TY - JOUR
T1 - Bayesian association-based fine mapping in small chromosomal segments
AU - Sillanpää, M J
AU - Bhattacharjee, Madhuchhanda
PY - 2005/1
Y1 - 2005/1
N2 - A Bayesian method for fine mapping is presented, which deals with multiallelic markers (with two or more alleles), unknown phase, missing data, multiple causal variants, and both continuous and binary phenotypes. We consider small chromosomal segments spanned by a dense set of closely linked markers and putative genes only at marker points. In the phenotypic model, locus-specific indicator variables are used to control inclusion in or exclusion from marker contributions. To account for covariance between consecutive loci and to control fluctuations in association signals along a candidate region we introduce a joint prior for the indicators that depends on genetic or physical map distances. The potential of the method, including posterior estimation of trait-associated loci, their effects, linkage disequilibrium pattern due to close linkage of loci, and the age of a causal variant (time to most recent common ancestor), is illustrated with the well-known cystic fibrosis and Friedreich ataxia data sets by assuming that haplotypes were not available. In addition, simulation analysis with large genetic distances is shown. Estimation of model parameters is based on Markov chain Monte Carlo (MCMC sampling and is implemented using WinBUGS. The model specification code is freely available for research purposes from http://NNiNr\v.t-iii.helsinki.fi/ mjs/.
AB - A Bayesian method for fine mapping is presented, which deals with multiallelic markers (with two or more alleles), unknown phase, missing data, multiple causal variants, and both continuous and binary phenotypes. We consider small chromosomal segments spanned by a dense set of closely linked markers and putative genes only at marker points. In the phenotypic model, locus-specific indicator variables are used to control inclusion in or exclusion from marker contributions. To account for covariance between consecutive loci and to control fluctuations in association signals along a candidate region we introduce a joint prior for the indicators that depends on genetic or physical map distances. The potential of the method, including posterior estimation of trait-associated loci, their effects, linkage disequilibrium pattern due to close linkage of loci, and the age of a causal variant (time to most recent common ancestor), is illustrated with the well-known cystic fibrosis and Friedreich ataxia data sets by assuming that haplotypes were not available. In addition, simulation analysis with large genetic distances is shown. Estimation of model parameters is based on Markov chain Monte Carlo (MCMC sampling and is implemented using WinBUGS. The model specification code is freely available for research purposes from http://NNiNr\v.t-iii.helsinki.fi/ mjs/.
KW - QUANTITATIVE TRAIT LOCI
KW - LINKAGE-DISEQUILIBRIUM
KW - HAPLOTYPE BLOCKS
KW - HUMAN GENOME
KW - STRUCTURED POPULATIONS
KW - ALLELIC ASSOCIATION
KW - QUALITATIVE TRAITS
KW - VARIABLE SELECTION
KW - MODEL SELECTION
KW - DISEASE GENES
UR - http://www.scopus.com/inward/record.url?scp=13744263024&partnerID=8YFLogxK
UR - http://www.genetics.org/cgi/search?volume=169&firstpage=427&sendit=Search&DOI=&author1=&author2=&titleabstract=&fulltext=&fmonth=Jan&fyear=1916&tmonth=Aug&tyear=2007&hits=10&fdatedef=1+January+1916&tdatedef=8+August+2007
U2 - 10.1534/genetics.104.032680
DO - 10.1534/genetics.104.032680
M3 - Article
SN - 0016-6731
VL - 169
SP - 427
EP - 439
JO - Genetics
JF - Genetics
IS - 1
ER -