Abstract
Wheat crop contributes to a major portion of the agriculture economy of Nepal. It is ranked as the third major cereal crop of the country even though, it faces terminal heat stress which speeds up the grain filling rate and shortens the filling period, causing reduction in grain weight, size, number and quality losses. We can minimize this loss through a genotypic selection of high-yielding lines by understanding the genotype-environment interaction. The objective of this research is to obtain a high yielding line with a stable performance across the environments. In order to do so, we conducted an experiment using eighteen elite wheat lines and two check varieties in alpha-lattice design with two replications in different environments viz. irrigated and terminal heat stress environment from November 2019 to April 2020. The analysis of variance revealed that genotype, environment and their interaction had a highly significant effect on the yield. Furthermore, the which-won–where model indicated specific adaptation of elite lines NL 1179, NL 1420, BL 4407, NL 1368 to the irrigated environment and Bhirkuti to the terminal heat-stressed environment. Similarly, the mean-versus-stability study indicated that elite lines BL 4407, NL 1368, BL 4919, NL 1350, and NL 1420 had above-average yield and higher stability whereas elite lines Gautam, NL 1412, NL 1376, NL 1387, NL 1404, and NL 1381 had below-average yield and lower stability. The ranking of elite lines biplot, PC1 explaining 73.6% and PC2 explaining 26.4% of the interaction effect, showed the rank of elite line, NL 1420 > NL 1368> NL 1350 > other lines, close to the ideal line. On the basis of the obtained results, we recommend NL 1420 with both the high yield and stability is suited across both the environments, while NL 1179 and Bhirkuti is adapted specifically for irrigated and terminal heat stress environment, respectively.
Highlights
The cultivation of wheat (Triticum aestivum L.) dates back to 10000 years ago when hunting and gathering society made a transition to agriculture
The result of the analysis of variance of the AMMI model revealed that grain yield is significantly (p < 0.001) affected by environment, genotype, and genotype-environment interaction, which explained 75.66 %, 17.25%, and 7.08 % of the occurred variation, respectively
This study indicated that genotype, environment, and their interaction have a significant effect on the yield stability and 100% of the interaction effect was explained by PC 1 as per the AMMI model
Summary
The cultivation of wheat (Triticum aestivum L.) dates back to 10000 years ago when hunting and gathering society made a transition to agriculture. In the past 10 years, Nepalese agriculture has seen a decrease in the cropping area of wheat and a very low increase in productivity. MoALD (2020) reports a decrease of 4% cropping area from 731131 ha in 2009/10 to 703992 ha in 2018/19 In these ten years, the productivity increase has been very slow at the rate of just 0.102 ton/ha. As a consequence of the low productivity, Nepal has been witnessing a gradual annual increase in wheat imports. Nepal's wheat import was 103705 tons in 2015, 217105 tons in 2016, 199626 tons in 2017, and 107467 tons in 2018 (FAOSTAT, 2020). Research on breeding and suitable intensification in order to bridge this yield gap of wheat carries a huge potential
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