Genome scan meta-analysis of schizophrenia and bipolar disorder, part III: Bipolar disorder

Ricardo Segurado; Sevilla D. Detera-Wadleigh; Douglas F. Levinson; Cathryn M. Lewis; Michael Gill; John I. Nurnberger; Nick Craddock; J. Raymond DePaulo; Miron Baron; Elliot S. Gershon; Jenny Ekholm; Sven Cichon; Gustavo Turecki; Stephan Claes; John R. Kelsoe; Peter R. Schofield; Renee F. Badenhop; J. Morissette; Hilary Coon; Douglas Blackwood; L. Alison Mclnnes; Tatiana Foroud; Howard J. Edenberg; Theodore Reich; John P. Rice; Alison Goate; Melvin G. McInnis; Francis J. McMahon; Judith A. Badner; Lynn R. Goldin; Phil Bennett; Virginia L. Willour; Peter P. Zandi; Jianjun Liu; Conrad Gilliam; Suh Hang Juo; Wade H. Berrettini; Takeo Yoshikawa; Leena Peltonen; Jouko Lönnqvist; Markus M. Nöthen; Johannes Schumacher; Christine Windemuth; Marcella Rietschel; Peter Propping; Wolfgang Maier; Martin Alda; Paul Grof; Guy A. Rouleau; Jurgen Del-Favero; Christine Van Broeckhoven; Julien Mendlewicz; Rolf Adolfsson; M. Anne Spence; Hermann Luebbert; Linda J. Adams; Jennifer A. Donald; Philip B. Mitchell; Nicholas Barden; Eric Shink; William Byerley; Walter Muir; Peter M. Visscher; Stuart Macgregor; Hugh Gurling; Gursharan Kalsi; Andrew McQuillin; Michael A. Escamilla; Victor I. Reus; Pedro Leon; Nelson B. Freimer; Henrik Ewald; Torben A. Kruse; Ole Mors; Uppala Radhakrishna; Jean Louis Blouin; Stylianos E. Antonarakis; Nurten Akarsu

doi:10.1086/376547

Genome scan meta-analysis of schizophrenia and bipolar disorder, part III: Bipolar disorder

Ricardo Segurado, Sevilla D. Detera-Wadleigh, Douglas F. Levinson, Cathryn M. Lewis, Michael Gill, John I. Nurnberger, Nick Craddock, J. Raymond DePaulo, Miron Baron, Elliot S. Gershon, Jenny Ekholm, Sven Cichon, Gustavo Turecki, Stephan Claes, John R. Kelsoe, Peter R. Schofield, Renee F. Badenhop, J. Morissette, Hilary Coon, Douglas BlackwoodL. Alison Mclnnes, Tatiana Foroud, Howard J. Edenberg, Theodore Reich, John P. Rice, Alison Goate, Melvin G. McInnis, Francis J. McMahon, Judith A. Badner, Lynn R. Goldin, Phil Bennett, Virginia L. Willour, Peter P. Zandi, Jianjun Liu, Conrad Gilliam, Suh Hang Juo, Wade H. Berrettini, Takeo Yoshikawa, Leena Peltonen, Jouko Lönnqvist, Markus M. Nöthen, Johannes Schumacher, Christine Windemuth, Marcella Rietschel, Peter Propping, Wolfgang Maier, Martin Alda, Paul Grof, Guy A. Rouleau, Jurgen Del-Favero, Christine Van Broeckhoven, Julien Mendlewicz, Rolf Adolfsson, M. Anne Spence, Hermann Luebbert, Linda J. Adams, Jennifer A. Donald, Philip B. Mitchell, Nicholas Barden, Eric Shink, William Byerley, Walter Muir, Peter M. Visscher, Stuart Macgregor, Hugh Gurling, Gursharan Kalsi, Andrew McQuillin, Michael A. Escamilla, Victor I. Reus, Pedro Leon, Nelson B. Freimer, Henrik Ewald, Torben A. Kruse, Ole Mors, Uppala Radhakrishna, Jean Louis Blouin, Stylianos E. Antonarakis, Nurten Akarsu

