Genetic Variability Analysis for Traits in Okra (<i>Abelmoschus esculents</i> L. Moench) Genotypes

Habtam Setu

doi:http://dx.doi.org/10.26855/ijfsa.2023.03.014

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Article Open Access http://dx.doi.org/10.26855/ijfsa.2023.03.014

Genetic Variability Analysis for Traits in Okra (Abelmoschus esculents L. Moench) Genotypes

Habtam Setu

Ethiopian Institute of Agricultural Research, Holetta Agricultural Research Center, Addis Ababa, Ethiopia.

*Corresponding author: Habtam Setu

Published: April 17,2023

Abstract

A country's okra production is vital for its economic and nutritional well-being, so selecting genotypes with high yields is crucial. A crop's potential for improvement is determined by the magnitude of genetic variability present in genotypes, along with genetic advancement, character association, and direct and indirect effects on yield and yield attributes; however, crop variability in this country is not well studied. Thus, sixty-three okra genotypes were evaluated using an alpha lattice (7 x 9) design to estimate the extent of their variability, heritability, and genetic advance. The data were collected from 15 quantitative traits. Analyses of variance revealed that all genotypes were highly significant for all traits. Overall, there was a slightly higher phenotypic coefficient of variation (PCV) compared to a genotypic coefficient of variation (GCV) for all traits. A wide range of variation was also observed within genotypes, with most traits exhibiting high coefficients of variation. Days to 50% flowering had the lowest GCV (4.93%) and PCV (6.37%), while secondary branch numbers per plant had the highest GCV (94.60%) and PCV (97.19%). A wide range of heritability and genetic advancement was observed, ranging from 46.44% (number of nodes per plant) to 97.42% (fruit yield per plant) and 8.13% (days to 50% flowering) to 94.99% (fruit yield per plant), respectively. High heritability (broad sense) along with high genetic advance was observed for fruit yield per plant, number of secondary branches per plant, number of fruit per plant, fruit weight, fruit length, plant height, and fruit diameter. Traits like plant spread in East-West direction, plant spread in North-South direction, number of ridges per fruit, and number of fruited-nodes per plant were also showed high heritability (broad sense) along with high genetic advance, which showing a diverse genetic background and predominance of additive gene control for these traits, thereby providing a great scope for selection.

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How to cite this paper

Genetic Variability Analysis for Traits in Okra (Abelmoschus esculents L. Moench) Genotypes

How to cite this paper: Habtam Setu. (2023) Genetic Variability Analysis for Traits in Okra (Abelmoschus esculents L. Moench) Genotypes. International Journal of Food Science and Agriculture, 7(1), 95-104.

DOI: http://dx.doi.org/10.26855/ijfsa.2023.03.014

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