366 m) in a Cerrado-Amazon Forest transition zone. In Sorriso, the experiments were performed at the experimental farm of the Federal Institute of Education, Science, and Technology of Mato Grosso (IFMT, Brazilian acronym) located at 12º32’40.17’’S; 55º43’24.29’’W (altitude 365 m) in a biome that is predominantly Cerrado.

At each year and location, the experiments were conducted with and without the application of fertilizers (Table 1). The fertilizer dose was based on the physicochemical characteristics of the top soil layer (0-0.20 m) and information from the literature (Duque; Pessanha, 1990DUQUE, F. F.; PESSANHA, G. G. Comportamento de dez cultivares de mungo verde nos períodos das águas e da seca em condições de campo. Pesquisa Agropecuária Brasileira, 25(7):963-969, 1990.; Vieira; Oliveira; Vieira, 2003VIEIRA, R. F.; OLIVEIRA, V. R.; VIEIRA, C. Cultivo do feijão-mungo-verde no verão em Viçosa e em Prudente de Morais. Horticultura Brasileira, 21(1):37-43, 2003.). The availability of P in the soil at the experimental sites in the 2019 and 2020 seasons (15.2 and 11.8 mg dm^-3, respectively, at Sinop and 1.4 and 2.5 mg dm^-3 at Sorriso) were also important for defining the fertilizer dose employed. Other soil characteristics were: pH (CaCl₂) 5.2; organic matter = 41 g dm^-3; K = 82 mg dm^-3; V = 27%; clay = 340 g kg^-1; silt = 160 g kg^-1and sand = 500 g kg^-1 in Sinop 2019; pH (CaCl₂) 4.52; organic matter = 19.56 g dm^-3; K = 82 mg dm^-3; V = 39.68%; clay = 502.5 g kg^-1; silt = 100 g kg^-1and sand = 397,5 g kg^-1 in Sinop 2020; pH (CaCl₂) 4.8; organic matter = 2.83 dag kg^-1; K = 40.8 mg dm^-3; V = 35.40%; clay = 428 g kg^-1; silt = 104 g kg^-1and sand = 468 g kg^-1 in Sorriso 2019; pH (CaCl₂) 4.7; organic matter = 1.6 dag kg^-1; K = 55.4 mg dm^-3; V = 37.7%; clay = 270 g kg^-1; silt = 55 g kg^-1and sand = 675 g kg^-1 in Sorriso 2020.

In Sinop, the soil was harrowed and the sowing furrows were opened mechanically. In Sorriso, the soil was prepared using two different approaches. In 2019, harrowing was followed by mechanical rotary hoeing and the furrows opened with the aid of hand hoes. In 2020, the experiments were conducted under a no-tillage system, after the soybean harvest. The spacing between furrows was first marked with a seeder and the furrows were opened with the aid of hand hoes.

At the sowing of the fertilized experiments, 200 kg ha^-1 of a formulated fertilizer 00-20-20 (N-P₂O₅-K₂O) was used in Sinop and 400 kg ha^-1 in Sorriso. Urea (45 kg ha^-1) was surface applied on soil 35 days after seedling emergence. The experiments without fertilization were conducted by simply distributing the seeds in the sowing furrows. In Sinop, sowing was carried out on 8^th March 2019 and 13^th March 2020, and in Sorriso on 9^th March 2019 and 6^th March 2020. Average precipitation during the crop cycle in Sinop was 347 and 438 mm in 2019 and 2020, respectively, and 234 and 318 mm in Sorriso. Insecticide was applied whenever the insect infestation caused approximately 5% damage to mungbean plants. Weeds were eliminated using hand hoes. Fungicides were not applied during the development of mungbean plants.

The experiments were carried out in a complete randomized block design with three repetitions. Each plot had two 3 m-long rows, spaced 0.5 m apart, with a rate of 18 seeds/m along the rows. Before harvesting, values for cultivation (VC) of each genotype were determined visually by taking into account the general conditions of the plants (i.e., pod and seed characteristics, pod loading, phytosanitary aspects, plant size, and lodging) based on Silva et al. (2018SILVA, M. B. O. et al. Desempenho agronómico de genótipos de feijão-caupi. Revista de Ciências Agrárias, 41(1):1059-1066, 2018.). VC scores were attributed as follows: 1- no desired traits, 2 - few desired traits, 3 - many desired traits, 4 - most of the desired traits, and 5 - all desired traits. Yield (g m^-2) was determined by weighing the total mass of grains produced in each of the plots and the values were subsequently extrapolated to kg ha^-1. The mass of 100 grains (g) was also determined for each plot.

The assumptions of normality of errors and homogeneity of variance were tested (Ramalho; Ferreira; Oliveira, 2012RAMALHO, M. A. P.; FERREIRA, D. F.; OLIVEIRA, A. C. Experimentação em genética e melhoramento de plantas. 3. ed. Lavras: UFLA, 2012, 305p.) before subjecting the data to analysis of variance (ANOVA) using GENES software (Cruz, 2013CRUZ, C. D. GENES: A software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum, 35(3):271-276, 2013). The mean values of the agronomic characteristics (yield, mass of 100 grains, and VC scores) of genotypes were compared using Tukey test at 5% probability.

Initially, individual ANOVA was performed for each environments and year of study, following the statistical model presented in Equation 1.