School of Medicine

Research output: Contribution to journal › Article › peer-review

345 Scopus citations

Abstract

Genome scans of bipolar disorder (BPD) have not produced consistent evidence for linkage. The rank-based genome scan meta-analysis (GSMA) method was applied to 18 BPD genome scan data sets in an effort to identify regions with significant support for linkage in the combined data. The two primary analyses considered available linkage data for "very narrow" (i.e., BP-I and schizoaffective disorder-BP) and "narrow" (i.e., adding BP-II disorder) disease models, with the ranks weighted for sample size. A "broad" model (i.e., adding recurrent major depression) and unweighted analyses were also performed. No region achieved genomewide statistical significance by several simulation-based criteria. The most significant P values (<.01) were observed on chromosomes 9p22.3-21.1 (very narrow), 10q11.21-22.1 (very narrow), and 14q24.1-32.12 (narrow). Nominally significant P values were observed in adjacent bins on chromosomes 9p and 18p-q, across all three disease models on chromosomes 14q and 18p-q, and across two models on chromosome 8q. Relatively few BPD pedigrees have been studied under narrow disease models relative to the schizophrenia GSMA data set, which produced more significant results. There was no overlap of the highest-ranked regions for the two disorders. The present results for the very narrow model are promising but suggest that more and larger data sets are needed. Alternatively, linkage might be detected in certain populations or subsets of pedigrees. The narrow and broad data sets had considerable power, according to simulation studies, but did not produce more highly significant evidence for linkage. We note that meta-analysis can sometimes provide support for linkage but cannot disprove linkage in any candidate region.

Original language	English (US)
Pages (from-to)	49-62
Number of pages	14
Journal	American journal of human genetics
Volume	73
Issue number	1
DOIs	https://doi.org/10.1086/376547
State	Published - Jul 1 2003

ASJC Scopus subject areas

Genetics
Genetics(clinical)

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10.1086/376547

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Segurado, R., Detera-Wadleigh, S. D., Levinson, D. F., Lewis, C. M., Gill, M., Nurnberger, J. I., Craddock, N., DePaulo, J. R., Baron, M., Gershon, E. S., Ekholm, J., Cichon, S., Turecki, G., Claes, S., Kelsoe, J. R., Schofield, P. R., Badenhop, R. F., Morissette, J., Coon, H., ... Akarsu, N. (2003). Genome scan meta-analysis of schizophrenia and bipolar disorder, part III: Bipolar disorder. American journal of human genetics, 73(1), 49-62. https://doi.org/10.1086/376547

Segurado, R, Detera-Wadleigh, SD, Levinson, DF, Lewis, CM, Gill, M, Nurnberger, JI, Craddock, N, DePaulo, JR, Baron, M, Gershon, ES, Ekholm, J, Cichon, S, Turecki, G, Claes, S, Kelsoe, JR, Schofield, PR, Badenhop, RF, Morissette, J, Coon, H, Blackwood, D, Mclnnes, LA, Foroud, T, Edenberg, HJ, Reich, T, Rice, JP, Goate, A, McInnis, MG, McMahon, FJ, Badner, JA, Goldin, LR, Bennett, P, Willour, VL, Zandi, PP, Liu, J, Gilliam, C, Juo, SH, Berrettini, WH, Yoshikawa, T, Peltonen, L, Lönnqvist, J, Nöthen, MM, Schumacher, J, Windemuth, C, Rietschel, M, Propping, P, Maier, W, Alda, M, Grof, P, Rouleau, GA, Del-Favero, J, Van Broeckhoven, C, Mendlewicz, J, Adolfsson, R, Spence, MA, Luebbert, H, Adams, LJ, Donald, JA, Mitchell, PB, Barden, N, Shink, E, Byerley, W, Muir, W, Visscher, PM, Macgregor, S, Gurling, H, Kalsi, G, McQuillin, A, Escamilla, MA, Reus, VI, Leon, P, Freimer, NB, Ewald, H, Kruse, TA, Mors, O, Radhakrishna, U, Blouin, JL, Antonarakis, SE & Akarsu, N 2003, 'Genome scan meta-analysis of schizophrenia and bipolar disorder, part III: Bipolar disorder', American journal of human genetics, vol. 73, no. 1, pp. 49-62. https://doi.org/10.1086/376547

