TY - JOUR
T1 - Exome sequencing of familial bipolar disorder
AU - Goes, Fernando S.
AU - Pirooznia, Mehdi
AU - Parla, Jennifer S.
AU - Kramer, Melissa
AU - Ghiban, Elena
AU - Mavruk, Senem
AU - Chen, Yun Ching
AU - Monson, Eric T.
AU - Willour, Virginia L.
AU - Karchin, Rachel
AU - Flickinger, Matthew
AU - Locke, Adam E.
AU - Levy, Shawn E.
AU - Scott, Laura J.
AU - Boehnke, Michael
AU - Stahl, Eli
AU - Moran, Jennifer L.
AU - Hultman, Christina M.
AU - Landén, Mikael
AU - Purcell, Shaun M.
AU - Sklar, Pamela
AU - Zandi, Peter P.
AU - McCombie, W. Richard
AU - Potash, James B.
N1 - Publisher Copyright:
Copyright 2016 American Medical Association. All rights reserved.
PY - 2016/6
Y1 - 2016/6
N2 - Importance: Complex disorders, such as bipolar disorder (BD), likely result from the influence of both common and rare susceptibility alleles. While common variation has been widely studied, rare variant discovery has only recently become feasible with next-generation sequencing. Objective: To utilize a combined family-based and case-control approach to exome sequencing in BD using multiplex families as an initial discovery strategy, followed by association testing in a large case-control meta-analysis. Design, Setting, and Participants: We performed exome sequencing of 36 affected members with BD from 8 multiplex families and tested rare, segregating variants in 3 independent case-control samples consisting of 3541 BD cases and 4774 controls. Main Outcomes and Measures: We used penalized logistic regression and 1-sided gene-burden analyses to test for association of rare, segregating damaging variants with BD. Permutation-based analyses were performed to test for overall enrichment with previously identified gene sets. Results: We found 84 rare (frequency <1%), segregating variants that were bioinformatically predicted to be damaging. These variants were found in 82 genes that were enriched for gene sets previously identified in de novo studies of autism (19 observed vs. 10.9 expected, P = .0066) and schizophrenia (11 observed vs. 5.1 expected, P = .0062) and for targets of the fragile X mental retardation protein (FMRP) pathway (10 observed vs. 4.4 expected, P = .0076). The case-control meta-analyses yielded 19 genes that were nominally associated with BD based either on individual variants or a gene-burden approach. Although no gene was individually significant after correction for multiple testing, this group of genes continued to show evidence for significant enrichment of de novo autism genes (6 observed vs 2.6 expected, P = .028). Conclusions and Relevance: Our results are consistent with the presence of prominent locus and allelic heterogeneity in BD and suggest that very large samples will be required to definitively identify individual rare variants or genes conferring risk for this disorder. However, we also identify significant associations with gene sets composed of previously discovered de novo variants in autism and schizophrenia, as well as targets of the FRMP pathway, providing preliminary support for the overlap of potential autism and schizophrenia risk genes with rare, segregating variants in families with BD.
AB - Importance: Complex disorders, such as bipolar disorder (BD), likely result from the influence of both common and rare susceptibility alleles. While common variation has been widely studied, rare variant discovery has only recently become feasible with next-generation sequencing. Objective: To utilize a combined family-based and case-control approach to exome sequencing in BD using multiplex families as an initial discovery strategy, followed by association testing in a large case-control meta-analysis. Design, Setting, and Participants: We performed exome sequencing of 36 affected members with BD from 8 multiplex families and tested rare, segregating variants in 3 independent case-control samples consisting of 3541 BD cases and 4774 controls. Main Outcomes and Measures: We used penalized logistic regression and 1-sided gene-burden analyses to test for association of rare, segregating damaging variants with BD. Permutation-based analyses were performed to test for overall enrichment with previously identified gene sets. Results: We found 84 rare (frequency <1%), segregating variants that were bioinformatically predicted to be damaging. These variants were found in 82 genes that were enriched for gene sets previously identified in de novo studies of autism (19 observed vs. 10.9 expected, P = .0066) and schizophrenia (11 observed vs. 5.1 expected, P = .0062) and for targets of the fragile X mental retardation protein (FMRP) pathway (10 observed vs. 4.4 expected, P = .0076). The case-control meta-analyses yielded 19 genes that were nominally associated with BD based either on individual variants or a gene-burden approach. Although no gene was individually significant after correction for multiple testing, this group of genes continued to show evidence for significant enrichment of de novo autism genes (6 observed vs 2.6 expected, P = .028). Conclusions and Relevance: Our results are consistent with the presence of prominent locus and allelic heterogeneity in BD and suggest that very large samples will be required to definitively identify individual rare variants or genes conferring risk for this disorder. However, we also identify significant associations with gene sets composed of previously discovered de novo variants in autism and schizophrenia, as well as targets of the FRMP pathway, providing preliminary support for the overlap of potential autism and schizophrenia risk genes with rare, segregating variants in families with BD.
UR - http://www.scopus.com/inward/record.url?scp=84973333991&partnerID=8YFLogxK
U2 - 10.1001/jamapsychiatry.2016.0251
DO - 10.1001/jamapsychiatry.2016.0251
M3 - Article
C2 - 27120077
AN - SCOPUS:84973333991
SN - 2168-622X
VL - 73
SP - 590
EP - 597
JO - JAMA Psychiatry
JF - JAMA Psychiatry
IS - 6
ER -