Your search keyword '"Jansen, P.R."' showing total 23 results

1. Hypothesis-driven genome-wide association studies provide novel insights into genetics of reading disabilities

Author

Price, K.M., Wigg, K.G., Eising, E., Feng, Y, Blokland, K., Wilkinson, M., Kerr, E.N., Guger, S.L., Abbondanza, F., Allegrini, A.G., Andlauer, T.F.M., Bates, T.C., Bernard, M., Bonte, M., Boomsma, D.I., Bourgeron, T., Brandeis, D., Carreiras, M., Ceroni, F., Csépe, V., Dale, P.S., DeFries, J.C., Jong, P.F. de, Démonet, J.F., Zeeuw, E.L. de, Franken, M.-C.J., Francks, C., Gerritse, M.L., Gialluisi, A., Gordon, S.D., Gruen, J.R., Hayiou-Thomas, M.E., Hernández-Cabrera, J., Hottenga, J.-J., Hulme, C., Jansen, P.R., Kere, J., Koomar, T., Landerl, K., Leonard, G.T., Liao, Z., Luciano, M., Lyytinen, H., Martin, N.G., Martinelli, A., Maurer, U., Michaelson, J.J., Mirza-Schreiber, N., Moll, K., Monaco, A.P., Morgan, A.T., Müller-Myhsok, B., Newbury, D.F., Nöthen, M.M., Olson, R.K., Paracchini, S., Paus, T., Pausova, Z., Pennell, C.E., Pennington, B.F., Plomin, R.J., Ramus, F., Reilly, S., Richer, L., Rimfeld, K., Schulte-Körne, G., Shapland, C.Y., Simpson, N.H., Smith, S.D., Snowling, M.J., St Pourcain, B., Stein, J.F., Talcott, J.B., Tiemeier, H., Tomblin, J.B., Truong, D.T., Bergen, E. van, Schroeff, M.P. van der, Donkelaar, M.M.J. van, Verhoef, E., Wang, C.A., Watkins, K.E., Whitehouse, A.J.O., Willcutt, E.G., Wright, M.J., Zhu, G., Fisher, S.E., Lovett, M.W., Strug, L.J., Barr, C.L., University of St Andrews. School of Medicine, University of St Andrews. Centre for Biophotonics, University of St Andrews. Biomedical Sciences Research Complex, University of St Andrews. Institute of Behavioural and Neural Sciences, University of St Andrews. St Andrews Bioinformatics Unit, University of St Andrews. Cellular Medicine Division, STEMM - Stem Cells and Metabolism Research Program, Juha Kere / Principal Investigator, Research Programs Unit, University of Helsinki, Consortium, Quantitative Trait Working Group of the GenLang, European Commission, Otorhinolaryngology and Head and Neck Surgery, Child and Adolescent Psychiatry / Psychology, RS: FPN CN 7, Language, Biological Psychology, Amsterdam Reproduction & Development, APH - Mental Health, APH - Methodology, APH - Health Behaviors & Chronic Diseases, APH - Personalized Medicine, Complex Trait Genetics, Amsterdam Neuroscience - Complex Trait Genetics, LEARN! - Educational neuroscience, learning and development, and Human genetics

Subjects

Neuroinformatics, single nucleotide, Candidate gene, Autism Spectrum Disorder, Developmental dyslexia, autism spectrum disorder, QH426 Genetics, Polymorphism, Single Nucleotide, Neuronal migration, 3124 Neurology and psychiatry, polymorphism, Dyslexia, Cellular and Molecular Neuroscience, All institutes and research themes of the Radboud University Medical Center, problem solving, SDG 3 - Good Health and Well-being, dyslexia, Humans, Kiaa0319, Family, humans, Children, QH426, Problem Solving, Biological Psychiatry, MCC, Neurodevelopmental disorders Donders Center for Medical Neuroscience [Radboudumc 7], genome-wide association study, Dyx1c1, Plasma-membrane, 3rd-DAS, Psychiatry and Mental health, Susceptibility, RC0321, SDG 4 - Quality Education, RC0321 Neuroscience. Biological psychiatry. Neuropsychiatry, Genome-Wide Association Study, Knockout mice