@article{7d44a9abd0d94a03a91d5f7194d4bfe7,

title = "Genome scan meta-analysis of schizophrenia and bipolar disorder, part III: Bipolar disorder",

abstract = "Genome scans of bipolar disorder (BPD) have not produced consistent evidence for linkage. The rank-based genome scan meta-analysis (GSMA) method was applied to 18 BPD genome scan data sets in an effort to identify regions with significant support for linkage in the combined data. The two primary analyses considered available linkage data for {"}very narrow{"} (i.e., BP-I and schizoaffective disorder-BP) and {"}narrow{"} (i.e., adding BP-II disorder) disease models, with the ranks weighted for sample size. A {"}broad{"} model (i.e., adding recurrent major depression) and unweighted analyses were also performed. No region achieved genomewide statistical significance by several simulation-based criteria. The most significant P values (<.01) were observed on chromosomes 9p22.3-21.1 (very narrow), 10q11.21-22.1 (very narrow), and 14q24.1-32.12 (narrow). Nominally significant P values were observed in adjacent bins on chromosomes 9p and 18p-q, across all three disease models on chromosomes 14q and 18p-q, and across two models on chromosome 8q. Relatively few BPD pedigrees have been studied under narrow disease models relative to the schizophrenia GSMA data set, which produced more significant results. There was no overlap of the highest-ranked regions for the two disorders. The present results for the very narrow model are promising but suggest that more and larger data sets are needed. Alternatively, linkage might be detected in certain populations or subsets of pedigrees. The narrow and broad data sets had considerable power, according to simulation studies, but did not produce more highly significant evidence for linkage. We note that meta-analysis can sometimes provide support for linkage but cannot disprove linkage in any candidate region.",

author = "Ricardo Segurado and Detera-Wadleigh, {Sevilla D.} and Levinson, {Douglas F.} and Lewis, {Cathryn M.} and Michael Gill and Nurnberger, {John I.} and Nick Craddock and DePaulo, {J. Raymond} and Miron Baron and Gershon, {Elliot S.} and Jenny Ekholm and Sven Cichon and Gustavo Turecki and Stephan Claes and Kelsoe, {John R.} and Schofield, {Peter R.} and Badenhop, {Renee F.} and J. Morissette and Hilary Coon and Douglas Blackwood and Mclnnes, {L. Alison} and Tatiana Foroud and Edenberg, {Howard J.} and Theodore Reich and Rice, {John P.} and Alison Goate and McInnis, {Melvin G.} and McMahon, {Francis J.} and Badner, {Judith A.} and Goldin, {Lynn R.} and Phil Bennett and Willour, {Virginia L.} and Zandi, {Peter P.} and Jianjun Liu and Conrad Gilliam and Juo, {Suh Hang} and Berrettini, {Wade H.} and Takeo Yoshikawa and Leena Peltonen and Jouko L{\"o}nnqvist and N{\"o}then, {Markus M.} and Johannes Schumacher and Christine Windemuth and Marcella Rietschel and Peter Propping and Wolfgang Maier and Martin Alda and Paul Grof and Rouleau, {Guy A.} and Jurgen Del-Favero and {Van Broeckhoven}, Christine and Julien Mendlewicz and Rolf Adolfsson and Spence, {M. Anne} and Hermann Luebbert and Adams, {Linda J.} and Donald, {Jennifer A.} and Mitchell, {Philip B.} and Nicholas Barden and Eric Shink and William Byerley and Walter Muir and Visscher, {Peter M.} and Stuart Macgregor and Hugh Gurling and Gursharan Kalsi and Andrew McQuillin and Escamilla, {Michael A.} and Reus, {Victor I.} and Pedro Leon and Freimer, {Nelson B.} and Henrik Ewald and Kruse, {Torben A.} and Ole Mors and Uppala Radhakrishna and Blouin, {Jean Louis} and Antonarakis, {Stylianos E.} and Nurten Akarsu",

