Affected relative pairs and simultaneous search for two‐locus linkage in the presence of epistasis

It is commonly believed that multiple interacting genes increase the susceptibility of genetically complex diseases, yet few linkage analyses of human diseases scan for more than one locus at a time. To overcome some of the statistical and computational limitations of a simultaneous search for two disease susceptibility loci in the presence of epistasis, we developed new score statistics to simultaneously scan for two disease susceptibility loci in pedigree data. These model‐free score statistics are based on developments for model‐free maximum lod scores, which in turn are based on variance components for indicators of disease status. To overcome reduced power caused by many parameters in the general two‐locus model, we impose constraints on ratios of variance components, much like those used for robust single‐locus linkage statistics (e.g., minimax constraints). The resulting three‐degree of freedom score statistic, constrained as a one‐sided multivariate test, can be computed rapidly, making simultaneous search feasible for human genetic linkage studies. Furthermore, using recent developments to rapidly compute simulation P‐values for score statistics, it is feasible to empirically evaluate the statistical significance of the proposed score statistics. Application of these methods to two large studies of the genetic linkage of prostate cancer illuminates their strengths and limitations. The results provide weak suggestions for linkage of several pairs of chromosomal regions (chromosome pairs 1–21, 3–13, 5–9, and 14–19), all of which showed stronger linkage signals when the score statistics accounted for epistasis. These novel score statistics should prove useful for linkage studies of other complex human diseases. Genet. Epidemiol. 31, 2007. © 2007 Wiley‐Liss, Inc.

[1]  Jerzy K. Kulski,et al.  Blood pressure QTLs identified by genome-wide linkage analysis and dependence on associated phenotypes , 2002 .

[2]  E. Gillanders,et al.  Two-locus genome-wide linkage scan for prostate cancer susceptibility genes with an interaction effect , 2006, Human Genetics.

[3]  N. Camp,et al.  Genomic search for prostate cancer predisposition loci in Utah pedigrees , 2005, The Prostate.

[4]  B. Weir,et al.  The quantitative genetics of transcription. , 2005, Trends in genetics : TIG.

[5]  John D. Storey,et al.  Genetic interactions between polymorphisms that affect gene expression in yeast , 2005, Nature.

[6]  John D. Storey,et al.  Multiple Locus Linkage Analysis of Genomewide Expression in Yeast , 2005, PLoS biology.

[7]  D. Y. Lin,et al.  An efficient Monte Carlo approach to assessing statistical significance in genomic studies , 2005, Bioinform..

[8]  Daniel J Schaid,et al.  Comparison of microsatellites versus single-nucleotide polymorphisms in a genome linkage screen for prostate cancer-susceptibility Loci. , 2004, American journal of human genetics.

[9]  T. Matise,et al.  A combined linkage-physical map of the human genome. , 2004, American journal of human genetics.

[10]  D. Siegmund Model selection in irregular problems: Applications to mapping quantitative trait loci , 2004 .

[11]  Chris S. Haley,et al.  Epistasis: too often neglected in complex trait studies? , 2004, Nature Reviews Genetics.

[12]  Carl D Langefeld,et al.  Ordered subset analysis in genetic linkage mapping of complex traits , 2004, Genetic epidemiology.

[13]  Daniel J Schaid,et al.  The complex genetic epidemiology of prostate cancer. , 2004, Human molecular genetics.

[14]  I. Inoue,et al.  Genomewide linkage analysis of familial prostate cancer in the Japanese population , 2004, Journal of Human Genetics.

[15]  Carl D. Langefeld,et al.  Interaction effect of PTEN and CDKN1B chromosomal regions on prostate cancer linkage , 2003, Human Genetics.

[16]  A. Whittemore,et al.  Where are the prostate cancer genes?—A summary of eight genome wide searches , 2003, The Prostate.

[17]  E. Goode,et al.  Genomic scan of 254 hereditary prostate cancer families , 2003, The Prostate.

[18]  D. Schaid,et al.  Genome linkage screen for prostate cancer susceptibility loci: Results from the Mayo Clinic familial prostate cancer study , 2003, The Prostate.

[19]  Jason H. Moore,et al.  The Ubiquitous Nature of Epistasis in Determining Susceptibility to Common Human Diseases , 2003, Human Heredity.

[20]  Erin M. Conlon,et al.  Oligogenic segregation analysis of hereditary prostate cancer pedigrees: Evidence for multiple loci affecting age at onset , 2003, International journal of cancer.

