Abstract
Parallel meta-analysis is a popular approach for increasing the power to detect genetic effects in genome-wide association studies across multiple cohorts. Consortia studying the genetics of behavioral phenotypes are oftentimes faced with systematic differences in phenotype measurement across cohorts, introducing heterogeneity into the meta-analysis and reducing statistical power. This study investigated integrative data analysis (IDA) as an approach for jointly modeling the phenotype across multiple datasets. We put forth a bi-factor integration model (BFIM) that provides a single common phenotype score and accounts for sources of study-specific variability in the phenotype. In order to capitalize on this modeling strategy, a phenotype reference panel was utilized as a supplemental sample with complete data on all behavioral measures. A simulation study showed that a mega-analysis of genetic variant effects in a BFIM were more powerful than meta-analysis of genetic effects on a cohort-specific sum score of items. Saving the factor scores from the BFIM and using those as the outcome in meta-analysis was also more powerful than the sum score in most simulation conditions, but a small degree of bias was introduced by this approach. The reference panel was necessary to realize these power gains. An empirical demonstration used the BFIM to harmonize aggression scores in 9-year old children across the Netherlands Twin Register and the Child and Adolescent Twin Study in Sweden, providing a template for application of the BFIM to a range of different phenotypes. A supplemental data collection in the Netherlands Twin Register served as a reference panel for phenotype modeling across both cohorts. Our results indicate that model-based harmonization for the study of complex traits is a useful step within genetic consortia.
Highlights
Multi-study consortia and large-scale meta-analyses are the status quo for genome-wide analyses of complex traits (Evangelou and Ioannidis, 2013; Pedersen et al, 2013; Reitveld et al, 2014)
The factor score meta-analysis resulted in power gains compared to sum score meta-analysis when the bi-factor integration model (BFIM) is correctly specified, there was a small amount of bias in the estimates
A bi-factor model for data integration was proposed that was designed to adjust for measurement differences across multiple cohorts such as the use of different questionnaires
Summary
Multi-study consortia and large-scale meta-analyses are the status quo for genome-wide analyses of complex traits (Evangelou and Ioannidis, 2013; Pedersen et al, 2013; Reitveld et al, 2014). Combining data from different studies presents an additional challenge when behavioral, psychological, or other complex phenotypes have been measured by different means across the studies. The current paper utilizes an integrative data analysis (IDA) framework for phenotype harmonization that can provide benefits for consortium-based GWAS meta-analyses by improving precision in phenotype measurement (Curran and Hussong, 2009). To quantify these benefits, we conduct a simulation study to assess the power to detect the effect of a genetic variant on a behavioral outcome that is modeled by IDAbased phenotype harmonization. We illustrate the IDA approach to harmonizing behavioral phenotypes
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