Y_{i j} = m + t_{i} + r_{j} + e_{i j}

(1)

in which Y _ij is the value obtained for the plot planted with genotype i within block j, m is the average value of the experiment, t _i is the effect of treatment related to genotype i (i = 1, 2, 3, …, 11), r _j is the effect of block j (j = 1, 2, and 3), and e _ij is the experimental error associated with the observation Y _ij , assuming that the errors were independent and normally distributed with a mean of zero and variance .

Subsequently, combined ANOVA was performed for each variable considering the eight environments and using a fixed effect model for genotypes and a random effect model for environments (Equation 2).

Y_{i j k} = m + t_{i} + b_{(j) k} + a_{k} + {(t a)}_{i k} + {\bar{e}}_{j k i}

(2)

in which, Y _ijk is the value obtained for the plot planted with genotype i within block j and environment k, m is the average value of the experiment, t _i is the effect of treatment related to genotype i (i = 1, 2, 3, …, 11), b _(j)k is the effect of the block j (j = 1, 2, and 3) within environment k; a _k is the effect of the environment k (k = 1, 2, ...,8), (ta) _ik is the effect of the interaction between genotype i and environment k, and ē _jki is the experimental error associated with observation Y _ijk assuming that the errors were independent and normally distributed with a mean of zero and variance $σ_{e}^{2}$ .

When the ratios between the largest and smallest mean squared residual values obtained in the individual analyses were greater than seven (Pimentel-Gomes, 2009PIMENTEL-GOMES, F. Curso de estatística experimental. 15 ed. Piracicaba: ESALQ, 2009. 451p.), the method described by Cochran (1954COCHRAN, W. G. The combination of estimates from different experiments. Biometrics, 10(1):101-129, 1954.) was used to adjust the degrees of freedom of residues and to enable the inclusion of all eight environments in the combined analysis. Thus, the possible effects of environmental heterogeneity on the significance were minimized by adjusting the degrees of freedom of residues and interactions.

The adaptability and stability of production were assessed using the method described by Lin and Binns (1988LIN, C. S.; BINNS, M. R. A. A superiority measure of cultivar performance for cultivar x location data. Canadian Journal of Plant Science, 68(1):193-198, 1988.) with modifications (Cruz; Carneiro, 2006CRUZ, C. D.; CARNEIRO, P. C. S. Modelos biométricos aplicados ao melhoramento genético. Vol. 2, 2 ed. Viçosa: UFV, 2006. 585p.). The P _i index was submitted to decomposition analysis to identify the genotypes that better suited favorable (P _if ) and unfavorable (P _iu ) environments. The environmental indices, the genetic and interaction deviations, and the contribution of genotype × environment interactions were estimated as proposed by Cruz and Carneiro (2006)CRUZ, C. D.; CARNEIRO, P. C. S. Modelos biométricos aplicados ao melhoramento genético. Vol. 2, 2 ed. Viçosa: UFV, 2006. 585p..

RESULTS AND DISCUSSION

Individual ANOVA tests showed differences (P < 0.05) in the genotypic source of variation concerning yield in the Sinop2020WF environment and all four environments in Sorriso (Table 2). The mean yield of genotypes in Sinop was generally lower than in Sorriso, indicating that the Sinop environments were less favorable to mungbeans. In addition, the lower yield in Sinop may be attributed to the conventional soil tillage employed and to the high rainfall events during the first three days after sowing in both years. These factors hampered germination and seedling emergence, thereby reducing stand and yield.

The mass of 100 grains differed among genotypes (P < 0.01) in all eight environments (Table 2), ranging from 4.98 g (Sorriso2020NF) to 6.38 g (Sinop2019WF). On average, grains of the evaluated genotypes were within the standard of commercial cultivars (Vieira et al., 2002VIEIRA, R. F et al. Ouro Verde MG2: Nova cultivar de mungo verde para-Minas Gerais. Horticultura Brasileira, 20(1):119-120, 2002.; Vieira et al., 2008VIEIRA, R. F et al. MGS esmeralda: New large seed mungbean cultivar. Pesquisa Agropecuária Brasileira, 43(6):781-782, 2008.; Khattak et al., 2021KHATTAK, G. S. S. et al. High yielding mungbean [Vigna radiata (L.) Wilczek] variety “NIFA Mung-2017”. Pure and Applied Biology, 10(1):105-114, 2021.; Kim et al., 2020KIM, D. K. et al. A new mungbean cultivar, ‘Samhwang’, with yellow seed coat and lobed leaflets. Korean Journal of Breeding Science , 52(2):179-183, 2020.;). Regarding the VC scores, there were significant differences (P < 0.05) among the tested genotypes in Sinop2020WF and in all four Sorriso environments (Table 2).

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Table 2:
Means, coefficients of variation (CV), and probabilities (P value) for the genotypic source of variation obtained in the individual analysis of variance for grain yield, mass of 100 grains, and value for cultivation (VC) of 11 mungbean genotypes grown in eight environments in Sinop and Sorriso, Mato Grosso, Brazil, in 2019 and 2020.

