Analysis of Indian post-rainy sorghum multi-location trial data reveals complexity of genotype × environment interaction

Rakshit, Sujay; Ganapathy, K. N.; Gomashe, S. S.; Dhandapani, A.; Swapna, M.; Mehtre, S. P.; Gadakh, S. R.; Ghorade, R. B.; Kamatar, M. Y.; Jadhav, B. D.; Das, I. K.; Prabhakar, .

doi:10.1017/s0021859616000137

Cited by 14 publications

(15 citation statements)

References 27 publications

(58 reference statements)

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“…In many regions of the world, in recent years, Sorghum [Sorghum bicolor (L.) Moench] has become an increasingly important forage crop (Qu, Liu, Dong, Lu, & Shen, 2014;Amelework, Shimelis, Tongoona, Mark Laing, & Mengistu, 2015;Rakshit et al, 2016;Perazzo et al, 2017;Mwamahonje & Maseta, 2018;Worede, Mamo, Assefa, Gebremariam, & Beze, 2020). This trend is a consequence of the high dry matter yield of sorghum and its ability to adjust to different climatic and soil conditions, which include hot weather, such as in the semiarid region (Perazzo et al, 2017;Mwamahonje & Maseta, 2018;Borges et al, 2019;Ramos et al, 2021;Rigueira et al, 2021), or relatively cold climates, like Canada, Korea (McCaughey, Therrien, & Mabon, 1996;Paradhipta et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Yield and nutritional value of biomass sorghum (BRS 716) managed in different row spacing and maturity at harvest in the semiarid region of Brazil

Souza¹,

Júnior²,

Monção³

et al. 2021

Semina: Ciênc. Agrár.

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The objective was to evaluate the structural, yield and nutritional characteristics of biomass sorghum BRS 716 managed in different row planting spacing and harvest age in a semiarid region of Brazil. Three row spacing (45, 70 and 90 cm; plots) and four maturity at harvest (70, 100, 130 and 160 days; subplots) were evaluated following a randomized block design in a 3 x 4 split plot arrangement, with eight blocks. The useful area was 3 x 15 m. Variation in soil fertility in the area was the blocking factor. There was interaction between row spacing and maturity at harvest (P < 0.05) on plant height (P = 0.01), dry matter yield (DMY; P < 0.01) and proportion of senescent material (P = 0.01). The DMY observed at the age of 160 days and spacing of 90 cm was 41.40% higher than the DMY at the same age and in spacings of 45 and 70 cm (mean of 21.45 t/ha). As the maturity at harvest increased, there was a reduction in the crude protein content (P < 0.01), potential degradability (P < 0.01) and effective degradability (P < 0.01) of dry matter, and the content of non-fiber carbohydrates (P < 0.01), total digestible nutrients (P < 0.01) and the readily soluble fraction (P < 0.01) of the dry matter increased. Considering the yield and nutritional characteristics of biomass sorghum BRS 716 managed in the semiarid region for silage production, the row spacing of 90 cm and the maturity at harvest of 160 days after planting are recommended.

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Section: Introductionmentioning

confidence: 99%

Yield and nutritional value of biomass sorghum (BRS 716) managed in different row spacing and maturity at harvest in the semiarid region of Brazil

Souza¹,

Júnior²,

Monção³

et al. 2021

Semina: Ciênc. Agrár.

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“…In Russia [1,3,[12][13][14][15][16][17][18] and other countries [11,[19][20][21][22][23][24][25][26], the leading breeders attached great importance to adaptive selection in their studies. Assessment of adaptability, ecological plasticity and stability of varieties by different methods, their application in different climatic conditions is an actual direction of the selection process.…”

Section: Introductionmentioning

confidence: 99%

Assessment of plasticity and stability of grain sorghum varieties on the basis of their grain yield

et al. 2020

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Assessment of adaptability, environmental plasticity and stability of crop varieties in different climatic conditions is an important direction of the selection process. The purpose of the research was to assess the ecological plasticity and stability of 5 varieties (Premiera, Slavyanka, Ros, Kinelskoye 63, Dershavnoe) and 3 lines (L-28/14, L-141/14, L 34/14) of grain sorghum, to identify the role of abiotic factors in the dynamics of its grain yield at the final stages of selection in the competitive testing of varieties. The studies were carried out in the forest-steppe of the Samara region in experimental fields and in the laboratories of the Volga Research Institute of Breeding and Seed Production in 2015-2018 according to the dispersion methods of A.V. Kilchevsky and L.V. Khotyleva, S.A. Eberhart and W.A. Russel. According to the ecological plasticity variety Ros and line L-34/14 were of intensive type. Varieties Derzhavhoe, Kinelskoye 63, Slavyanka and line L-28/14 belonged to the semi-intensive type. Variety Premiera and line L-141/14 were of extensive type. The combination of high productivity and stability was observed in varities Kinelskoye 63, Derzhavnoe, L-28/14 with high parameters of breeding value of genotype. Promising sample L-28/14 with high productivity and environmental stability is recommended for transfer to the state variety testing.

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“…The Additive Main Effects and Multiplicative Interaction (AMMI) is a biplot based graphical unique linear-bilinear model and combines both of the above approaches of ANOVA and multiplicative models (Gabriel 1971;Gauch 1988;Yan et al 2007). AMMI model is an efficient method to study stable genotypes and discriminating environments and widely used in several studies (Nurminiemi et al 2002;Mortazavian et al 2014;Sousa et al 2015;Raggi et al 2017;Rakshit et al 2017). It displays main effects, environment (E) main effects, and genotype by environment interaction effects on a biplot and helpful for the plant scientists to see and judge desirable genotypes and environments (Gauch 2006;Gauch et al 2008).…”

Section: Introductionmentioning

confidence: 99%

Additive main effects and multiplicative interaction and yield stability index for genotype by environment analysis and wider adaptability in Barley

Kumar

Kharub

Singh

2018

Cereal Research Communications

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Genotype by environment interaction distorts genetic analysis, changes relative ranking of genotypes and a major obstruction for varietal release. AMMI model is a quick and relevant tool to judge environmental behaviour and genotypic stability in comparison to ANOVA, multiplicative model and linear regressions. We evaluated 19 barley genotypes grown at 08 diverse locations to identify discriminating environments and ideal genotypes with dynamic stability. In AMMI ANOVA, the locations and genotype by environment interaction exhibited 66% and 14.7% of the total variation. The initial first two principal components showed significant interaction with 36.0 and 28.4% variation, respectively. AMMI1 biplot showed that the environments Bawal, Ludhiana and Durgapura were high yielding with high IPCA1 scores and located far away from the biplot origin. However, in AMMI1and AMMI2 biplots the locations Hisar, Ludhiana, Karnal, Bathinda and Modipuram were found suitable with low IPCA2 scores. Yield stability index (YSI) was highly useful with ASV ranks and the genotypes DWRB150 and BH1013 and checks BH902, DWRUB52 and DWRB101 were selected for high grain yield and wider adaptability across the locations.

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Analysis of Indian post-rainy sorghum multi-location trial data reveals complexity of genotype × environment interaction

Cited by 14 publications

References 27 publications

Yield and nutritional value of biomass sorghum (BRS 716) managed in different row spacing and maturity at harvest in the semiarid region of Brazil

Yield and nutritional value of biomass sorghum (BRS 716) managed in different row spacing and maturity at harvest in the semiarid region of Brazil

Assessment of plasticity and stability of grain sorghum varieties on the basis of their grain yield

Additive main effects and multiplicative interaction and yield stability index for genotype by environment analysis and wider adaptability in Barley

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