Abstract

Reading Disability (RD) is often characterized by difficulties in the phonology of the language. While the molecular mechanisms underlying it are largely undetermined, loci are being revealed by genome-wide association studies (GWAS). In a previous GWAS for word reading (Price, 2020), we observed that top single-nucleotide polymorphisms (SNPs) were located near to or in genes involved in neuronal migration/axon guidance (NM/AG) or loci implicated in autism spectrum disorder (ASD). A prominent theory of RD etiology posits that it involves disturbed neuronal migration, while potential links between RD-ASD have not been extensively investigated. To improve power to identify associated loci, we up-weighted variants involved in NM/AG or ASD, separately, and performed a new Hypothesis-Driven (HD)–GWAS. The approach was applied to a Toronto RD sample and a meta-analysis of the GenLang Consortium. For the Toronto sample (n = 624), no SNPs reached significance; however, by gene-set analysis, the joint contribution of ASD-related genes passed the threshold (p~1.45 × 10–2, threshold = 2.5 × 10–2). For the GenLang Cohort (n = 26,558), SNPs in DOCK7 and CDH4 showed significant association for the NM/AG hypothesis (sFDR q = 1.02 × 10–2). To make the GenLang dataset more similar to Toronto, we repeated the analysis restricting to samples selected for reading/language deficits (n = 4152). In this GenLang selected subset, we found significant association for a locus intergenic between BTG3-C21orf91 for both hypotheses (sFDR q < 9.00 × 10–4). This study contributes candidate loci to the genetics of word reading. Data also suggest that, although different variants may be involved, alleles implicated in ASD risk may be found in the same genes as those implicated in word reading. This finding is limited to the Toronto sample suggesting that ascertainment influences genetic associations., Translational Psychiatry, 12 (1), ISSN:2158-3188

Published

2022

2. Genome-wide analyses of individual differences in quantitatively assessed reading- and language-related skills in up to 34,000 people

Author

Eising, E., Mirza-Schreiber, N., Zeeuw, E.L. de, Wang, C.A., Truong, D.T., Allegrini, A.G., Shapland, C.Y., Zhu, G., Wigg, K.G., Gerritse, M.L., Molz, B., Alagöz, G., Gialluisi, A., Abbondanza, F., Rimfeld, K., Donkelaar, M.M.J. van, Liao, Z., Jansen, P.R., Andlauer, T.F.M., Bates, T.C., Bernard, M., Blokland, K., Bonte, M., Børglum, A.D., Bourgeron, T., Brandeis, D., Ceroni, F., Csépe, V., Dale, P.S., Jong, P.F. de, DeFries, J.C., Démonet, J.F., Demontis, D., Feng, Yu, Gordon, S.D.S., Guger, S.L., Hayiou-Thomas, M.E., Hernández-Cabrera, J.A., Hottenga, J.J., Hulme, C., Kere, J., Kerr, E.N., Koomar, T., Landerl, K., Leonard, G.T., Lovett, M.W., Lyytinen, H., Martin, N.G., Martinelli, A., Maurer, U., Michaelson, J.J., Moll, K., Monaco, A.P., Morgan, A.T., Nöthen, M.M., Pausova, Z., Pennell, C.E., Pennington, B.F., Price, K.M., Rajagopal, V.M., Ramus, F., Richer, L., Simpson, N.H., Smith, S.D., Snowling, M.J., Stein, J., Strug, L.J., Talcott, J.B., Tiemeier, H., Schroeff, M.P. van der, Verhoef, E., Watkins, K.E., Wilkinson, M., Wright, M.J., Barr, C.L., Boomsma, D.I., Carreiras, M., Franken, M.J., Gruen, J.R., Luciano, M., Müller-Myhsok, B., Newbury, D.F., Olson, R.K., Paracchini, S., Paus, T., Plomin, R., Reilly, S., Schulte-Körne, G., Tomblin, J.B., Bergen, E. van, Whitehouse, A.J.O., Willcutt, E.G., Pourcain, B. St, Francks, C., Fisher, S.E., St Pourcain, B., Génétique humaine et fonctions cognitives - Human Genetics and Cognitive Functions (GHFC (UMR_3571 / U-Pasteur_1)), Institut Pasteur [Paris] (IP)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Cité (UPCité), Laboratoire de sciences cognitives et psycholinguistique (LSCP), Département d'Etudes Cognitives - ENS Paris (DEC), École normale supérieure - Paris (ENS-PSL), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-École normale supérieure - Paris (ENS-PSL), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-École des hautes études en sciences sociales (EHESS)-Centre National de la Recherche Scientifique (CNRS), Human genetics, APH - Aging & Later Life, APH - Mental Health, Biological Psychology, Complex Trait Genetics, Amsterdam Neuroscience - Complex Trait Genetics, APH - Health Behaviors & Chronic Diseases, APH - Personalized Medicine, Amsterdam Reproduction & Development, APH - Methodology, LEARN! - Educational neuroscience, learning and development, Child and Adolescent Psychiatry / Psychology, Otorhinolaryngology and Head and Neck Surgery, STEMM - Stem Cells and Metabolism Research Program, Juha Kere / Principal Investigator, Research Programs Unit, University of Helsinki, Language, RS: FPN CN 7, The Royal Society, University of St Andrews. Cellular Medicine Division, University of St Andrews. School of Medicine, University of St Andrews. Centre for Biophotonics, University of St Andrews. Biomedical Sciences Research Complex, University of St Andrews. Institute of Behavioural and Neural Sciences, and University of St Andrews. St Andrews Bioinformatics Unit

