Abstract
Key messageA new R-software procedure for fixed/random Diallel models was developed. We eased the diallel schemes approach by considering them as specific cases with different parameterisations of a general linear model.Diallel experiments are based on a set of possible crosses between some homozygous (inbred) lines. For these experiments, six main diallel models are available in literature, to quantify genetic effects, such as general combining ability (GCA), specific combining ability (SCA), reciprocal (maternal) effects and heterosis. Those models tend to be presented as separate entities, to be fitted by using specialised software. In this manuscript, we reinforce the idea that diallel models should be better regarded as specific cases (different parameterisations) of a general linear model and might be fitted with general purpose software facilities, as used for all other types of linear models. We start from the estimation of fixed genetical effects within the R environment and try to bridge the gap between diallel models, linear models and ordinary least squares estimation (OLS). First, we review the main diallel models in literature. Second, we build a set of tools to enable geneticists, plant/animal breeders and students to fit diallel models by using the most widely known R functions for OLS fitting, i.e. the ‘lm()’ function and related methods. Here, we give three examples to show how diallel models can be built by using the typical process of GLMs and fitted, inspected and processed as all other types of linear models in R. Finally, we give a fourth example to show how our tools can be also used to fit random/mixed effect diallel models in the Bayesian framework.
Highlights
A diallel experiment is based on a set of possible crosses between some homozygous lines and it is usually aimed at quantifying genetic effects, such as: 1. General combining ability (GCA), that is the discrepancy from the average performance of two parental lines in a hybrid combination
We used Gaussian priors with means equal to 0 and precisions equal to 0.0001
We have tried to reinforce the idea that all diallel models are special cases of the same general linear model
Summary
A diallel experiment is based on a set of possible crosses between some homozygous (inbred) lines and it is usually aimed at quantifying genetic effects, such as: 1. General combining ability (GCA), that is the discrepancy from the average performance of two parental lines in a hybrid combination. A diallel experiment is based on a set of possible crosses between some homozygous (inbred) lines and it is usually aimed at quantifying genetic effects, such as: 1. General combining ability (GCA), that is the discrepancy from the average performance of two parental lines in a hybrid combination. Based on Sprague and Tatum (1942), GCA mainly depends on the additive effects. The assessment of genetic effects is very useful in plant breeding; for example, a high GCA value can predict a flow of several desirable additive genes from parents to offspring (Franco et al 2001). The same authors showed that a high GCA estimate may indicate high heritability and low environmental effects, which may result in low gene interactions, high selection response and large adaptability. Genetic effects were determined to describe nonadditive gene effects (Singh et al 1986; Chigeza et al 2014) and to identify heterotic groups or patterns (Napolitano et al 2020)
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