Causal inference for the covariance between breeding values under identity disequilibrium

Cantet, Rodolfo Juan Carlos; Angarita-Barajas, Belcy K; Forneris, Natalia Soledad; Munilla, S.

doi:10.1186/s12711-022-00750-6

Cited by 2 publications

(1 citation statement)

References 59 publications

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“…Second, a population of N genetically related individuals has the N (1 + q) × N (1 + q) Kronecker product covariance matrix G G G t = G G G A A A t , where A A A t is the symmetric N × N additive genetic relationship matrix (Ch. 26, Lynch and Walsh, 1998;Cantet et al, 2022;Mathew et al, 2018), and where is the Kronecker product operator. The Kronecker product simply means that each of the elements in G G G are multiplied by A A A t .…”

Section: Covariance Structuresmentioning

confidence: 99%

Microevolutionary system identification and climate response predictions by use of BLUP prediction error method

Ergon

2023

MIC

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Animals and other organisms in wild populations may adjust to climate change by means of plasticity and evolution, and it is an important task to find the contributions from each of these effects. Attempts to solve this disentanglement problem by use of best linear unbiased prediction (BLUP) and restricted maximum likelihood (REML) methods, as borrowed from the field of domestic breeding, have been criticized because of errors in the variances of the predicted random effects. A primary purpose of this article is to show how the problem can be solved by use of BLUP in a prediction error method (PEM), borrowed from the well-established engineering system identification discipline.The PEM approach is first to collect environmental input data u t and mean phenotypic output data y t , as well as individual phenotypic and fitness data, for consecutive generations from t = 1 to T . A reaction norm model of the evolutionary system is then used to find predictions y t , and the parameters in this model, together with environmental reference values and initial state variables, are finally tuned such that T t=1 y t − y t 2 is minimized.The main contribution is the use a dynamical BLUP model in a BLUP/PEM method for parameter estimation and mean reaction norm trait predictions. The model is dynamical in the sense that the incidence matrix in an underlying linear mixed model, as well as the corresponding residual covariance matrix, are functions of time. For comparisons, a selection gradient prediction model as presented in Ergon (2022a,b) is also used in a GRAD/PEM method. The advantages of the BLUP/PEM method are that it can utilize genetic relationship information, and that it produces better estimates of environmental reference values. The treatment is limited to multiple-input single-output (MISO) systems. Generations are assumed to be non-overlapping.Simulation examples show that BLUP/PEM may find good estimates of environmental reference values and initial state variables, as well as good mean reaction norm trait predictions. Details for use of additional fixed effects, as well as appropriate methods for model validation remain to be worked out.

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Section: Covariance Structuresmentioning

confidence: 99%

Microevolutionary system identification and climate response predictions by use of BLUP prediction error method

Ergon

2023

MIC

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Causal inference and GWAS: Rubin, Pearl, and Mendelian randomization

Cantet,

Jensen

2024

J Animal Breeding Genetics

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Although Genome Wide Analysis (GWAS) have been widely used to understand the genetic architecture of complex quantitative traits, interpreting their results in terms of the biological processes that determine those traits has been difficult or even lacking, because of the variability in responses to the tests of hypotheses within a trait, species, and breed or cross, and the lack of follow‐up studies. It is then essential employing appropriate statistical tests that point out to the causal genes responsible of the relevant fraction of the genetic variability observed. We briefly review the main theoretical aspects of the two schools of causal inference (Rubin's Causal Model, RCM, and Pearl's causal inference, PCI). RCM approachs the hypothesis testing from a randomization perspective by considering a wider space of the observation, i.e. the “potential outcomes”, rather than the narrower space that results from defining “treatment” effects after observing the data. Next, we discuss the assumptions involved to meet the requirements of randomization for RCM with observational data (non‐designed experiments) with special emphasis on the Stable Unit Treatment Analysis (SUTVA). Due to the presence of “confounders” (i.e. systematic fixed effects, environmental permanent effects, interaction among genes, etc.), causal average treatment effects are viewed through the familiar lens of normal linear (or mixed) models. To overcome the difficulties of association analyses, a tests of causal effects is introduced using independent predicted residual breeding values from animal models of genetic evaluation that avoids the effects of population structure and confounder effects. An independent section discusses the issue of whether the additive effects defined at the “gene” level by R. A. Fisher and popularized in D. S. Falconer's textbook of quantitative genetics can be termed causal from either RCM or PCI.

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Causal inference for the covariance between breeding values under identity disequilibrium

Cited by 2 publications

References 59 publications

Microevolutionary system identification and climate response predictions by use of BLUP prediction error method

Microevolutionary system identification and climate response predictions by use of BLUP prediction error method

Causal inference and GWAS: Rubin, Pearl, and Mendelian randomization

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