Subjects

Neuroinformatics, Adult, kieli ja kielet, Adolescent, Individuality, QH426 Genetics, Polymorphism, Single Nucleotide, lukeminen, Language in Interaction, Young Adult, SDG 3 - Good Health and Well-being, RA0421, reading, RA0421 Public health. Hygiene. Preventive Medicine, Humans, Speech, study, Polymorphism, Reading j, Preschool, Child, QH426, perinnöllisyys, Genome-wide Association Study, Language, Meta-analysis, Reading, MCC, Neurodevelopmental disorders Donders Center for Medical Neuroscience [Radboudumc 7], genome-wide association study, language, Multidisciplinary, meta-analyysi, 1184 Genetics, developmental biology, physiology, kielitaito, [SDV.NEU.SC]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Cognitive Sciences, DAS, Single Nucleotide, meta-analysis, Genetic Loci, Child, Preschool, Genome-Wide Association Study, perimä, lukutaito, genome-wide association, SDG 4 - Quality Education

Abstract

Published August 23, 2022 The use of spoken and written language is a fundamental human capacity. Individual differences in reading- and language-related skills are influenced by genetic variation, with twin-based heritability estimates of 30 to 80% depending on the trait. The genetic architecture is complex, heterogeneous, and multifactorial, but investigations of contributions of single-nucleotide polymorphisms (SNPs) were thus far underpowered. We present a multicohort genome-wide association study (GWAS) of five traits assessed individually using psychometric measures (word reading, nonword reading, spelling, phoneme awareness, and nonword repetition) in samples of 13,633 to 33,959 participants aged 5 to 26 y. We identified genome-wide significant association with word reading (rs11208009, P = 1.098 × 1028) at a locus that has not been associated with intelligence or educational attainment. All five reading-/language-related traits showed robust SNP heritability, accounting for 13 to 26% of trait variability. Genomic structural equation modeling revealed a shared genetic factor explaining most of the variation in word/nonword reading, spelling, and phoneme awareness, which only partially overlapped with genetic variation contributing to nonword repetition, intelligence, and educational attainment. A multivariate GWAS of word/nonword reading, spelling, and phoneme awareness maximized power for follow-up investigation. Genetic correlation analysis with neuroimaging traits identified an association with the surface area of the banks of the left superior temporal sulcus, a brain region linked to the processing of spoken and written language. Heritability was enriched for genomic elements regulating gene expression in the fetal brain and in chromosomal regions that are depleted of Neanderthal variants. Together, these results provide avenues for deciphering the biological underpinnings of uniquely human traits. We thank all the children, twins, families, and participants who took part and are taking part in the 22 cohorts whose data contributed to these GWAS meta-analyses; the staff working on the different cohorts, including volunteers, study coordinators, interviewers, teachers, nurses, research scientists, general practitioners, midwives, psychologists, psychometrists, computer and laboratory technicians, and colleagues who assisted in the quality control and preparation of the imputed GWAS data; and the pharmacies and hospitals that were involved. B.M., B.M.