ADAPTABILIDADE E ESTABILIDADE DE FERRO E ZINCO EM FEIJÃO-CAUPI POR MEIO DA ANÁLISE AMMI

Carlos Enrique Cardona-Ayala; Hermes Araméndiz Tatis; Miguel Mariano Espitia Camacho

doi:10.1590/1983-21252021v34n310rc

Authors

Carlos Enrique Cardona-Ayala Department of Agronomic Engineering and Rural Development, Universidade de Cordoba, Montería, CO https://orcid.org/0000-0002-9607-3858
Hermes Araméndiz Tatis Department of Agronomic Engineering and Rural Development, Universidade de Cordoba, Montería, CO https://orcid.org/0000-0002-2585-6273
Miguel Mariano Espitia Camacho Department of Agronomic Engineering and Rural Development, Universidade de Cordoba, Montería, CO https://orcid.org/0000-0001-7382-9643

DOI:

https://doi.org/10.1590/1983-21252021v34n310rc

Keywords:

Vigna unguiculata. Biofortification. Genotype-environment interaction. Micronutrients. Malnutrition.

Abstract

Iron and zinc deficiency is one of the main problems affecting vulnerable populations in the Colombian Caribbean, thereby generating malnutrition from the consumption of foods with low content of essential minerals. The objective of this study was to evaluate the genotype-environment interaction for iron and zinc accumulation in grains in 10 cowpea bean genotypes by additive main effects and multiplicative interaction (AMMI) model and to select the most stable ones to stimulate their planting or as parents in the genetic improvement program. Nine promising lines and a commercial control were evaluated using the randomized complete block design with 10 treatments and four replications in 10 environments of the northern Colombia in the second semester of 2017 and first of 2018. The adaptability and stability analysis was done using AMMI model. The results showed highly significant differences at the level of environments, genotypes, and genotype-environment interaction for iron and zinc, demostrating a differential adaptability of genotypes in the test environments. Genotypes 2 and 3 expressed greater adaptability and stability for iron contents in the seed; while genotype 1, recorded it for zinc contents. These three genotypes outperformed the commercial control and, therefore, can be recommended for planting or be used as parents in the genetic improvement program.

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References

ANURADHA, N. et al. Evaluation of pearl millet [Pennisetum glaucum (L.) R. Br.] for grain iron and zinc content in different agro climatic zones of India. Indian Journal of Genetics and Plant Breeding, 77: 65-73, 2017.

BASHIR, E.M.A. et al. Patterns of pearl millet genotype-by-environment interaction for yield performance and grain iron (Fe) and zinc (Zn) concentrations in Sudan. Field Crops Research, 166: 82-91, 2014.

DARAI, R. et al. AMMI biplot analysis for genotype environment interaction on yield trait of high Fe content lentil genotypes in Terai and Mid-Hill environment of Nepal. Annals of Agricultural and Crop Sciences, 2: e-1026, 2017.

EBDON, J.S.; GAUCH JR, H .G. Additive Main and Multiplicative Interaction Analysis of National Turfgrass Performance Trials: I. Interpretation of Genotype x Envirinment interaction. Crop Science, 42: 489-496, 2002.

EBERHART, S.A.; RUSSELL, W.A. Stability parameters for comparing varieties. Crop Science, 6: 36-40, 1966.

FAO. 2020. Estadísticas de cultivo. Disponível em: http://www.fao.org/faostat/es/#data/QC. Acesso em: 18 ago. 2020.

GADDAMEEDI, A. et al. Inheritance studies on grain iron and zinc concentration and agronomic traits in sorghum [Sorghum bicolor (L.) Moench]. Journal of Cereal Science, 83: 252-258, 2018.

GERRANO, A.S. et al. Selection of cowpea genotypes based on grain mineral and total protein content.Acta Agriculturae Scandinavica, 69: 155-166, 2019.

GOLLOB, H.F. A statistical model which combines features of factor analytic and analysis of variance techniques. Psychometrika, 33: 73-115, 1968.

GUILLÉN-MOLINA, M. et al. Biofortificación de frijol caupí (Vigna unguiculata L. Walp) con hierro y zinc. Revista Mexicana de ciencias Agrícolas, 9:3427-3438, 2016.

INABANGAN-ASILO, M. et al. Stability and G × E analysis of zinc-biofortified rice genotypes evaluated in diverse environments. Euphytica, 215:1-17, 2019.

KUMAR, S. et al. Crop biofortification for iron (Fe), zinc (Zn) and vitamin A with transgenic approaches. Heliyon,5: e01914, 2019.

LIU, H. et al. Grain iron and zinc concentrations of wheat and their relationships to yield in major wheat production areas in China. Field Crops Research, 156: 151-160, 2014.

MALLIKARJUNA, M.G. et al. Stability performance of inductively coupled plasma mass spectrometry-phenotyped kernel minerals concentration and grain yield in maize in different agro-climatic zones. PLoS One, 10: e0140947, 2015.

MÁRQUEZ-QUIROZ, C. et al. Biofortification of cowpea beans with iron: iron´s influence on mineral content and yield. Journal of Soil Science and Plant Nutrition, 15: 839-847, 2015.

MURANAKA, S. et al. Genetic diversity of physical, nutritional and functional properties of cowpea grain and relationships among the traits. Plant Genetic Resources, 14: 67-76, 2016.

OLIVEIRA, D.S. et al. Adaptability and tability of the zinc density in cowpea genotypes through GGE-Biplot method. Revista Ciência Agronômica, 48: 783-791, 2017.

PACHECO, A. et al. 2015. "GEA-R (Genotype x Environment Analysis with R for Windows) Version 4.1", https://hdl.handle.net/11529/10203, CIMMYT Research Data & Software Repository Network, V16. Disponível em: https://data.cimmyt.org/dataset.xhtml?persistentId=hdl:11529/10203. Acesso em: 19 abr. 2020.

SANTOS, A. et al. Nonlinear regression and multivariate analysis used to study the phenotypic stability of Cowpea Genotypes. Hortscience, 54: 1682-1685, 2019.

SANTOS, A. et al. Adaptability and stability of cowpea genotypes to Brazilian Midwest. African Journal of Agricultural Research, 10: 3901-3908, 2015.

SINGH, P. et al. Bioavailability of Fe and Zn in selected legumes, cereals, meat and milk products consumed in Fiji. Food chemistry, 207: 125-131, 2016.

SINGH, V. et al. Stability analysis in mung vean (Vigna radiata (L.) Wilczek) for nutritional quality and seed yield. Legume Research, 36: 56-61, 2013.

SINGHAL, T. et al. Genotype × environment interaction and genetic association of grain iron and zinc content with other agronomic traits in RIL population of pearl millet. Crop & Pasture Science, 69: 1092-1102, 2018.

ZOBEL, R.; WRIGHT, M.; GAUCH, H. Statistical analysis of a yield trial. Agronomy Journal, 80: 388-393, 1988.