note = "Funding Information: We would like to express our profound thanks to all of the participating family members and the many clinicians who evaluated subjects in the projects that contributed data to the present analysis. Financial support is gratefully acknowledged from NIMH grants K24-MH064197 and R01-MH062276 (to D.F.L.); Enterprise Ireland and the Higher Education Authority (National Development Plan [Ireland] and European Regional Development Fund) Programme for Research in Third Level Institutions (to R.S.); NIMH grants U01-MH 46282, U01-54794, U01-46280, U01-54723, U01-46274, and U01-54701 (NIMH Genetics Initiative); NIMH grant R01MH59545 and a grant from the Indiana Division of Mental Health (to J.I.N.); The Wellcome Trust (U.K./Irish); NIMH grants MH42243 and MH01099, the Charles Dana Foundation, the National Alliance for Research on Schizophrenia and Depression, the Alexander Wilson Schweizer fund, and the George Browne Laboratory Fund (to the Hopkins/Dana project); NIMH grants MH42535, MH43979, and 00176 (to M.B.); National Institutes of Health grants MH59553 and MH63876 (to W.H.B.); the Academy of Finland and the MacDonald Foundation, USA (to L.P.); Canadian Institutes of Health Research grant 14041 (to M.A.); Special Research Fund of the University of Antwerp, Fund for Scientific Research Flanders, and the InterUniversity Attraction Poles program 19/5 of the Federal Office for Scientific, Technical and Cultural Affairs, Belgium (to C.V.B.); Novartis, NIMH grants MH47612 and MH59567, the Department of Veterans Affairs, the Veterans Administration Veterans Integrated Service Network 22 Mental Illness Research, Education, and Clinical Center, and University of California San Diego General Clinical Research Center grant M01 RR00827 (to J.R.K.); National Health and Medical Research Council of Australia grants 993050 and 157209 (to P.R.S.), 993208 and 222708 (to P.B.M.), and 983302 (to J.A.D.); NIMH grant 1R01MH3448 and Fonds de Recherche en Sant{\'e} du Qu{\'e}bec (to N.B.); NIMH grants R01-MH042463, K02-MH01089, and R01-MH42643 (to W.B.); Medical Research Council, London, and The Chief Scientist Office of the Scottish Executive (Edinburgh); National Institute of Neurological Disorders and Stroke grant R01 NS37484 and NIMH grant R01 MH49499 (to N.B.F.); the Swiss Science National Foundation (to S.E.A.); and the Danish Medical Research Council and the Lundbeck Foundation (to H.E.). The Center for Inherited Disease Research provided genotyping services to the Hopkins/Dana project under National Institutes of Health contract N01-HG65493 (to Johns Hopkins University). ",

year = "2003",

month = jul,

day = "1",

doi = "10.1086/376547",

language = "English (US)",

volume = "73",

pages = "49--62",

journal = "American journal of human genetics",

issn = "0002-9297",

publisher = "Cell Press",

number = "1",

}

TY - JOUR

T1 - Genome scan meta-analysis of schizophrenia and bipolar disorder, part III

T2 - Bipolar disorder

AU - Segurado, Ricardo

AU - Detera-Wadleigh, Sevilla D.

AU - Levinson, Douglas F.

AU - Lewis, Cathryn M.

AU - Gill, Michael

AU - Nurnberger, John I.

AU - Craddock, Nick

AU - DePaulo, J. Raymond

AU - Baron, Miron

AU - Gershon, Elliot S.

AU - Ekholm, Jenny

AU - Cichon, Sven

AU - Turecki, Gustavo

AU - Claes, Stephan

AU - Kelsoe, John R.

AU - Schofield, Peter R.

AU - Badenhop, Renee F.

AU - Morissette, J.

AU - Coon, Hilary

AU - Blackwood, Douglas

AU - Mclnnes, L. Alison

AU - Foroud, Tatiana

AU - Edenberg, Howard J.

