Estimación de la interacción genotipo-ambiente en tomate (Solanum lycopersicum L.) con el modelo AMMI

Aspeytia, David Sánchez; Escalante, Fernando Borrego; Villa, Víctor Manuel Zamora; Chaparro, Juan David Sánchez; Castillo, Francisco Daniel Hernández

doi:10.29312/remexca.v6i4.617

Cited by 6 publications

(9 citation statements)

References 11 publications

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“…In our study, the same genotypes showed highly significant differential responses in the tested environments; in particular, the lycopene content was favored in the environments with an average temperature of 22°C, such as Palmira and Montelindo. Likewise, Sánchez et al (2015) found that high temperatures in three tested environments significantly influenced lycopene and vitamin C contents in tomato genotypes. Moreover, according to Luna-Guevara and Delgado-Alvarado ( 2014), precursors of lycopene are inhibited below 12°C and above 32°C, with an optimal range between 22 and 25°C for the production of this pigment.…”

Section: Analysis Of the Genotype-environment Interaction With The Ammi Modelmentioning

confidence: 89%

“…The authors found significant G×E interactions for lycopene, beta-carotene, and ascorbic acid contents, while no significant differences were found for number of locules per fruit, pericarp thickness, soluble solids, or pH. Similarly, Cebolla-Cornejo et al (2011);Sánchez et al (2015); and Savale and Patel (2017) among others also reported significant differences in quality traits because of GxE interactions. By contrast, Patel et al (2017) found that the genotype x environments interaction was highly significant for all characteristics except fruit pH, reducing sugar (%), total sugar (%), lycopene content (mg/100 g) and viscosity (cSt) with a stability analysis of quality parameters in tomatoes (Solanum lycopersicum L.).…”

Section: N N=1mentioning

confidence: 94%

“…Environmental factors play a relevant role in gene regulation and can affect the expression of genes that control a trait of interest, as well as phenotypic expressions across localities (Panthee et al, 2012). The creation of new genotypes requires the assessment of different environments and measuring the magnitude of genotype-environment interactions, providing insight into the phenotypic stability of genotypes in response to environmental fluctuations (Sánchez et al, 2015). Crossa (1990) suggested that the application of multivariate methods is useful for exploring genotype-environment interactions and recommended techniques such as principal component analysis (PCA), clustering analysis, and Additive Main Effect and Multiplicative Interaction (AMMI) method.…”

Section: Introductionmentioning

confidence: 99%

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Estimating genotype-environment interactions for internal fruit quality traits in cherry tomatoes

Ceballos-Aguirre¹,

Cabrera²,

Morillo-Coronado³

2020

Rev. Colomb. Cienc. Hortic.

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Genotype-environment interactions (GEI) were assessed in 10 cherry tomato accessions in nine environments, including four artificial settings (0, 60 120, and 180 kg ha-1 of potassium) established on the experimental farms Montelindo (Palestina), Tesorito (Manizales), and CEUNP (Palmira) (Colombia). The plant material included 10 cherry tomato genotypes obtained from the germplasm bank at the Instituto Agronómico de Campinas and Tomato Genetics Resources Center (TGRC). A completely randomized block design with four blocks corresponding to the level of potassium fertilization was used (0, 60, 120, 180 kg ha-1); 0 kg ha-1 was the level reported for the soil. The effective size of the experiment unit was seven plants; the plot included the five central plants. A distance of 1.5 m between rows, 0.50 m between plants, and 2 m between blocks was used. The contents of soluble solids (°Brix), vitamin C (mg/100 g fresh weight), and lycopene (µg g-1 fresh weight) were assessed. The analysis of variance (ANOVA) showed significant differences (P<0.01) between the tomato genotypes, environments, and G×E interactions for the three assessed traits . The AMMI analysis identified similar and contrasting environments and determined the genotypes that contributed the most to the GEI. The environments with 120 and 180 kg ha-1 potassium favored the expression of vitamin C, while Palmira favored the lycopene content. The findings are useful for identifying optimal locations and elite genotypes that can be used as sources of variability in fruit quality improvement programs for cherry tomatoes.

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Section: Analysis Of the Genotype-environment Interaction With The Ammi Modelmentioning

confidence: 89%

Section: N N=1mentioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

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Estimating genotype-environment interactions for internal fruit quality traits in cherry tomatoes

Ceballos-Aguirre¹,

Cabrera²,

Morillo-Coronado³

2020

Rev. Colomb. Cienc. Hortic.