Combined ANOVA showed differences (P < 0.01) in the genotypic source of variation for the three traits evaluated (Table 3), suggesting that it is possible to select genotypes suitable for the growing conditions in Mato Grosso. The genotype × environment interactions were significant (P < 0.05) only for yield, indicating that the genotypes presented different responses in the experimental environments. Although the occurrence of genotype × environment interactions in mungbean has been previously reported (Thangavel; Anandan; Eswaran, 2011THANGAVEL, P.; ANANDAN, A.; ESWARAN, R. AMMI analysis to comprehend genotype-by-environment (G×E) interactions in rainfed grown mungbean (Vigna radiata L.). Australian Journal of Crop Science, 5(13):1767-1775, 2011.; Asfaw et al., 2012ASFAW, A. et al. Analysis of multi-environment grain yield trials in mung bean Vigna radiata (L.) Wilczek based on GGE biplot in Southern Ethiopia. Journal of Agricultural Science and Technology, 14(2):389-398. 2012.; Win et al., 2018WIN, K. S. et al. Genotype by environment interaction and stability analysis of seed yield, agronomic characters in mungbean (Vigna radiata L. Wilczek) genotypes. International Journal Advanced Research, 6(3):926-934, 2018.; Samyuktha et al., 2020SAMYUKTHA, S. M. et al. Delineation of genotype × environment interaction for identification of stable genotypes to grain yield in mungbean. Frontiers in Agronomy, 2:577911, 2020.), this is the first study evaluating these interactions in the state of Mato Grosso, Brazil.

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Table 3:
Summary of combined ANOVA of the grain yield, mass of 100 grains, and value for cultivation (VC) of 11 mungbean genotypes grown in eight different environments in Sinop and Sorriso, Mato Grosso, Brazil, in 2019 and 2020.

The mean yield of genotype G4 (1305 kg ha^-1) was higher compared with the genotypes G1, G7, and G9 (Table 4). However, the yields of the other seven genotypes were higher than 1150 kg ha^-1 indicating good yield potential for cultivation in the mid-north of Mato Grosso, with averages above 1000 kg ha^-1. In Mato Grosso, yield estimates for mungbean grown in the off-season ranged from 298.40 kg ha^-1 to 1163 kg ha^-1 (Menezes Júnior; Silva; Rocha, 2019MENEZES JÚNIOR, J. A. N.; SILVA, K. J. D.; ROCHA, M. M. Feijão-mungo como perspectiva para a safrinha em Mato Grosso. In: EMPRESA BRASILEIRA DE PESQUISA AGROPECUÁRIA - EMBRAPA. Embrapa Agrossilvipastoril: Primeiras contribuições para o desenvolvimento de uma agropecuária Sustentável. Brasil, Brasília: Embrapa, p.635-640, 2019.). It is noteworthy that yield in the Sorriso2020WF environment was 2055 kg ha^-1, demonstrating that the genotypes respond to the improvement of the environment.

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Table 4:
Means of yield, mass of 100 grains, and value for cultivation (VC) of 11 mungbean genotypes grown in eight environments in Sinop and Sorriso, Mato Grosso, Brazil, in 2019 and 2020.

Besides high yield, genotypes G10, G4, G2, G5, and the control G11 had a mass of 100 grains above 5.5 grams (Table 4). Moreover, the mass of 100 grains of G10 (6.56 g) stood out, higher than that of other genotypes (Table 4). Grain size is important for the commercial acceptance of a mungbean cultivar and, in Brazil, successful cultivars such as MGS Esmeralda exhibit masses of 100 grains ranging from 5.5 to 6.8 g (Vieira et al., 2008VIEIRA, R. F et al. MGS esmeralda: New large seed mungbean cultivar. Pesquisa Agropecuária Brasileira, 43(6):781-782, 2008.).

For cultivation value, G6 had the highest average score (3.56), similar to other six genotypes (Table 4). G6 is the only genotype with yellow seed coat color and also showed high productivity (1162 kg ha^-1) and mass of 100 grains. Thus, G6 is promising for cultivation in the mid-north region of Mato Grosso, Brazil. The market for green seed coat grains is most common for mungbean. However, yellow seed coat cultivars have been selected for regions with a preference for this grain color (Biswas et al., 2016BISWAS, S. C. et al. Development of an early maturing yellow seeded mung bean variety from local germplasms. Plant Environment Development, 5(2):8-16, 2016.; Kim et al., 2019KIM, D. K. et al. A new mungbean cultivar, ‘Jinhwang’, with a short stem and yellow seed coat. Korean Journal of Breeding Science, 51(4):428-433, 2019.; Kim et al, 2020KIM, D. K. et al. A new mungbean cultivar, ‘Samhwang’, with yellow seed coat and lobed leaflets. Korean Journal of Breeding Science , 52(2):179-183, 2020.). Exception for G9, the VC scores of the genotypes were equal to or greater than three (Table 4), which corresponds to most of the traits suitable for commercial cultivation.

Based on the results of the adaptability and stability analysis, the G4 genotype presented the lowest estimate of overall P _i (Table 5). The G2 and G10 genotypes also showed low P _i estimates, indicating good adaptability of these genotypes to the evaluated environments. In addition, these three genotypes had the highest grain yield means. The combination of low P _i index and high yield has been reported previously (Cruz; Carneiro, 2006CRUZ, C. D.; CARNEIRO, P. C. S. Modelos biométricos aplicados ao melhoramento genético. Vol. 2, 2 ed. Viçosa: UFV, 2006. 585p.), including a study with cowpea lines in Mato Grosso, Brazil (Alves et al., 2020ALVES, S. M. et al. Adaptability, stability and agronomic performance of cowpea lines in Mato Grosso, Brazil. Revista Brasileira de Ciências Agrárias, 15(3):e7896, 2020.).