-M., B.S.P., C.F., E.E., E.V., G.A., M.v.D., and S.E.F. are supported by the Max Planck Society. A.G. and T.F.M.A. were supported by the Munich Cluster for Systems Neurology (SyNergy), and A.G. was supported by Fondazione Umberto Veronesi. A.T.M. is supported by National Health and Medical Research Council of Australia (NHMRC) Grants 1105008 and 1195955 and Centre of Research Excellence Grant 1116976. A.J.O.W. is supported by NHMRC Grant 1173896. B.S.P. is supported by Simons Foundation Autism Research Initiative Grant 514787. C.Y.S. works in the Medical Research Council Integrative Epidemiology Unit at the University of Bristol (MC_UU_00011/3). D.I.B. acknowledges Royal Netherlands Academy of Science Professor Award PAH/6635. E.E. is supported by NIH Grant R01DC016977. E.G.W. and J.R.G. are supported by National Institute of Child Health and Human Development (NICHD) Grant P50 HD 27802. F.R. is supported by Agence Nationale de la Recherche Grants ANR-06-NEURO-019-01, ANR-17-EURE-0017 IEC, ANR-10-IDEX-0001-02 PSL, and ANR-11-BSV4-014-01 and European Commission Grant LSHM-CT-2005-018696. H.T. is supported by the Netherlands Organization for Scientific Research (NWO) and Netherlands Organisation for Health Research and Development (ZonMW) Grant VICI 016.VICI.170.200. J.C.D. was supported by NICHD Grant P50 HD 27802. J.J.M., J.B.To., and T.K. were supported by NIH Grant R01 DC014489. K.M.P. was supported by the Hospital for Sick Children Research Training Program (Restracomp). K.R. is supported by a Sir Henry Wellcome Postdoctoral Fellowship (213514/Z/18/Z). M.J.S. is supported by Wellcome Trust Grant WT082032MA. S.P. and F.A. are supported by Royal Society Grants UF150663 and RGF\EA\180141. T.B. is supported by Institut Pasteur, the Bettencourt-Schueller Foundation, and Université de Paris. The Adolescent Brain Cognitive Development Study is supported by the NIH and additional federal partners (NIH Grants U01DA041048, U01DA050989, U01DA051016, U01DA041022, U01DA051018, U01DA051037, U01DA050987, U01DA041174, U01DA041106, U01DA041117, U01DA041028, U01DA041134, U01DA050988, U01DA051039, U01DA041156, U01DA041025, U01DA041120, U01DA051038, U01DA041148, U01DA041093, U01DA041089, U24DA041123, and U24DA041147). The Aston Cohort was supported by funding from European Union (EU) Horizon 2020 Programme 641652 and Waterloo Foundation Grant 797/17290. The St. Andrews Bioinformatics Unit is funded by Wellcome Trust Grants 105621/Z/14/Z and 204821/Z/16/Z. ALSPAC is supported by UK Medical Research Council and Wellcome Grant 217065/Z/19/Z and the University of Bristol. A comprehensive list of grant funding is available on the ALSPAC website (http://www.bristol.ac.uk/alspac/external/documents/grant-acknowledgements.pdf). The Basque Center on Cognition, Brain and Language (BCBL) cohort was supported by the Basque Government through the Basic Excellence Research Centre program and the Agencia Estatal de Investigación through BCBL Severo Ochoa excellence accreditation. The Brisbane Adolescent Twin Sample was supported by Australian Research Council Grants A7960034, A79906588, A79801419, DP0212016, and DP0343921, with genotyping funded by the NHMRC Grant 389891. The Colorado Learning Disabilities Research Center cohort was supported by NICHD Grant P50 HD 27802. The Early Language in Victoria Study