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Acknowledgements
This work is supported by European Research Council grants FP7/2007-2013 ERC agreement no[294519]-PSARPS (Y.B., N.K., I.G., I.J., T.S., and S.Y.) and REFINE (H.W.). We thank the International Mouse Phenotyping Consortium (IMPC) and their Data Coordination Centre for the provision of phenotyping data sets.
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Integrated supplementary information
Supplementary Figure 1 The Random Lab Model.
The proposed Random Lab Model (RLM) analysis vs. the commonly-used Fixed Lab Model (FLM) standard analysis for a single laboratory experiment. The illustrated example represents a phenotyping experiment comparing two genotypes g' and g'' (e.g., a “knockout” mutant vs. its wildtype control) in a single laboratory l. The two models include the same effects (upper row), but in the RLM, the laboratory and therefore its interaction with the genotype are modeled as random (effects in red) rather than fixed (blue). bl is the contribution of laboratory specific to its measurement procedure, which is common to all animals from any genotype measured in lab l. cg'l and cg''l are the contributions of interactions of lab specifics with genotypes g' and g'' specific to measurement, which are common to all animals from same genotype measured in lab l. When phenotyping the two genotypes in the same laboratory, the laboratory effect cancels whether it is fixed or random. However, the random interaction effect are not the same, they do not cancel out, and because they are independent their variances sum up in the standard error (SE, bottom row) just as the individual animals effects do. Unlike the individual animal “noise”, it cannot be reduced by increasing the number of animals n, and it cannot be estimated in a single laboratory, and thus has to be imported from previous multi-lab experiments (GxL-adjustment). Larger SE increases the p-value and confidence interval, therefore requiring more power to show a difference, but also ensures results will be replicated in other laboratories.
Supplementary Figure 2 A proposed framework for practical community implementation of GxL-adjustment.
Researchers in a local laboratory Labl (left) perform a local phenotyping experiment comparing genotypes g' and g''. They search an online community database (right) and retrieve the current estimate of the interaction variability σ2G × L for the phenotype p of interest, estimated in other genotypes g1–g4 across other laboratories Lab1–Lab3. The researchers use this σ2G × L to GxL-adjust their local statistical analysis of p-value and confidence interval of the genotype effect, deriving a conclusion that is more likely to replicate in other laboratories. The researchers also submit their local data to the community database, thus enriching it and enabling an updated estimation of σ2G × L for future users.
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Kafkafi, N., Golani, I., Jaljuli, I. et al. Addressing reproducibility in single-laboratory phenotyping experiments. Nat Methods 14, 462–464 (2017). https://doi.org/10.1038/nmeth.4259
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DOI: https://doi.org/10.1038/nmeth.4259
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