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Table 5:
Mean yield, adaptability and stability indices (P _i ) of mungbean genotypes grown in eight environments in Sinop and Sorriso, Mato Grosso, Brazil, in 2019 and 2020.

Decomposition of the P _i indices into the genetic and interaction components revealed that genetic deviation contributed substantially (> 50%) to the magnitude of the P _i values of all genotypes except for the control G11 (Table 5). According to Daros and Amaral Júnior (2000DAROS, M.; AMARAL JÚNIOR, A. T. Adaptabilidade e estabilidade de produção de Ipomoea batatas. Acta Scientiarum Agronomy, 22(4):911-917, 2000.), the combination of low P _i index with a high percentage of genetic deviation is an important criterion for the selection of genotypes. On this basis, G4, G2, and G10 are the most promising genotypes for cultivation in the mid-north of Mato Grosso, since they showed high mean yield and low percentage contributions to the genotype × environment interactions.

As shown by the mean environmental indices (Table 6), all four Sinop environments were classified as unfavorable (negative values) regardless of the application of fertilizer. In contrast, three of the four Sorriso environments were classified as favorable (positive indices). By the minimum and maximum values, one can see the divergence between the genotypes for yield. The lowest yield amplitude was observed in Sinop2019NF (461 kg ha^-1), whereas the largest was recorded in Sorriso2020WF (997 kg ha^-1). The practical meaning of these results is that the most productive genotype yielded approximately 1000 kg ha^-1 more than the least productive. In general, the yield amplitude in fertilized environments was higher in comparison with those cultivated in the absence of fertilizer, suggesting that the tested genotypes responded well to the environmental improvement.

Thumbnail

Table 6:
Environmental indices and yield of mungbean genotypes grown in eight environments in Sinop and Sorriso, Mato Grosso, Brazil, in 2019 and 2020.

Table 7 shows the adaptability and stability indices of the tested genotypes under environments considered favorable and unfavorable. G10 had the lowest P _if index and was, therefore, the most adaptable to favorable environments. G2, G4, and G6 also exhibited low P _if indices. Our results suggest that these four genotypes were the most responsive to environmental improvement. G4 showed the lowest P _iu index (22.03), indicating that this genotype has good production performance in unfavorable environments (Table 7). G3 and G5 combined high yield and good adaptability under unfavorable environments, indicating a stable behavior in the evaluated environments.

Thumbnail

Table 7:
Adaptability and stability indices under favorable (P _if ) and unfavorable (P _iu ) environments of the mungbean genotypes grown in eight environments in Sinop and Sorriso, Mato Grosso, Brazil, in 2019 and 2020.

The method proposed by Lin and Binns (1988LIN, C. S.; BINNS, M. R. A. A superiority measure of cultivar performance for cultivar x location data. Canadian Journal of Plant Science, 68(1):193-198, 1988.) with modifications (Cruz; Carneiro, 2006CRUZ, C. D.; CARNEIRO, P. C. S. Modelos biométricos aplicados ao melhoramento genético. Vol. 2, 2 ed. Viçosa: UFV, 2006. 585p.) allowed efficient identification of the most adaptable genotypes for cultivation under favorable and unfavorable environments. Pereira et al. (2009PEREIRA, H. S. et al. Comparação de métodos de análise de adaptabilidade e estabilidade fenotípica em feijoeiro-comum. Pesquisa Agropecuária Brasileira , 44(4):374-383, 2009.) have previously highlighted that the method is simple whilst allowing straightforward interpretation of the results and logical classification of genotypes. This methodology is commonly used in research with other types of beans, such as common bean and cowpea (Ribeiro et al., 2008RIBEIRO, N. D. et al. Adaptação e estabilidade de produção de cultivares e linhagens-elite de feijão no Estado do Rio Grande do Sul. Ciência Rural , 38(9):2434-2440, 2008.; Pereira et al., 2009PEREIRA, H. S. et al. Comparação de métodos de análise de adaptabilidade e estabilidade fenotípica em feijoeiro-comum. Pesquisa Agropecuária Brasileira , 44(4):374-383, 2009.; Silva et al., 2013SILVA, G. A. et al. Análise da adaptabilidade e estabilidade de produção em ensaios regionais de feijoeiro para o estado de São Paulo. Revista Ceres, 60(1):59-65, 2013.; Alves et al., 2020ALVES, S. M. et al. Adaptability, stability and agronomic performance of cowpea lines in Mato Grosso, Brazil. Revista Brasileira de Ciências Agrárias, 15(3):e7896, 2020.).

From the field evaluations, the genotypes had a short cycle and high productivity in the mid-north region of Mato Grosso, Brazil. Even in environments without any fertilizer application and sowing at the end of the rainy season (March), yields above 1000 kg ha^-1 were obtained (Table 6). It was possible to identify genotypes with stable behavior, good adaptability to unfavorable environments, and that respond to environmental improvement. In general, the genotypes are promising for further experiments testing the value for cultivation and use.

CONCLUSIONS

Genotypes G2 (BRA-08654-1), G4 (BRA-000027), G5 (BRA-084654-2), and G10 (BG3) combine high yield and large grains. These four genotypes show good general adaptability for cultivation in the mid-north region of Mato Grosso, Brazil. The yellow grain genotype G6 (BRA-084689) also shows high productivity and good adaptability in this region. Genotypes BRA-08654-1, BRA-000027, BRA-084654-2, BRA-084689, and BG3 are indicated for further experiments evaluating cultivation value and use.