was supported by NHMRC Grant 436958. The Familial Influences on Literacy Abilities cohort is supported by the University of Amsterdam, the Max Planck Institue Nijmegen, and NWO Grants Rubicon 446-12-005 and VENI 451-15-017. The GRaD study was funded by the Manton Foundation, NIH Grants P50-HD027802 and K99-HD094902, and the Lambert Family. NeuroDys was funded by an EU Sixth Framework Program grant to the NeuroDys Consortium, Swiss National Science Foundation Grant 32-108130, and Austrian Science Fund Grant 18351-B02. The Netherlands Twin Register is funded by NWO Grants 480-04-004, 481-08-011, 056-32-010, 024.001.003, 480-15-001/674, 184.021.007, 184.033.111, and 56-464-14192; ZonMW Grants 911-09-032 and 912-10-020; the Amsterdam Public Health and Amsterdam Reproduction and Development Research Institutes; European Science Council Grant ERC Advanced 230374; EU Seventh Framework Program (FP7) Grant FP7/2007-2013: 602768; National Institute of Mental Health (NIMH) Grants U24 MH068457-06, R01 MH58799-03, and 1RC2 MH089995; and the Avera Institute for Human Genetics. The Pediatric Imaging, Neurocognition, and Genetics cohort is funded by NIH Grant RC2DA029475, the National Institute on Drug Abuse, and the Eunice Kennedy Shriver NICHD. The Philadelphia Neurodevelopmental Cohort is funded by NIH Grants RC2MH089983 and RC2MH089924, an institutional development award to the Center for Applied Genomics from The Children’s Hospital of Philadelphia, and a donation from Adele and Daniel Kubert and thanks the NIH data repository. The Raine study was supported by long-term funding from NHMRC Grants 572613, 403981, and 1059711 and Canadian Institutes of Health Research (CIHR) Grant MOP-82893. Funding was also provided by the University of Western Australia, Curtin University, the Women and Infants Research Foundation, the Telethon Kids Institute, Edith Cowan University, Murdoch University, the University of Notre Dame Australia, and the Raine Medical Research Foundation. The Raine study analyses were supported by the Pawsey Supercomputing Centre with funding from the Australian Government and the Government of Western Australia. The Saguenay Youth Study is supported by the CIHR, the Heart and Stroke Foundation of Quebec, and the Canadian Foundation for Innovation. The SLI Consortium was funded by Wellcome Trust Grant 076566 and UK Medical Research Council Grant G1000569. The Twins Early Development Study is supported by UK Medical Research Council Grants MR/V012878/1 and MR/M021475/1, NIH Grant AG046938, and the EU FP7 grant FP7/2007-2013/: 602768. Toronto was supported by CIHR Grant MOP-133440. UK Dyslexia was supported by Wellcome Trust Grants 076566/Z/05/Z and 075491/Z/04, Waterloo Foundation Grant 797–1720, EU Grant 018696, and Royal Society Grant UF100463. The York cohort was funded by Wellcome Trust Grant 082036/B/07/Z. We acknowledge iPSYCH for sharing their summary statistics. The iPSYCH team was supported by Lundbeck Foundation Grants R102-A9118, R155-2014-1724, and R248-2017-2003; NIMH Grant 1U01MH109514-01; and the Universities and University Hospitals of Aarhus and Copenhagen. The Danish National Biobank resource was supported by the Novo Nordisk Foundation. High-performance computer capacity was provided by the Center for Genomics and Personalized Medicine and the Centre for Integrative Sequencing, Aarhus University, Denmark.