AU - Reich, Theodore

AU - Rice, John P.

AU - Goate, Alison

AU - McInnis, Melvin G.

AU - McMahon, Francis J.

AU - Badner, Judith A.

AU - Goldin, Lynn R.

AU - Bennett, Phil

AU - Willour, Virginia L.

AU - Zandi, Peter P.

AU - Liu, Jianjun

AU - Gilliam, Conrad

AU - Juo, Suh Hang

AU - Berrettini, Wade H.

AU - Yoshikawa, Takeo

AU - Peltonen, Leena

AU - Lönnqvist, Jouko

AU - Nöthen, Markus M.

AU - Schumacher, Johannes

AU - Windemuth, Christine

AU - Rietschel, Marcella

AU - Propping, Peter

AU - Maier, Wolfgang

AU - Alda, Martin

AU - Grof, Paul

AU - Rouleau, Guy A.

AU - Del-Favero, Jurgen

AU - Van Broeckhoven, Christine

AU - Mendlewicz, Julien

AU - Adolfsson, Rolf

AU - Spence, M. Anne

AU - Luebbert, Hermann

AU - Adams, Linda J.

AU - Donald, Jennifer A.

AU - Mitchell, Philip B.

AU - Barden, Nicholas

AU - Shink, Eric

AU - Byerley, William

AU - Muir, Walter

AU - Visscher, Peter M.

AU - Macgregor, Stuart

AU - Gurling, Hugh

AU - Kalsi, Gursharan

AU - McQuillin, Andrew

AU - Escamilla, Michael A.

AU - Reus, Victor I.

AU - Leon, Pedro

AU - Freimer, Nelson B.

AU - Ewald, Henrik

AU - Kruse, Torben A.

AU - Mors, Ole

AU - Radhakrishna, Uppala

AU - Blouin, Jean Louis

AU - Antonarakis, Stylianos E.

AU - Akarsu, Nurten

N1 - Funding Information: We would like to express our profound thanks to all of the participating family members and the many clinicians who evaluated subjects in the projects that contributed data to the present analysis. Financial support is gratefully acknowledged from NIMH grants K24-MH064197 and R01-MH062276 (to D.F.L.); Enterprise Ireland and the Higher Education Authority (National Development Plan [Ireland] and European Regional Development Fund) Programme for Research in Third Level Institutions (to R.S.); NIMH grants U01-MH 46282, U01-54794, U01-46280, U01-54723, U01-46274, and U01-54701 (NIMH Genetics Initiative); NIMH grant R01MH59545 and a grant from the Indiana Division of Mental Health (to J.I.N.); The Wellcome Trust (U.K./Irish); NIMH grants MH42243 and MH01099, the Charles Dana Foundation, the National Alliance for Research on Schizophrenia and Depression, the Alexander Wilson Schweizer fund, and the George Browne Laboratory Fund (to the Hopkins/Dana project); NIMH grants MH42535, MH43979, and 00176 (to M.B.); National Institutes of Health grants MH59553 and MH63876 (to W.H.B.); the Academy of Finland and the MacDonald Foundation, USA (to L.P.); Canadian Institutes of Health Research grant 14041 (to M.A.); Special Research Fund of the University of Antwerp, Fund for Scientific Research Flanders, and the InterUniversity Attraction Poles program 19/5 of the Federal Office for Scientific, Technical and Cultural Affairs, Belgium (to C.V.B.); Novartis, NIMH grants MH47612 and MH59567, the Department of Veterans Affairs, the Veterans Administration Veterans Integrated Service Network 22 Mental Illness Research, Education, and Clinical Center, and University of California San Diego General Clinical Research Center grant M01 RR00827 (to J.R.K.); National Health and Medical Research Council of Australia grants 993050 and 157209 (to P.R.S.), 993208 and 222708 (to P.B.M.), and 983302 (to J.A.D.); NIMH grant 1R01MH3448 and Fonds de Recherche en Santé du Québec (to N.B.); NIMH grants R01-MH042463, K02-MH01089, and R01-MH42643 (to W.B.); Medical Research Council, London, and The Chief Scientist Office of the Scottish Executive (Edinburgh); National Institute of Neurological Disorders and Stroke grant R01 NS37484 and NIMH grant R01 MH49499 (to N.B.F.); the Swiss Science National Foundation (to S.E.A.); and the Danish Medical Research Council and the Lundbeck Foundation (to H.E.). The Center for Inherited Disease Research provided genotyping services to the Hopkins/Dana project under National Institutes of Health contract N01-HG65493 (to Johns Hopkins University).

