Impact of temporal variation on design and analysis of mouse knockout phenotyping studies.

Natasha A Karp,Richard F Mott,Anneliese O Speak,Yann Hérault,Jacqueline K White,Martin Hrabé De Angelis,David J Adams,Georgios V Gkoutos

doi:10.1371/journal.pone.0111239

Abstract

A significant challenge facing high-throughput phenotyping of in-vivo knockout mice is ensuring phenotype calls are robust and reliable. Central to this problem is selecting an appropriate statistical analysis that models both the experimental design (the workflow and the way control mice are selected for comparison with knockout animals) and the sources of variation. Recently we proposed a mixed model suitable for small batch-oriented studies, where controls are not phenotyped concurrently with mutants. Here we evaluate this method both for its sensitivity to detect phenotypic effects and to control false positives, across a range of workflows used at mouse phenotyping centers. We found the sensitivity and control of false positives depend on the workflow. We show that the phenotypes in control mice fluctuate unexpectedly between batches and this can cause the false positive rate of phenotype calls to be inflated when only a small number of batches are tested, when the effect of knockout becomes confounded with temporal fluctuations in control mice. This effect was observed in both behavioural and physiological assays. Based on this analysis, we recommend two approaches (workflow and accompanying control strategy) and associated analyses, which would be robust, for use in high-throughput phenotyping pipelines. Our results show the importance in modelling all sources of variability in high-throughput phenotyping studies.

Highlights

Phenotyping, the process by which an organism’s observable characteristics are measured, is an essential component of biological research
We show that unexpectedly large batch-to-batch fluctuations in the control data, cause false positive significant phenotype calls when mice are phenotyped across only a few batches
Investigating reproducibility issues At Wellcome Trust Sanger Institute (WTSI), we have found instances where phenotype calls that were significant according to either the reference range (RR) and mixed model (MM) criteria were not reproducible

Summary

Introduction

Phenotyping, the process by which an organism’s observable characteristics are measured, is an essential component of biological research. The mouse is the premier model organism for understanding gene function in development and disease. The International Mouse Phenotyping Consortium (IMPC) [4] aims to phenotype knockouts for all mouse protein coding genes, building on the large collection of targeted alleles in C57BL/6N embryonic stem cells available from the International Knockout Mouse Consortium [5,6,7]. The IMPC has developed a central resource (www.mousephenotype.org) to disseminate and share all animal, experimental and phenotypic data from every mutant line analysed. These data can be mined to determine which factors influence phenotyping experiments and whether different workflows produce comparable results

Methods

Results

Conclusion