Published

2022

3. Uncovering the genetic architecture of broad antisocial behavior through a genome-wide association study meta-analysis

Author

Tielbeek, J.J., Uffelmann, E., Williams, B.S., Colodro-Conde, L., Gagnon, É., Mallard, T.T., Levitt, B.E., Jansen, P.R., Johansson, A, Sallis, H.M., Pistis, G., Saunders, G.R.B., Allegrini, A.G., Rimfeld, K., Konte, B., Klein, M., Hartmann, A.M., Salvatore, J.E., Nolte, I.M., Demontis, D., Malmberg, A.L.K., Burt, S.A., Savage, J.E., Sugden, K., Poulton, R., Harris, K.M., Vrieze, S., McGue, M., Iacono, W.G., Roth Mota, N., Mill, J., Viana, J.F., Mitchell, B.L., Morosoli, J.J., Andlauer, T.F.M., Ouellet-Morin, I., Tremblay, R.E., Côté, S.M., Gouin, J.-P., Brendgen, M.R., Dionne, G., Vitaro, F., Lupton, M.K., Martin, N.G., Porjesz, B., Hesselbrock, V., Foroud, T., Agrawal, A., Edenberg, H.J., Liu, Y, Plawecki, M.H., Kuperman, S., Kramer, J.R., Meyers, J.M., Kamarajan, C., Pandey, A., Bierut, L., Rice, J., Bucholz, K.K., Schuckit, M.A., Tischfield, J., Hart, R., Almasy, L., Goate, A., Slesinger, P., Scott, D., Castelao, E., Räikkönen, K., Eriksson, J.G., Lahti, J., Hartman, C.A, Oldehinkel, A.J., Snieder, H., Liu, H., Preisig, M., Whipp, A., Vuoksimaa, E., Lu, Y., Jern, P., Rujescu, D., Giegling, I., Palviainen, T., Kaprio, J., Harden, K.P., Munafò, M.R., Morneau-Vaillancourt, G., Plomin, R., Viding, E., Boutwell, B.B., Aliev, F., Dick, D.M., Popma, A., Faraone, S.V, Børglum, A.D., Medland, S.E., Franke, B., Boivin, M., Pingault, J.-B., Glennon, J.C., Barnes, J.C., Fisher, S.E., Tielbeek, J.J., Uffelmann, E., Williams, B.S., Colodro-Conde, L., Gagnon, É., Mallard, T.T., Levitt, B.E., Jansen, P.R., Johansson, A, Sallis, H.M., Pistis, G., Saunders, G.R.B., Allegrini, A.G., Rimfeld, K., Konte, B., Klein, M., Hartmann, A.M., Salvatore, J.E., Nolte, I.M., Demontis, D., Malmberg, A.L.K., Burt, S.A., Savage, J.E., Sugden, K., Poulton, R., Harris, K.M., Vrieze, S., McGue, M., Iacono, W.G., Roth Mota, N., Mill, J., Viana, J.F., Mitchell, B.L., Morosoli, J.J., Andlauer, T.F.M., Ouellet-Morin, I., Tremblay, R.E., Côté, S.M., Gouin, J.-P., Brendgen, M.R., Dionne, G., Vitaro, F., Lupton, M.K., Martin, N.G., Porjesz, B., Hesselbrock, V., Foroud, T., Agrawal, A., Edenberg, H.J., Liu, Y, Plawecki, M.H., Kuperman, S., Kramer, J.R., Meyers, J.M., Kamarajan, C., Pandey, A., Bierut, L., Rice, J., Bucholz, K.K., Schuckit, M.A., Tischfield, J., Hart, R., Almasy, L., Goate, A., Slesinger, P., Scott, D., Castelao, E., Räikkönen, K., Eriksson, J.G., Lahti, J., Hartman, C.A, Oldehinkel, A.J., Snieder, H., Liu, H., Preisig, M., Whipp, A., Vuoksimaa, E., Lu, Y., Jern, P., Rujescu, D., Giegling, I., Palviainen, T., Kaprio, J., Harden, K.P., Munafò, M.R., Morneau-Vaillancourt, G., Plomin, R., Viding, E., Boutwell, B.B., Aliev, F., Dick, D.M., Popma, A., Faraone, S.V, Børglum, A.D., Medland, S.E., Franke, B., Boivin, M., Pingault, J.-B., Glennon, J.C., Barnes, J.C., and Fisher, S.E.