[21]  H. Cordell Epistasis: what it means, what it doesn't mean, and statistical methods to detect it in humans. , 2002, Human molecular genetics.

[22]  David Siegmund,et al.  Mapping multiple genes for quantitative or complex traits , 2002, Genetic epidemiology.

[23]  T. Reich,et al.  A perspective on epistasis: limits of models displaying no main effect. , 2002, American journal of human genetics.

[24]  G. Abecasis,et al.  Merlin—rapid analysis of dense genetic maps using sparse gene flow trees , 2002, Nature Genetics.

[25]  E. Goode,et al.  A genomic scan of families with prostate cancer identifies multiple regions of interest. , 2000, American journal of human genetics.

[26]  D J Schaid,et al.  Evidence for a prostate cancer-susceptibility locus on chromosome 20. , 2000, American journal of human genetics.

[27]  R. Elston,et al.  Multilocus linkage tests based on affected relative pairs. , 2000, American journal of human genetics.

[28]  D. Siegmund,et al.  Boundary crossing probabilities in linkage analysis , 2000 .

[29]  Nancy J. Cox,et al.  Loci on chromosomes 2 (NIDDM1) and 15 interact to increase susceptibility to diabetes in Mexican Americans , 1999, Nature Genetics.

[30]  M S McPeek,et al.  Optimal allele‐sharing statistics for genetic mapping using affected relatives , 1999, Genetic epidemiology.

[31]  J. Weber,et al.  Identification of novel susceptibility loci for inflammatory bowel disease on chromosomes 1p, 3q, and 4q: evidence for epistasis between 1p and IBD1. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[32]  A. Whittemore,et al.  Simple, robust linkage tests for affected sibs. , 1998, American journal of human genetics.

[33]  N J Cox,et al.  Allele-sharing models: LOD scores and accurate linkage tests. , 1997, American journal of human genetics.

[34]  D. Siegmund,et al.  Strategies for mapping heterogeneous recessive traits by allele-sharing methods. , 1997, American journal of human genetics.

[35]  J. Olson Likelihood-based models for genetic linkage analysis using affected sib pairs. , 1997, Human heredity.

[36]  M. Farrall Affected sibpair linkage tests for multiple linked susceptibility genes , 1997, Genetic epidemiology.

[37]  N. Schork,et al.  Who's afraid of epistasis? , 1996, Nature Genetics.

[38]  E. Lander,et al.  Genetic dissection of complex traits: guidelines for interpreting and reporting linkage results , 1995, Nature Genetics.

[39]  M Farrall,et al.  Two-locus maximum lod score analysis of a multifactorial trait: joint consideration of IDDM2 and IDDM4 with IDDM1 in type 1 diabetes. , 1995, American journal of human genetics.

[40]  Paramsothy Silvapulle,et al.  A Score Test against One-Sided Alternatives , 1995 .

[41]  S A Seuchter,et al.  Two-locus disease models with two marker loci: the power of affected-sib-pair tests. , 1994, American journal of human genetics.

[42]  N. Schork,et al.  Two-trait-locus linkage analysis: a powerful strategy for mapping complex genetic traits. , 1993, American journal of human genetics.

[43]  E Feingold,et al.  Gaussian models for genetic linkage analysis using complete high-resolution maps of identity by descent. , 1993, American journal of human genetics.

[44]  P. Holmans,et al.  Asymptotic properties of affected-sib-pair linkage analysis. , 1993, American journal of human genetics.

[45]  Frank A. Wolak,et al.  An Exact Test for Multiple Inequality and Equality Constraints in the Linear Regression Model , 1987 .

[46]  R. Dykstra,et al.  Minimizing linear inequality constrained mahalanobis distances , 1987 .

[47]  E. Lander,et al.  Strategies for studying heterogeneous genetic traits in humans by using a linkage map of restriction fragment length polymorphisms. , 1986, Proceedings of the National Academy of Sciences of the United States of America.

[48]  D. Rao,et al.  Two‐disease locus model: Sib pair method using information on both HLA and Gm , 1986, Genetic epidemiology.

[49]  H. White Maximum Likelihood Estimation of Misspecified Models , 1982 .

[50]  A. J. Collins,et al.  Introduction To Multivariate Analysis , 1981 .

[51]  J. James,et al.  Frequency in relatives for an all‐or‐none trait , 1971, Annals of human genetics.