AUTHOR CONTRIBUTION

Conceptual idea: Menezes Júnior, J.A.N.; Silva, K.J.D.; Methodology design: Menezes Júnior, J.A.N.; Olibone, D.; Data collection: Menezes Júnior, J.A.N.; Noleto, M.P.; Olibone, D.; Gobbi, S.D.; Pivetta, L.G.; Data analysis and interpretation: Menezes Júnior, J.A.N.; Noleto, M.P.; Pivetta, L.G., and Writing and editing: Menezes Júnior, J.A.N.; Noleto, M.P.; Gobbi, S.D.; Olibone, D.; Pivetta, L.G.; Silva, K.J.D.

ACKNOWLEDGEMENTS

The authors thank the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq; grant no. 432849/2018-1, Chamada Universal MCTIC/2018, SEG no. 20.19.00.151.00.03) and Embrapa (SEG no. 20.19.01.012.00.07) for funding the research, Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) for supporting the Postgraduate Program in Genetics and Plant Breeding of UNEMAT and IFMT (Campus Sorriso) , and EMPAER (Sinop) for cooperation with the study.

REFERENCES

ALVES, S. M. et al. Adaptability, stability and agronomic performance of cowpea lines in Mato Grosso, Brazil. Revista Brasileira de Ciências Agrárias, 15(3):e7896, 2020.
ASFAW, A. et al. Analysis of multi-environment grain yield trials in mung bean Vigna radiata (L.) Wilczek based on GGE biplot in Southern Ethiopia. Journal of Agricultural Science and Technology, 14(2):389-398. 2012.
BISWAS, S. C. et al. Development of an early maturing yellow seeded mung bean variety from local germplasms. Plant Environment Development, 5(2):8-16, 2016.
CHENG, A. et al. In search of alternative proteins: Unlocking the potential of underutilized tropical legumes. Food Security, 11(6):1205-1215, 2019.
COCHRAN, W. G. The combination of estimates from different experiments. Biometrics, 10(1):101-129, 1954.
CRUZ, C. D. GENES: A software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum, 35(3):271-276, 2013
CRUZ, C. D.; CARNEIRO, P. C. S. Modelos biométricos aplicados ao melhoramento genético. Vol. 2, 2 ed. Viçosa: UFV, 2006. 585p.
DAROS, M.; AMARAL JÚNIOR, A. T. Adaptabilidade e estabilidade de produção de Ipomoea batatas Acta Scientiarum Agronomy, 22(4):911-917, 2000.
DUQUE, F. F.; PESSANHA, G. G. Comportamento de dez cultivares de mungo verde nos períodos das águas e da seca em condições de campo. Pesquisa Agropecuária Brasileira, 25(7):963-969, 1990.
KHATTAK, G. S. S. et al. High yielding mungbean [Vigna radiata (L.) Wilczek] variety “NIFA Mung-2017”. Pure and Applied Biology, 10(1):105-114, 2021.
KIM, D. K. et al. A new mungbean cultivar, ‘Jinhwang’, with a short stem and yellow seed coat. Korean Journal of Breeding Science, 51(4):428-433, 2019.
KIM, D. K. et al. A new mungbean cultivar, ‘Samhwang’, with yellow seed coat and lobed leaflets. Korean Journal of Breeding Science , 52(2):179-183, 2020.
KUMAR, S. et al. Next generation breeding in pulses: Present status and future directions. Crop Breeding and Applied Biotechnology, 21(S):e394221S13, 2021.
KUMAR, S. et al. Study on genotype x environment interactions and AMMI analysis for agronomic traits in mungbean (Vigna radiata L. Wilczek) under rainfed conditions. Indian Journal of Genetics and Plant Breeding, 80(3):354-358. 2020.
LIN, C. S.; BINNS, M. R. A. A superiority measure of cultivar performance for cultivar x location data. Canadian Journal of Plant Science, 68(1):193-198, 1988.
LIN, S. S.; ALVES, A. C. Comportamento de linhagens de feijão-mungo (Vigna radiata L.) em Santa Catarina. Ciência Rural, 32(4):553-558, 2002.
MENEZES JÚNIOR, J. A. N.; SILVA, K. J. D.; ROCHA, M. M. Feijão-mungo como perspectiva para a safrinha em Mato Grosso. In: EMPRESA BRASILEIRA DE PESQUISA AGROPECUÁRIA - EMBRAPA. Embrapa Agrossilvipastoril: Primeiras contribuições para o desenvolvimento de uma agropecuária Sustentável. Brasil, Brasília: Embrapa, p.635-640, 2019.
NAIR, R. M. et al. Biotic and abiotic constraints in mungbean production-progress in genetic improvement. Frontieres in Plant Science, 10:1340, 2019.
PEREIRA, H. S. et al. Comparação de métodos de análise de adaptabilidade e estabilidade fenotípica em feijoeiro-comum. Pesquisa Agropecuária Brasileira , 44(4):374-383, 2009.
PIMENTEL-GOMES, F. Curso de estatística experimental. 15 ed. Piracicaba: ESALQ, 2009. 451p.
RAMALHO, M. A. P.; FERREIRA, D. F.; OLIVEIRA, A. C. Experimentação em genética e melhoramento de plantas. 3. ed. Lavras: UFLA, 2012, 305p.
RIBEIRO, N. D. et al. Adaptação e estabilidade de produção de cultivares e linhagens-elite de feijão no Estado do Rio Grande do Sul. Ciência Rural , 38(9):2434-2440, 2008.
SAMYUKTHA, S. M. et al. Delineation of genotype × environment interaction for identification of stable genotypes to grain yield in mungbean. Frontiers in Agronomy, 2:577911, 2020.
SAYÃO, F. D. A; BRIOSO, P. S. T.; DUQUE, F. F. Comportamento de linhagens de mungo verde em condições de campo em Itaguí, RJ. Pesquisa Agropecuária Brasileira , 26(5):669-664, 1991.
SEQUEROS, T. et al. Impact and returns on investment of mungbean research and development in myanmar. Agriculture & Food Security, 9:5, 2020.
SILVA, M. B. O. et al. Desempenho agronómico de genótipos de feijão-caupi. Revista de Ciências Agrárias, 41(1):1059-1066, 2018.
SILVA, G. A. et al. Análise da adaptabilidade e estabilidade de produção em ensaios regionais de feijoeiro para o estado de São Paulo. Revista Ceres, 60(1):59-65, 2013.
THANGAVEL, P.; ANANDAN, A.; ESWARAN, R. AMMI analysis to comprehend genotype-by-environment (G×E) interactions in rainfed grown mungbean (Vigna radiata L.). Australian Journal of Crop Science, 5(13):1767-1775, 2011.
VIEIRA, R. F et al. BRSMG camaleão: New mungbean cultivar with large, shiny, green seeds. Crop Breeding and Applied Biotechnology , 22(2):e32732227, 2022.
VIEIRA, R. F. et al. Desempenho de genótipos de feijão-mungo-verde semeados no inverno na Zona da Mata de Minas Gerais. Revista Ceres, 58(3):402-405, 2011.
VIEIRA, R. F et al. MGS esmeralda: New large seed mungbean cultivar. Pesquisa Agropecuária Brasileira, 43(6):781-782, 2008.
VIEIRA, R. F et al. Ouro Verde MG2: Nova cultivar de mungo verde para-Minas Gerais. Horticultura Brasileira, 20(1):119-120, 2002.
VIEIRA, R. F.; OLIVEIRA, V. R.; VIEIRA, C. Cultivo do feijão-mungo-verde no verão em Viçosa e em Prudente de Morais. Horticultura Brasileira, 21(1):37-43, 2003.
WIN, K. S. et al. Genotype by environment interaction and stability analysis of seed yield, agronomic characters in mungbean (Vigna radiata L. Wilczek) genotypes. International Journal Advanced Research, 6(3):926-934, 2018.