Abstract

Item does not contain fulltext

Published

2022

4. Schizophrenia polygenic risk is associated with child mental health problems through early childhood adversity

Author

Bolhuis, K., Steenkamp, L.R., Blanken, L.M.E., Neumann, A., Jansen, P.R., Hillegers, M.H.J., Cecil, C.A.M., Tiemeier, H., and Kushner, S.A.

Subjects

Stressful life events, Generation R, Gene–environment, Population-based, Psychosis

Abstract

Previous studies have shown that schizophrenia polygenic risk predicts a multitude of mental health problems in the general population. Yet it is unclear by which mechanisms these associations arise. Here, we explored a possible gene-environment correlation in the association of schizophrenia polygenic risk with mental health problems via childhood adversity. This study was embedded in the population-based Generation R Study, including N = 1901 participants with genotyping for schizophrenia polygenic risk, maternal reporting of childhood adversity, and Child Behaviour Checklist measurement of mental health problems. Independent replication was attempted in the Avon Longitudinal Study of Parents and Children (ALSPAC; N = 3641). Associations were analysed with Poisson regression and statistical mediation analysis. Higher burden of schizophrenia polygenic risk was associated with greater exposure to childhood adversity (P-value threshold < 0.5: Generation R Study, OR = 1.08, 95%CI 1.02-1.15, P = 0.01; ALSPAC, OR = 1.02, 95%CI 1.01-1.03, P < 0.01). Childhood adversities partly explained the relationship of schizophrenia polygenic risk with emotional, attention, and thought problems (proportion explained, range 5-23%). Direct effects of schizophrenia polygenic risk and adversity on mental health outcomes were also observed. In summary, genetic liability to schizophrenia increased the risk for mental health problems in the general paediatric population through childhood adversity. Although this finding could result from a mediated causal relationship between genotype and mental health, we argue that these observations most likely reflect a gene-environment correlation, i.e. adversities are a marker for the genetic risk that parents transmit to children. These and similar recent findings raise important conceptual questions about preventative interventions aimed at reducing childhood adversities.

Published

2021

5. Prevalence of radiologically isolated syndrome in a pediatric population-based cohort: A longitudinal description of a rare diagnosis

Author

de Mol, C.L. (C. L.), Bruijstens, A.L. (A. L.), Jansen, P.R. (Philip), Dremmen, M.H.G. (Marjolein), Wong, Y.Y.M. (Yu Yi), Lugt, A. (Aad) van der, White, T.J.H. (Tonya), Neuteboom, R.F. (Rinze), de Mol, C.L. (C. L.), Bruijstens, A.L. (A. L.), Jansen, P.R. (Philip), Dremmen, M.H.G. (Marjolein), Wong, Y.Y.M. (Yu Yi), Lugt, A. (Aad) van der, White, T.J.H. (Tonya), and Neuteboom, R.F. (Rinze)

Abstract

Background: Radiologically isolated syndrome (RIS) is typified by multiple sclerosis (MS)-like lesions on imaging, without clinical MS symptoms. The prevalence of pediatric RIS is largely unknown. Objective: The objective of the study is to provide an estimated RIS prevalence in a population-based cohort of children. Methods: We used data from the Generation R study to identify the childhood RIS prevalence. Results: In 5238 participants, only one RIS case was identified (prevalence: 0.02%; 95% confidence interval (CI): 0.00–0.11). During a 62-month follow-up, imaging examinations showed accrual of new focal demyelinating lesions; however, no clinical MS symptoms occurred. Conclusions: This study shows that the occurrence of RIS in children from the general population is rare.

