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Accelerating Tomato Breeding by Exploiting Genomic Selection Approaches

Elisa Cappetta, Giuseppe Andolfo, Antonio Di Matteo, Amalia Barone, Luigi Frusciante, Maria Raffaella Ercolano

2020Plants58 citationsDOIOpen Access PDF

Abstract

unit of time and reduce the generation interval by utilizing genome-wide markers in breeding programs. It has emerged as a valuable method for improving complex traits that are controlled by many genes with small effects. GS enables the prediction of the breeding value of candidate genotypes for selection. In this work, we address important issues related to GS and its implementation in the plant context with special emphasis on tomato breeding. Genomic constraints and critical parameters affecting the accuracy of prediction such as the number of markers, statistical model, phenotyping and complexity of trait, training population size and composition should be carefully evaluated. The comparison of GS approaches for facilitating the selection of tomato superior genotypes during breeding programs is also discussed. GS applied to tomato breeding has already been shown to be feasible. We illustrated how GS can improve the rate of gain in elite line selection, and descendent and backcross schemes. The GS schemes have begun to be delineated and computer science can provide support for future selection strategies. A new promising breeding framework is beginning to emerge for optimizing tomato improvement procedures.

Topics & Concepts

Genomic selectionSelection (genetic algorithm)BackcrossingGenetic gainContext (archaeology)BiologyTraitPlant breedingPopulationBiotechnologyMarker-assisted selectionQuantitative trait locusComputer scienceGeneticsMachine learningGenotypeGeneGenetic variationAgronomyDemographyPaleontologyProgramming languageSociologySingle-nucleotide polymorphismGenetic and phenotypic traits in livestockGenetics and Plant BreedingGenetic Mapping and Diversity in Plants and Animals