Publication Dates

Publication in this collection
17 July 2023
Date of issue
2023

History

Received
15 Sept 2022
Accepted
19 May 2023

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

[1] ALVES, S. M. et al. Adaptability, stability and agronomic performance of cowpea lines in Mato Grosso, Brazil. Revista Brasileira de Ciências Agrárias, 15(3):e7896, 2020.

[2] ASFAW, A. et al. Analysis of multi-environment grain yield trials in mung bean Vigna radiata (L.) Wilczek based on GGE biplot in Southern Ethiopia. Journal of Agricultural Science and Technology, 14(2):389-398. 2012.

[3] BISWAS, S. C. et al. Development of an early maturing yellow seeded mung bean variety from local germplasms. Plant Environment Development, 5(2):8-16, 2016.

[4] CHENG, A. et al. In search of alternative proteins: Unlocking the potential of underutilized tropical legumes. Food Security, 11(6):1205-1215, 2019.

[5] COCHRAN, W. G. The combination of estimates from different experiments. Biometrics, 10(1):101-129, 1954.

[6] CRUZ, C. D. GENES: A software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum, 35(3):271-276, 2013

[7] CRUZ, C. D.; CARNEIRO, P. C. S. Modelos biométricos aplicados ao melhoramento genético. Vol. 2, 2 ed. Viçosa: UFV, 2006. 585p.

[8] DAROS, M.; AMARAL JÚNIOR, A. T. Adaptabilidade e estabilidade de produção de Ipomoea batatas Acta Scientiarum Agronomy, 22(4):911-917, 2000.

[9] DUQUE, F. F.; PESSANHA, G. G. Comportamento de dez cultivares de mungo verde nos períodos das águas e da seca em condições de campo. Pesquisa Agropecuária Brasileira, 25(7):963-969, 1990.

[10] KHATTAK, G. S. S. et al. High yielding mungbean [Vigna radiata (L.) Wilczek] variety “NIFA Mung-2017”. Pure and Applied Biology, 10(1):105-114, 2021.

[11] KIM, D. K. et al. A new mungbean cultivar, ‘Jinhwang’, with a short stem and yellow seed coat. Korean Journal of Breeding Science, 51(4):428-433, 2019.

[12] KIM, D. K. et al. A new mungbean cultivar, ‘Samhwang’, with yellow seed coat and lobed leaflets. Korean Journal of Breeding Science , 52(2):179-183, 2020.

[13] KUMAR, S. et al. Next generation breeding in pulses: Present status and future directions. Crop Breeding and Applied Biotechnology, 21(S):e394221S13, 2021.

