Association Study of 182 Candidate Genes in Anorexia Nervosa

Overview

Journal Am J Med Genet B Neuropsychiatr Genet

Specialties Genetics
Neurology
Psychiatry

Date 2010 May 15

PMID 20468064

Citations 37

Authors

Andrea Poyastro Pinheiro

Cynthia M Bulik

Laura M Thornton

Patrick F Sullivan

Tammy L Root

Cinnamon S Bloss

Wade H Berrettini

Nicholas J Schork

Walter H Kaye

Andrew W Bergen

Pierre Magistretti

Harry Brandt

Steve Crawford

Scott Crow

Manfred M Fichter

David Goldman

Katherine A Halmi

Craig Johnson

Allan S Kaplan

Pamela K Keel

Kelly L Klump

Maria La Via

James E Mitchell

Michael Strober

Alessandro Rotondo

Janet Treasure

D Blake Woodside

Affiliations

Soon will be listed here.

Abstract

We performed association studies with 5,151 SNPs that were judged as likely candidate genetic variations conferring susceptibility to anorexia nervosa (AN) based on location under reported linkage peaks, previous results in the literature (182 candidate genes), brain expression, biological plausibility, and estrogen responsivity. We employed a case-control design that tested each SNP individually as well as haplotypes derived from these SNPs in 1,085 case individuals with AN diagnoses and 677 control individuals. We also performed separate association analyses using three increasingly restrictive case definitions for AN: all individuals with any subtype of AN (All AN: n = 1,085); individuals with AN with no binge eating behavior (AN with No Binge Eating: n = 687); and individuals with the restricting subtype of AN (Restricting AN: n = 421). After accounting for multiple comparisons, there were no statistically significant associations for any individual SNP or haplotype block with any definition of illness. These results underscore the importance of large samples to yield appropriate power to detect genotypic differences in individuals with AN and also motivate complementary approaches involving Genome-Wide Association (GWA) studies, Copy Number Variation (CNV) analyses, sequencing-based rare variant discovery assays, and pathway-based analysis in order to make up for deficiencies in traditional candidate gene approaches to AN.

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