Abstract
Detecting gene-gene interaction in complex diseases is a major challenge for common disease genetics. Most interaction detection approaches use disease-marker associations and such methods have low power and unknown reliability in real data. We developed and tested a powerful linkage-analysis-based gene-gene interaction detection strategy based on conditioning the family data on a known disease-causing allele or disease-associated marker allele. We computer-generated multipoint linkage data for a disease caused by two epistatically interacting loci (A and B). We examined several two-locus epistatic inheritance models: dominant-dominant, dominant-recessive, recessive-dominant, recessive-recessive. At one of the loci (A), there was a known disease-related allele. We stratified the family data on the presence of this allele, eliminating family members who were without it. This elimination step has the effect of raising the “penetrance” at the second locus (B). We then calculated the lod score at the second locus (B) and compared the pre- and post-stratification lod scores at B. A positive difference indicated interaction. We also examined if it was possible to detect interaction with locus B based on a disease-marker association (instead of an identified disease allele) at locus A. We also tested whether the presence of genetic heterogeneity would generate false positive evidence of interaction. The power to detect interaction for a known disease allele was 60–90%. The probability of false positives, based on heterogeneity, was low. Decreasing linkage disequilibrium between the disease and marker at locus A decreased the likelihood of detecting interaction. The allele frequency of the associated marker made little difference to the power.
Highlights
It is clear that the expression of common disease depends on the interaction of multiple loci
One could conceivably do a pair-wise test of all single nucleotide polymorphism (SNP) in a Genome Wide Association Studies (GWAS) to search for an association but achieving a result with enough statistical significance to survive a correction for the number of tests would be difficult
We recently showed how linkage analysis could be used to both prove the existence of gene-gene interaction and uncover additional loci that contribute to disease [3]
Summary
It is clear that the expression of common disease depends on the interaction of multiple loci. The technique of choice for identifying disease loci has been association analysis, Genome Wide Association Studies (GWAS). These studies, which usually involve thousands, if not tens of thousands of subjects, assume that finding highly significant statistical differences between marker allele frequencies in case and control populations would guarantee that a gene strongly influencing disease expression would be discovered. Gene-gene interaction is viewed as critical for understanding common disease expression, the statistical tests used to detect gene-gene interaction from association data are weak. There are several current techniques to detect interaction from association data. The rational alternative is to choose loci that show association by themselves and test for interaction. There are data-mining approaches and methods that look for all combinations of alleles that appear to influence disease expression [1]
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