[14] KUMAR, S. et al. Study on genotype x environment interactions and AMMI analysis for agronomic traits in mungbean (Vigna radiata L. Wilczek) under rainfed conditions. Indian Journal of Genetics and Plant Breeding, 80(3):354-358. 2020.

[15] LIN, C. S.; BINNS, M. R. A. A superiority measure of cultivar performance for cultivar x location data. Canadian Journal of Plant Science, 68(1):193-198, 1988.

[16] LIN, S. S.; ALVES, A. C. Comportamento de linhagens de feijão-mungo (Vigna radiata L.) em Santa Catarina. Ciência Rural, 32(4):553-558, 2002.

[17] MENEZES JÚNIOR, J. A. N.; SILVA, K. J. D.; ROCHA, M. M. Feijão-mungo como perspectiva para a safrinha em Mato Grosso. In: EMPRESA BRASILEIRA DE PESQUISA AGROPECUÁRIA - EMBRAPA. Embrapa Agrossilvipastoril: Primeiras contribuições para o desenvolvimento de uma agropecuária Sustentável. Brasil, Brasília: Embrapa, p.635-640, 2019.

[18] NAIR, R. M. et al. Biotic and abiotic constraints in mungbean production-progress in genetic improvement. Frontieres in Plant Science, 10:1340, 2019.

[19] PEREIRA, H. S. et al. Comparação de métodos de análise de adaptabilidade e estabilidade fenotípica em feijoeiro-comum. Pesquisa Agropecuária Brasileira , 44(4):374-383, 2009.

[20] PIMENTEL-GOMES, F. Curso de estatística experimental. 15 ed. Piracicaba: ESALQ, 2009. 451p.

[21] RAMALHO, M. A. P.; FERREIRA, D. F.; OLIVEIRA, A. C. Experimentação em genética e melhoramento de plantas. 3. ed. Lavras: UFLA, 2012, 305p.

[22] RIBEIRO, N. D. et al. Adaptação e estabilidade de produção de cultivares e linhagens-elite de feijão no Estado do Rio Grande do Sul. Ciência Rural , 38(9):2434-2440, 2008.

[23] SAMYUKTHA, S. M. et al. Delineation of genotype × environment interaction for identification of stable genotypes to grain yield in mungbean. Frontiers in Agronomy, 2:577911, 2020.

[24] SAYÃO, F. D. A; BRIOSO, P. S. T.; DUQUE, F. F. Comportamento de linhagens de mungo verde em condições de campo em Itaguí, RJ. Pesquisa Agropecuária Brasileira , 26(5):669-664, 1991.

[25] SEQUEROS, T. et al. Impact and returns on investment of mungbean research and development in myanmar. Agriculture & Food Security, 9:5, 2020.

[26] SILVA, M. B. O. et al. Desempenho agronómico de genótipos de feijão-caupi. Revista de Ciências Agrárias, 41(1):1059-1066, 2018.

[27] SILVA, G. A. et al. Análise da adaptabilidade e estabilidade de produção em ensaios regionais de feijoeiro para o estado de São Paulo. Revista Ceres, 60(1):59-65, 2013.

[28] THANGAVEL, P.; ANANDAN, A.; ESWARAN, R. AMMI analysis to comprehend genotype-by-environment (G×E) interactions in rainfed grown mungbean (Vigna radiata L.). Australian Journal of Crop Science, 5(13):1767-1775, 2011.

[29] VIEIRA, R. F et al. BRSMG camaleão: New mungbean cultivar with large, shiny, green seeds. Crop Breeding and Applied Biotechnology , 22(2):e32732227, 2022.

[30] VIEIRA, R. F. et al. Desempenho de genótipos de feijão-mungo-verde semeados no inverno na Zona da Mata de Minas Gerais. Revista Ceres, 58(3):402-405, 2011.

[31] VIEIRA, R. F et al. MGS esmeralda: New large seed mungbean cultivar. Pesquisa Agropecuária Brasileira, 43(6):781-782, 2008.

[32] VIEIRA, R. F et al. Ouro Verde MG2: Nova cultivar de mungo verde para-Minas Gerais. Horticultura Brasileira, 20(1):119-120, 2002.

[33] VIEIRA, R. F.; OLIVEIRA, V. R.; VIEIRA, C. Cultivo do feijão-mungo-verde no verão em Viçosa e em Prudente de Morais. Horticultura Brasileira, 21(1):37-43, 2003.

[34] WIN, K. S. et al. Genotype by environment interaction and stability analysis of seed yield, agronomic characters in mungbean (Vigna radiata L. Wilczek) genotypes. International Journal Advanced Research, 6(3):926-934, 2018.

