Searching for causal networks involving latent variables in complex traits: Application to growth, carcass, and meat quality traits in pigs.

Structural equation models (SEQM) can be used to model causal relationships between multiple variables in multivariate systems. Among the strengths of SEQM is its ability to consider causal links between latent variables. The use of latent variables allows modeling complex phenomena while reducing at the same time the dimensionality of the data. One relevant aspect in the quantitative genetics context is the possibility of correlated genetic effects influencing sets of variables under study. Under this scenario, if one aims at inferring causality among latent variables, genetic covariances act as confounders if ignored. Here we describe a methodology for assessing causal networks involving latent variables underlying complex phenotypic traits. The first step of the method consists of the construction of latent variables defined on the basis of prior knowledge and biological interest. These latent variables are jointly evaluated using confirmatory factor analysis. The estimated factor scores are then used as phenotypes for fitting a multivariate mixed model to obtain the covariance matrix of latent variables conditional on the genetic effects. Finally, causal relationships between the adjusted latent variables are evaluated using different SEQM with alternative causal specifications. We have applied this method to a data set with pigs for which several phenotypes were recorded over time. Five different latent variables were evaluated to explore causal links between growth, carcass, and meat quality traits. The measurement model, which included 5 latent variables capturing the information conveyed by 19 different phenotypic traits, showed an acceptable fit to data (e.g., χ/df = 1.3, root-mean-square error of approximation = 0.028, standardized root-mean-square residual = 0.041). Causal links between latent variables were explored after removing genetic confounders. Interestingly, we found that both growth (-0.160) and carcass traits (-0.500) have a significant negative causal effect on quality traits (-value ≤ 0.001). This result may have important implications for strategies for pig production improvement. More generally, the proposed method allows further learning regarding phenotypic causal structures underlying complex traits in farm species.

[1]  T. Haavelmo The Statistical Implications of a System of Simultaneous Equations , 1943 .

[2]  L. Tucker,et al.  A reliability coefficient for maximum likelihood factor analysis , 1973 .

[3]  D. A. Kenny,et al.  Correlation and Causation , 1937, Wilmott.

[4]  Kenneth A. Bollen,et al.  Structural Equations with Latent Variables , 1989 .

[5]  Peter M. Bentler,et al.  EQS : structural equations program manual , 1989 .

[6]  P. Bentler,et al.  Comparative fit indexes in structural models. , 1990, Psychological bulletin.

[7]  P. Games Correlation and Causation: A Logical Snafu , 1990 .

[8]  J. H. Steiger Structural Model Evaluation and Modification: An Interval Estimation Approach. , 1990, Multivariate behavioral research.

[9]  R. Fernando,et al.  Genetic analyses of growth, real-time ultrasound, carcass, and pork quality traits in Duroc and Landrace pigs: II. Heritabilities and correlations. , 1992, Journal of animal science.

[10]  A. Satorra,et al.  Corrections to test statistics and standard errors in covariance structure analysis. , 1994 .

[11]  J. Pearl Causality: Models, Reasoning and Inference , 2000 .

[12]  B. Shipley Cause and correlation in biology , 2000 .

[13]  E. Huff-Lonergan,et al.  Selection for lean growth efficiency in Duroc pigs influences pork quality. , 2001, Journal of animal science.

[14]  Structural Equation Modeling: From biological hypotheses to structural equation models: the imperfection of causal translation , 2003 .

[15]  Daniel Gianola,et al.  Quantitative Genetic Models for Describing Simultaneous and Recursive Relationships Between Phenotypes This article is dedicated to Arthur B. Chapman, teacher and mentor of numerous animal breeding students and disciple and friend of Sewall Wright. , 2004, Genetics.

[16]  D. Gianola,et al.  A structural equation model for describing relationships between somatic cell score and milk yield in dairy goats. , 2006, Journal of animal science.

[17]  D Gianola,et al.  Inferring relationships between somatic cell score and milk yield using simultaneous and recursive models. , 2007, Journal of dairy science.

[18]  R. Bates,et al.  Quantitative trait locus mapping in an F2 Duroc x Pietrain resource population: II. Carcass and meat quality traits. , 2008, Journal of animal science.

[19]  G. Rosa,et al.  Quantitative trait loci mapping in an F2 Duroc x Pietrain resource population: I. Growth traits. , 2008, Journal of animal science.

[20]  K. Weigel,et al.  Exploring Biological Relationships Between Calving Traits in Primiparous Cattle with a Bayesian Recursive Model , 2009, Genetics.

[21]  Jarrod D. Hadfield,et al.  MCMC methods for multi-response generalized linear mixed models , 2010 .

[22]  Guilherme J M Rosa,et al.  Searching for Recursive Causal Structures in Multivariate Quantitative Genetics Mixed Models , 2010, Genetics.

[23]  Xiao-Lin Wu,et al.  Inferring causal phenotype networks using structural equation models , 2011, Genetics Selection Evolution.

[24]  Daniel Gianola,et al.  "Likelihood, Bayesian, and Mcmc Methods in Quantitative Genetics" , 2010 .

[25]  Yves Rosseel,et al.  lavaan: An R Package for Structural Equation Modeling , 2012 .

[26]  V. Planchon,et al.  Structural equation models to estimate risk of infection and tolerance to bovine mastitis , 2013, Genetics Selection Evolution.

[27]  J. Pearl,et al.  EIGHT MYTHS ABOUT CAUSALITY AND STRUCTURAL EQUATION MODELS , 2013 .