10.11588/data/X9UEHBKabisch, MariaMariaKabischMolecular Genetics of Breast Cancer, German Cancer Research Center (DKFZ), Heidelberg, Germany, and Institute of Medical Biometry and Informatics, University of Heidelberg, Heidelberg, GermanyHamann, UteUteHamannMolecular Genetics of Breast Cancer, German Cancer Research Center (DKFZ), Heidelberg, GermanyLorenzo Bermejo, JustoJustoLorenzo Bermejo0000-0002-6568-5333Institute of Medical Biometry and Informatics, University of Heidelberg, Heidelberg, GermanyImputation of Missing Genotypes within LD-Blocks Relying on the Basic Coalescent and Beyond [Source Code]heiDATA2018Medicine, Health and Life SciencesGenotype imputationCoalescent theoryLinkage disequilibriumImputation accuracyPopulation growthPopulation structureLorenzo Bermejo, JustoJustoLorenzo BermejoInstitute of Medical Biometry and Informatics, University of Heidelberg, Heidelberg, Germany2018-07-202018-10-1510.1186/s12864-017-4208-21156726411830421095292244085application/x-sas-syntaxapplication/x-sas-syntaxapplication/x-sas-syntaxapplication/x-sas-syntaxapplication/x-sas-syntaxapplication/pdf1.0Background <p /> <p /> Genotypes not directly measured in genetic studies are often imputed to improve statistical power and to increase mapping resolution. The accuracy of standard imputation techniques strongly depends on the similarity of linkage disequilibrium (LD) patterns in the study and reference populations. Here we develop a novel approach for genotype imputation in low-recombination regions that relies on the coalescent and permits to explicitly account for population demographic factors.<p /> To test the new method, study and reference haplotypes were simulated and gene trees were inferred under the basic coalescent and also considering population growth and structure. The reference haplotypes that first coalesced with study haplotypes were used as templates for genotype imputation. Computer simulations were complemented with the analysis of real data. Genotype concordance rates were used to compare the accuracies of coalescent-based and standard (IMPUTE2) imputation.<p /> <p /> Results<p /> <p /> Simulations revealed that, in LD-blocks, imputation accuracy relying on the basic coalescent was higher and less variable than with IMPUTE2. Explicit consideration of population growth and structure, even if present, did not practically improve accuracy. The advantage of coalescent-based over standard imputation increased with the minor allele frequency and it decreased with population stratification. Results based on real data indicated that, even in low-recombination regions, further research is needed to incorporate recombination in coalescence inference, in particular for studies with genetically diverse and admixed individuals.<p /> <p /> Conclusions<p /> <p /> To exploit the full potential of coalescent-based methods for the imputation of missing genotypes in genetic studies, further methodological research is needed to reduce computer time, to take into account recombination, and to implement these methods in user-friendly computer programs. Here we provide reproducible code which takes advantage of publicly available software to facilitate further developments in the field.