Genotypes, color of seed tegument	Environment¹
G1 (BRA-084638), green	Sinop2019WF
G2 (BRA-08654-1), green	Sinop2019NF
G3 (BRA-084671), green	Sinop2020WF
G4 (BRA-000027), green	Sinop2020NF
G5 (BRA-084654-2), green	Sorriso2019WF
G6 (BRA-084689), yellow	Sorriso 2019NF
G7 (BRA-084930), green	Sorriso2020WF
G8 (BRA-084981), green	Sorriso2020NF
G9 (BG2), green
G10 (BG3), green
G11 (BRSMG Camaleão; control), green

Environment¹	Yield (kg ha^-1)			Mass of 100 grains (g)			VC (score)
Environment¹	Mean value	CV %	P value	Mean value	CV %	P value	Mean value	CV %	P value
Sinop2019WF	899	26.35	0.082	6.38	5.98	0.000	2.86	19.19	0.263
Sinop2019NF	576	32.01	0.097	6.16	8.81	0.000	2.46	27.27	0.239
Sinop2020WF	895	27.12	0.012	5.44	8.49	0.000	3.09	9.59	0.000
Sinop2020NF	781	47.41	0.293	5.36	8.55	0.002	2.98	21.74	0.283
Sorriso2019WF	1464	10.17	0.000	5.21	3.87	0.000	3.95	7.19	0.000
Sorriso2019NF	851	15.82	0.006	5.13	3.86	0.000	3.19	9.81	0.000
Sorriso2020WF	2055	11.39	0.001	5.36	9.24	0.004	3.33	8.69	0.000
Sorriso2020NF	1656	16.22	0.048	4.98	6.06	0.000	3.21	10.28	0.001

Source of variation	DF¹	Mean square yield	DF¹	Mean square 100-grain mass	DF	Mean square VC
Block within environment	16	469732.67	16	0.295	16	0.535
Genotype	10	599283.60**	10	8.044**	10	3.619**
Environment	7	8753011.99**	7	8.239**	7	5.946**
Genotype × environment interactions	53	115752.57*	55	0.214^ns	70	0.157^ns
Mean Error	115	78904.97	122	0.209	160	0.204
Mean		1147		5.50		3.13
CV%²		24.48		8.32		14.41

Treatment (genotype)	Yield¹ (kg ha^-1)	Mass of 100 grains¹ (g)	VC¹ (score)
G1 (BRA-084638)	1048 b	5.44 de	3.20 ab
G2 (BRA-08654-1)	1239 ab	5.71 cd	3.06 b
G3 (BRA-084671)	1204 ab	5.14 ef	3.00 b
G4 (BRA-000027)	1305 a	5.96 bc	3.35 ab
G5 (BRA-084654-2)	1216 ab	5.69 cd	3.02 b
G6 (BRA-084689)	1162 ab	5.38 de	3.56 a
G7 (BRA-084930)	1057 b	4.63 g	3.22 ab
G8 (BRA-084981)	1161 ab	5.00 fg	3.35 ab
G9 (BG2)	734 c	4.88 fg	2.08 c
G10 (BG3)	1250 ab	6.56 a	3.35 ab
G11 (control)	1243 ab	6.13 b	3.29 ab

Genotype	Mean yield (kg ha^-1)	Overall P _i ¹/1000	Genetic deviation/1000	Interaction deviation/1000	Genetic deviation (%)	Contribution to the interaction (%)
G1 (BRA-084638)	1048	91.88	83.14	8.74	90.48	4.39
G2 (BRA-08654-1)	1239	36.20	23.55	12.65	65.03	6.35
G3 (BRA-084671)	1204	41.84	31.84	10.00	76.08	5.02
G4 (BRA-000027	1305	20.38	11.45	8.93	56.16	4.48
G5 (BRA-084654-2)	1216	54.00	28.75	25.25	53.23	12.67
G6 (BRA-084689)	1162	65.38	43.24	22.14	66.13	11.11
G7 (BRA-084930)	1057	105.99	79.57	26.42	75.06	13.26
G8 (BRA-084981)	1161	65.59	43.50	22.09	66.32	11.08
G9 (BG2)	734	276.15	260.28	15.87	94.25	7.97
G10 (BG3)	1250	36.40	21.15	15.25	58.10	7.65
G11 (control)	1243	54.54	22.61	31.93	41.46	16.02

Environment¹	Mean environmental index	Yield (kg ha^-1)
Environment¹	Mean environmental index	Mean	Minimum	Maximum	Amplitude
Sinop2019WF	-248	899	578	1227	649
Sinop2019NF	-572	576	366	827	461
Sinop2020WF	-252	895	460	1341	881
Sinop2020NF	-366	781	498	1262	764
Sorriso2019WF	317	1464	913	1774	861
Sorriso2019NF	-296	851	477	993	516
Sorriso2020WF	908	2055	1411	2408	997
Sorriso2020NF	509	1656	1020	1816	796
Mean	-	1147	-	-	-

Genotype	P_if /1000	P_iu /1000
G1 (BRA-084638)	95.73	89.58
G2 (BRA-08654-1)	9.27	52.35
G3 (BRA-084671)	38.13	44.06
G4 (BRA-000027)	17.64	22.03
G5 (BRA-084654-2)	67.88	45.68
G6 (BRA-084689)	9.90	98.67
G7 (BRA-084930)	103.03	107.76
G8 (BRA-084981)	33.65	84.75
G9 (BG2)	394.84	204.94
G10 (BG3)	2.98	56.44
G11 (control)	9.73	81.42

Brasil

Brasil

Adaptability and stability of mungbean genotypes in the Mid-North of Mato Grosso, Brazil

Adaptabilidade e estabilidade de linhagens de feijão-mungo na região médio-norte de Mato Grosso, Brasil

ABSTRACT

RESUMO

INTRODUCTION

MATERIAL AND METHODS

RESULTS AND DISCUSSION

CONCLUSIONS

AUTHOR CONTRIBUTION

ACKNOWLEDGEMENTS

REFERENCES

Publication Dates

History