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Effects of single SNPs, haplotypes, and whole-genome LD maps on accuracy of association mapping

Effects of single SNPs, haplotypes, and whole-genome LD maps on accuracy of association mapping
Effects of single SNPs, haplotypes, and whole-genome LD maps on accuracy of association mapping
We describe an association mapping approach that utilizes linkage disequilibrium (LD) maps in LD units (LDU). This method uses composite likelihood to combine information from all single marker tests, and applies a model with a parameter for the location of the causal polymorphism. Previous analyses of the poor drug metabolizer phenotype provided evidence of the substantial utility of LDU maps for disease gene association mapping. Using LDU locations for the 27 single nucleotide polymorphisms (SNPs) flanking the CYP2D6 gene on chromosome 22, the most common functional polymorphism within the gene was located at 15 kb from its true location. Here, we examine the performance of this mapping approach by exploiting the high-density LDU map constructed from the HapMap data. Expressing the locations of the 27 SNPs in LDU from the HapMap LDU map, analysis yielded an estimated location that is only 0.3 kb away from the CYP2D6 gene. This supports the use of the high marker density HapMap-derived LDU map for association mapping even though it is derived from a much smaller number of individuals compared to the CYP2D6 sample. We also examine the performance of 2-SNP haplotypes. Using the same modelling procedures and composite likelihood as for single SNPs, the haplotype data provided much poorer localization compared to single SNP analysis. Haplotypes generate more autocorrelation through multiple inclusions of the same SNPs, which could inflate significance in association studies. The results of the present study demonstrate the great potential of the genome HapMap LDU maps for high-resolution mapping of complex phenotypes.
chromosomes, analysis, chromosome mapping, phenotype, drug, cytochrome p-450 cyp2d6, genetic predisposition to disease, metabolic detoxication, haplotypes, genome, humans, genetic, human, pair 22, research support, research, models, polymorphism, single nucleotide, chi-square distribution, genetics, disease, linkage disequilibrium
0741-0395
179-188
Maniatis, Nikolas
369fb005-aae0-4243-807b-b42af088debd
Collins, Andrew
7daa83eb-0b21-43b2-af1a-e38fb36e2a64
Morton, Newton E.
c668e2be-074a-4a0a-a2ca-e8f51830ebb7
Maniatis, Nikolas
369fb005-aae0-4243-807b-b42af088debd
Collins, Andrew
7daa83eb-0b21-43b2-af1a-e38fb36e2a64
Morton, Newton E.
c668e2be-074a-4a0a-a2ca-e8f51830ebb7

Maniatis, Nikolas, Collins, Andrew and Morton, Newton E. (2007) Effects of single SNPs, haplotypes, and whole-genome LD maps on accuracy of association mapping. Genetic Epidemiology, 31 (3), 179-188. (doi:10.1002/gepi.20199).

Record type: Article

Abstract

We describe an association mapping approach that utilizes linkage disequilibrium (LD) maps in LD units (LDU). This method uses composite likelihood to combine information from all single marker tests, and applies a model with a parameter for the location of the causal polymorphism. Previous analyses of the poor drug metabolizer phenotype provided evidence of the substantial utility of LDU maps for disease gene association mapping. Using LDU locations for the 27 single nucleotide polymorphisms (SNPs) flanking the CYP2D6 gene on chromosome 22, the most common functional polymorphism within the gene was located at 15 kb from its true location. Here, we examine the performance of this mapping approach by exploiting the high-density LDU map constructed from the HapMap data. Expressing the locations of the 27 SNPs in LDU from the HapMap LDU map, analysis yielded an estimated location that is only 0.3 kb away from the CYP2D6 gene. This supports the use of the high marker density HapMap-derived LDU map for association mapping even though it is derived from a much smaller number of individuals compared to the CYP2D6 sample. We also examine the performance of 2-SNP haplotypes. Using the same modelling procedures and composite likelihood as for single SNPs, the haplotype data provided much poorer localization compared to single SNP analysis. Haplotypes generate more autocorrelation through multiple inclusions of the same SNPs, which could inflate significance in association studies. The results of the present study demonstrate the great potential of the genome HapMap LDU maps for high-resolution mapping of complex phenotypes.

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More information

Published date: 6 February 2007
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Keywords: chromosomes, analysis, chromosome mapping, phenotype, drug, cytochrome p-450 cyp2d6, genetic predisposition to disease, metabolic detoxication, haplotypes, genome, humans, genetic, human, pair 22, research support, research, models, polymorphism, single nucleotide, chi-square distribution, genetics, disease, linkage disequilibrium
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Identifiers

Local EPrints ID: 60021
URI: http://eprints.soton.ac.uk/id/eprint/60021
DOI: doi:10.1002/gepi.20199
ISSN: 0741-0395
PURE UUID: d29e91f0-5f86-4820-a504-c55b631b76c3
ORCID for Andrew Collins: ORCID iD orcid.org/0000-0001-7108-0771

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Date deposited: 08 Sep 2008
Last modified: 16 Mar 2024 02:42

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Author: Nikolas Maniatis
Author: Andrew Collins ORCID iD
Author: Newton E. Morton

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