PY - 2003/7/1

Y1 - 2003/7/1

N2 - Genome scans of bipolar disorder (BPD) have not produced consistent evidence for linkage. The rank-based genome scan meta-analysis (GSMA) method was applied to 18 BPD genome scan data sets in an effort to identify regions with significant support for linkage in the combined data. The two primary analyses considered available linkage data for "very narrow" (i.e., BP-I and schizoaffective disorder-BP) and "narrow" (i.e., adding BP-II disorder) disease models, with the ranks weighted for sample size. A "broad" model (i.e., adding recurrent major depression) and unweighted analyses were also performed. No region achieved genomewide statistical significance by several simulation-based criteria. The most significant P values (<.01) were observed on chromosomes 9p22.3-21.1 (very narrow), 10q11.21-22.1 (very narrow), and 14q24.1-32.12 (narrow). Nominally significant P values were observed in adjacent bins on chromosomes 9p and 18p-q, across all three disease models on chromosomes 14q and 18p-q, and across two models on chromosome 8q. Relatively few BPD pedigrees have been studied under narrow disease models relative to the schizophrenia GSMA data set, which produced more significant results. There was no overlap of the highest-ranked regions for the two disorders. The present results for the very narrow model are promising but suggest that more and larger data sets are needed. Alternatively, linkage might be detected in certain populations or subsets of pedigrees. The narrow and broad data sets had considerable power, according to simulation studies, but did not produce more highly significant evidence for linkage. We note that meta-analysis can sometimes provide support for linkage but cannot disprove linkage in any candidate region.

AB - Genome scans of bipolar disorder (BPD) have not produced consistent evidence for linkage. The rank-based genome scan meta-analysis (GSMA) method was applied to 18 BPD genome scan data sets in an effort to identify regions with significant support for linkage in the combined data. The two primary analyses considered available linkage data for "very narrow" (i.e., BP-I and schizoaffective disorder-BP) and "narrow" (i.e., adding BP-II disorder) disease models, with the ranks weighted for sample size. A "broad" model (i.e., adding recurrent major depression) and unweighted analyses were also performed. No region achieved genomewide statistical significance by several simulation-based criteria. The most significant P values (<.01) were observed on chromosomes 9p22.3-21.1 (very narrow), 10q11.21-22.1 (very narrow), and 14q24.1-32.12 (narrow). Nominally significant P values were observed in adjacent bins on chromosomes 9p and 18p-q, across all three disease models on chromosomes 14q and 18p-q, and across two models on chromosome 8q. Relatively few BPD pedigrees have been studied under narrow disease models relative to the schizophrenia GSMA data set, which produced more significant results. There was no overlap of the highest-ranked regions for the two disorders. The present results for the very narrow model are promising but suggest that more and larger data sets are needed. Alternatively, linkage might be detected in certain populations or subsets of pedigrees. The narrow and broad data sets had considerable power, according to simulation studies, but did not produce more highly significant evidence for linkage. We note that meta-analysis can sometimes provide support for linkage but cannot disprove linkage in any candidate region.

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UR - http://www.scopus.com/inward/citedby.url?scp=0038341184&partnerID=8YFLogxK

U2 - 10.1086/376547

DO - 10.1086/376547

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AN - SCOPUS:0038341184

SN - 0002-9297

VL - 73

SP - 49

EP - 62

JO - American journal of human genetics

JF - American journal of human genetics

IS - 1

ER -

Genome scan meta-analysis of schizophrenia and bipolar disorder, part III: Bipolar disorder

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