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“…The Fusarium fungus is recognized for its phytopathogenic ability, which is usually associated with vascular wilting (Forero-Reyes et al, 2018). The use of genotypes resistant or tolerant to the pathogen has been one of the tactics to minimize the fungus infection, since its presence, along with favorable environmental conditions, reduces tomato yields (Sánchez-Aspeytia et al, 2015). For this reason, different genotypes are used in order to fulfill the producer needs, including production increases, tolerance to environmental conditions (high temperature), pests and diseases (fungi, viruses, nematodes) (Rodríguez et al, 2004).…”

Section: Fully Bilingualmentioning

confidence: 99%

“…For this reason, different genotypes are used in order to fulfill the producer needs, including production increases, tolerance to environmental conditions (high temperature), pests and diseases (fungi, viruses, nematodes) (Rodríguez et al, 2004). Therefore, the objective of this study was to este hongo, ha sido el uso de genotipos resistentes o tolerantes al patógeno, ya que la presencia de este en adición a las condiciones climáticas favorables demerita el rendimiento (Sánchez-Aspeytia et al, 2015). Por ello que, de acuerdo a las necesidades del productor, se llegan a utilizar diferentes genotipos de acuerdo a sus necesidades como el incremento en la producción, tolerancia a condiciones ambientales (temperaturas altas), plagas y enfermedades (hongos, virus, nematodos) (Rodríguez et al, 2004).…”

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Wilt incidence in tomato genotypes (Solanum lycopersicum) in different production systems under shade mesh

Montiel-Peralta¹,

Ávila-Alistac²,

Montiel-Peralta³

et al. 2020

RMF

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El objetivo del trabajo fue identificar el agente asociado a la marchitez y evaluar la incidencia en nueve genotipos de jitomate comerciales: seis genotipos con crecimiento indeterminado (Cid, Sun 7705, Moctezuma, Cuauhtémoc, Ramsés y Aníbal) y tres de crecimiento determinado (Palomo, Pony express y Toro). Los genotipos se evaluaron en cuatro sistemas de producción en malla sombra: suelo con acolchado, y tezontle en bolsas de plástico polietileno de 37x37, 40x40 y 40x45 cm. La incidencia de marchitez se evaluó a 114 días en 3,476 plantas. De acuerdo a características morfológicas in vitro en medio PDA y cámara húmeda, de 18/20 plantas se aisló únicamente un hongo del género Fusarium y en 2/20 se obtuvieron aislados de Fusarium y Rhizoctonia solani. La mayor incidencia se observó en los genotipos Cid (20.1%), Moctezuma (22.4 %) y Sun 7705 (29.7%) y la menor en genotipos de crecimiento determinado. El sistema de producción en bolsas 37x37 cm presentó la mayor incidencia de marchitez (25.9%) con rendimiento de 4.3 t ha-1; mientras que en bolsas 40x45 cm la incidencia fue menor (4.7%). En los cuatro sistemas de producción, el menor rendimiento se obtuvo con el genotipo Sun 7705 con producción en rango de 59.7 - 70.6 t ha-1.

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Genotype-environment interaction for production characteristics in cherry tomato (Solanum spp.)

Ceballos-Aguirre

Cabrera

Morillo-Coronado

2021

Rev. Colomb. Cienc. Hortic.

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Much of the tomato diversity is found in cherry-type populations. There are promising wild cherry tomato species with good behavior in terms of yield and quality that can be produced with a minimum of agro-inputs. The genetic expression of genotypes is influenced by the optimal environment they can develop in. The genotype-environment interaction must be known to estimate the phenotypic adaptability in different environments. The objective of this research was to evaluate the genotype-environment interaction for 10 cherry tomato introductions in nine environments, four of which were artificial environments (0, 60, 120 and 180 kg ha-1 of potassium) established in natural environments on the Farms Montelindo, Tesorito and CEUNP. The experiment design used randomized complete blocks with four replicates; the experiment unit consisted of five effective plants per introduction. The evaluated variables were production per plant (PFT) (kg/pl), number of fruits per plant (NFT), and average fruit weight (AWF) (g/fruit). The genotype×environment interaction and the stability of the 10 genotypes were estimated with the AMMI multivariate model. The environments for T120K and T180K were optimal for the variables associated with production (PFT, NFT and AWF), with IAC1621, IAC426 and IAC1624 being the most promising genotypes per environment on the Farms Tesorito, Montelindo and CEUNP, respectively. The results are useful for the identification of genotypes in key locations for selection and evaluation in breeding programs.

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Estimación de la interacción genotipo-ambiente en tomate (Solanum lycopersicum L.) con el modelo AMMI

Cited by 6 publications

References 11 publications

Estimating genotype-environment interactions for internal fruit quality traits in cherry tomatoes

Estimating genotype-environment interactions for internal fruit quality traits in cherry tomatoes

Wilt incidence in tomato genotypes (Solanum lycopersicum) in different production systems under shade mesh

Genotype-environment interaction for production characteristics in cherry tomato (Solanum spp.)

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