Yield and leaf nutrient concentrations of common bean genotypes as influenced by aluminium toxicity under acidic soils

Legesse, Hirpa; Dechassa, N.; Gebeyehu, Setegn; Bultosa, Geremew; Mekbib, Firew

doi:10.18801/jbar.120117.122

Cited by 4 publications

(4 citation statements)

References 35 publications

(38 reference statements)

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“…Similar findings were reported by Kushwaha et al (2017) in cowpea. Legesse et al (2017) also reported a significant decrease in plant height with aluminium treatment in common bean.…”

Section: Resultsmentioning

confidence: 88%

“…From the results obtained, it was revealed that marked negative effects of aluminium were observed at higher aluminium levels. Effect of interaction between genotypes and aluminium treatment were found to be significant as Legesse et al (2017) reported significant reductions in the pod length and yield of common bean in response to applying higher level of aluminium (100 mg Al/ kg soil), however at the lower rate (12.5 mg Al/kg soil), they observed no significant difference for all the yield components compared to the control. In agreement with the results of this study, Kushwaha et al (2017) reported a decrease in pod weight and pod yield in response to aluminium treatment in soil.…”

Section: Genotypesmentioning

confidence: 91%

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Screening of Dolichos bean (Lablab purpureus (L.) Sweet) genotypes for aluminium tolerance

Ansari

Pandey

Mailappa

et al. 2018

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The present investigation was carried out to screen the dolichos bean genotypes for aluminium tolerance. The experiment was laid out in a factorial completely randomized design with 2 factors (20 genotypes with four aluminium concentration of 0, 15, 30, 45 mg of Al/kg soil) with three replications. Main effect and interaction effects were studied for vine length, root length, root tolerance index, root dry matter, shoot dry matter, leaf dry matter, total dry matter and extractable aluminium in soil at 4th week after sowing whereas the pod weight, pod length and yield were observed at harvesting stage. The genotypes and aluminium treatment showed significant difference for all the studied parameters. The interaction effect was also found to be significant for all the characters except for vine length. From the present study it was concluded that genotypes Pusa Sem 3, G 2 and G 4 were tolerant to aluminium toxicity upto 45 mg Al/kg as well as high yielding.

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“…Similar findings were reported by Kushwaha et al (2017) in cowpea. Legesse et al (2017) also reported a significant decrease in plant height with aluminium treatment in common bean.…”

Section: Resultsmentioning

confidence: 88%

Section: Genotypesmentioning

confidence: 91%

Screening of Dolichos bean (Lablab purpureus (L.) Sweet) genotypes for aluminium tolerance

Ansari

Pandey

Mailappa

et al. 2018

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“…Con respecto al K, de acuerdo a Das et al (2019), este elemento es requerido por los cultivos casi en las mismas proporciones o en algunos casos mayor que el N; no obstante, la mayoría de los agricultores solo aplican N, o N y P sin considerar o solo agregando cantidades pequeñas de fertilizante potásico. Esto concuerda con los resultados en los Cuadros 2, 3 y 4, con bajos contenidos de K y elevadas concentraciones de P. Con relación a sitios de pH ácido, Legesse et al (2017) mencionan que la acidif icación del suelo resulta en la def iciencia de nutrientes, entre ellos el K. Diversos estudios han demostrado que la disponibilidad de K es menor en suelos ácidos (Zhang et al, 2009), lo cual reduce el rendimiento de los cultivos. Por esta razón, corregir la acidez de los sitios evaluados resulta un factor importante en la asimilación de los nutrientes por los cultivos, en el caso del K, Liu et al (2020) mencionan que la adición de cal permite remover el Al de los sitios intercambiables incrementando la disponibilidad de K y otras bases intercambiables.…”

Section: Resultados Y Discusiónunclassified

Fertilidad e índice de calidad del suelo de la cuenca del río San Pedro en Nayarit

Martínez-Rodríguez

Can-Chulim

Ortega-Escobar

et al. 2021

Terra

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El área agrícola de la cuenca del río San Pedro en Nayarit es una llanura costera con suelos de origen aluvial, sometidos a inundación, deposición y a diferentes procesos que controlan el aporte de nutrientes y la fertilidad del suelo. El objetivo de esta investigación fue evaluar las propiedades de los suelos para diagnosticar la fertilidad y determinar el índice de calidad del suelo, tomando como parámetros pH, MO, N, P, K, CIC, Ca y Mg. Se realizaron muestreos a 30 cm de profundidad en 38 sitios en junio de 2017 y en 45 en 2018. Se midió pH, CE, textura, Da, CO, MO, N inorgánico, P, CIC y bases intercambiables. Los valores promedio, máximo y mínimo fueron pH 5.78, 8.15 y 3.28; MO 1.58, 3.02 y 0.65%; N inorgánico 22.5, 43.6 y 3.5 mg kg-1; P Olsen 32.5, 67.4 y 1.4 mg kg‑1; K 0.45, 0.80 y 0.10 cmolc kg-1, respectivamente. La CE promedio fue 1.39 dS m-1 e indica que no existen problemas de salinidad. El 73% de los sitios fueron de textura arenosa a franco. El índice de calidad del suelo (SQI por su nombre en inglés) indica que la cuenca tiene un nivel de fertilidad medio, SQI promedio de 0.64; el 17% de los sitios tuvieron una fertilidad baja con pH entre 3.28-5.40, MO 0.81-1.20%, N 10-20 y P 5-10 mg kg-1; 42% media, pH 6.41-7.30, MO 2.01‑2.50, N 40-60 y P 15-20 mg kg-1; 36% moderadamente alta, y 5% alta con pH 8.20-8.80, MO 3.01-4.00, N 100-150 y P 25-35 mg kg-1. La distribución del SQI demuestra que en la llanura superior los suelos son de fertilidad baja a media, en la llanura intermedia y baja son de fertilidad media a alta, y en las partes de menor altura, la fertilidad está limitada por la interacción entre el sistema continental y el marino que salinizan los suelos.

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“…Therefore, statisticians and breeders are continuously putting effort to develop an effective model to select superior genotypes based on multiple traits. In this regard, initially genotype by trait (GT) analysis was proposed to understand the relationship among traits and genotypes (Yan and Rajcan 2002) and was utilized by many breeders in cereals as well as in other crops (Rubio et al 2004;Oladejo et al 2011;Legesse et al 2013;Paramesh et al 2016). However, this GT biplot model cannot show the strengths and weaknesses of a genotype, hence deprives of providing a decisive power of selection or rejection of given genotype (Yan et al 2019).…”

Section: Selection Of the Best Genotype Based On Multiple Traitsmentioning

confidence: 99%

Selection of Wheat Ideotype Based on Multiple Traits using Genotype by Yield-Trait Approach

Faheem¹

2021

IJAB

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In plant breeding, a novel genotype-by-yield trait (GYT) biplot approach was introduced to select superior genotypes based on multiple traits. The present study demonstrated the application of the GYT biplot model to evaluate the superior wheat advanced lines from a panel of 24 genotypes to select the ideotype for end users. Results show that the genotype-by-trait (GT) biplot covered 57% of the total variation of the data to reveal that grain yield was strongly associated with 1000-grain weight and grain width. In contrast, the GYT biplot explained 90.2% of the total variation which was significantly much higher than GT biplot. According to tester vector view of GYT biplot almost all the yield trait combinations were associated with each other at different degree of association; whereas the genotypes present within the acute angles of tester vectors (yield trait combinations) had the trait profile contributed positively towards grain yield. The polygon biplot of GYT had eight sectors, out of which only three had the yield trait combinations. The eight genotypes were the polygon vertex among which the advanced line DF1906 of first sector was designated as the best genotype for spike length, number of spikelets per spike, grain weight per spike and number of grains per spike. Additionally, the DF1912 of second sector was early maturing coupled with high 1000-grain weight while DF1917 of third sector had short stature and gave the highest harvest index. The average tester coordination (ATC) biplot grouped 13 genotypes as superior and nine as inferior genotypes and recommended two advanced lines DF1912 and DF1917 as ideotype based on balanced traits profile. These findings strengthened the argument that the GYT biplot analysis is better than other selection indices and guaranteed the selection of superior genotypes and rejection of inferior ones based on multiple traits yield combinations. © 2021 Friends Science Publishers

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Yield and leaf nutrient concentrations of common bean genotypes as influenced by aluminium toxicity under acidic soils

Cited by 4 publications

References 35 publications

Screening of Dolichos bean (Lablab purpureus (L.) Sweet) genotypes for aluminium tolerance

Screening of Dolichos bean (Lablab purpureus (L.) Sweet) genotypes for aluminium tolerance

Fertilidad e índice de calidad del suelo de la cuenca del río San Pedro en Nayarit

Selection of Wheat Ideotype Based on Multiple Traits using Genotype by Yield-Trait Approach

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