Published

2021

6. Genetic scores for adult subcortical volumes associate with subcortical volumes during infancy and childhood

Author

Lamballais, S. (Sander), Jansen, P.R. (Philip), Labrecque, J.A. (Jeremy A.), Ikram, M.A. (Arfan), White, T.J.H. (Tonya), Lamballais, S. (Sander), Jansen, P.R. (Philip), Labrecque, J.A. (Jeremy A.), Ikram, M.A. (Arfan), and White, T.J.H. (Tonya)

Abstract

Individual differences in subcortical brain volumes are highly heritable. Previous studies have identified genetic variants that underlie variation in subcortical volumes in adults. We tested whether those previously identified variants also affect subcortical regions during infancy and early childhood. The study was performed within the Generation R study, a prospective birth cohort. We calculated polygenic scores based on reported GWAS for volumes of the accumbens, amygdala, brainstem, caudate nucleus, globus pallidus, putamen, and thalamus. Participants underwent cranial ultrasound around 7 weeks of age (range: 3–20), and we obtained metrics for the gangliothalamic ovoid, a predecessor of the basal ganglia. Furthermore, the children participated in a magnetic resonance imaging (MRI) study around the age of 10 years (range: 9–12). A total of 340 children had complete data at both examinations. Polygenic scores primarily associated with their corresponding volumes at 10 years of age. The scores also moderately related to the diameter of the gangliothalamic ovoid on cranial ultrasound. Mediation analysis showed that the genetic influence on subcortical volumes at 10 years was only mediated for 16.5–17.6% of the total effect through the gangliothalamic ovoid diameter at 7 weeks of age. Combined, these findings suggest that previously identified genetic variants in adults are relevant for subcortical volumes during early life, and that they affect both prenatal and postnatal development of the subcortical regions.

Published

2021

7. Polygenic Risk Scores for Developmental Disorders, Neuromotor Functioning During Infancy, and Autistic Traits in Childhood

Author

Serdarevic, F. (Fadila), Tiemeier, H.W. (Henning), Jansen, P.R. (Philip), Alemany, S. (Silvia), Xerxa, Y. (Yllza), Neumann, A. (Alexander), Robinson, E. (Elise), Hillegers, M.H.J. (Manon), Verhulst, F.C. (Frank), Ghassabian, A. (Akhgar), Serdarevic, F. (Fadila), Tiemeier, H.W. (Henning), Jansen, P.R. (Philip), Alemany, S. (Silvia), Xerxa, Y. (Yllza), Neumann, A. (Alexander), Robinson, E. (Elise), Hillegers, M.H.J. (Manon), Verhulst, F.C. (Frank), and Ghassabian, A. (Akhgar)

Abstract

Background: Impaired neuromotor development is often one of the earliest observations in children with autism spectrum disorder (ASD). We investigated whether a genetic predisposition to developmental disorders was associated with nonoptimal neuromotor development during infancy and examined the genetic correlation between nonoptimal neuromotor development and autistic traits in the general population. Methods: In a population-based cohort in The Netherlands (2002–2006), we calculated polygenic risk scores (PRSs) for ASD and attention-deficit/hyperactivity disorder (ADHD) using genome-wide association study summary statistics. In 1921 children with genetic data, parents rated autistic traits at 6 years of age. Among them, 1174 children (61.1%) underwent neuromotor examinations (tone, responses, senses, and other observations) during infancy (9–20 weeks of age). We used linear regressions to examine associations of PRSs with neuromotor scores and autistic traits. We performed a bivariate genome-based restricted maximum likelihood analysis to explore whether genetic susceptibility underlies the association between neuromotor development and autistic traits. Results: Higher PRSs for ASD were associated with less optimal overall infant neuromotor development, in particular low muscle tone. Higher PRSs for ADHD were associated with less optimal senses. PRSs for ASD and those for ADHD both were associated with autistic traits. The single nucleotide polymorphism–based heritability of overall motor development was 20% (SE = .21) and of autistic traits was 68% (SE = .26). The genetic correlation between overall motor development and autistic traits was .35 (SE = .21, p < .001). Conclusions: We found that genetic liabilities for ASD and ADHD covary with neuromotor development during infancy. Shared genetic liability might partly explain the association between nonoptimal neuromotor development during infancy and autistic traits in childhood.

Published

2020

8. [Polygenic risk prediction of common diseases: from epidemiology to clinical application]

Author

Jansen, P.R., Broeders, M.J.M., Cornel, M.C, and Meijers-Heijboer, H.

Subjects

Women's cancers Radboud Institute for Health Sciences [Radboudumc 17]

Abstract

Item does not contain fulltext Since the first map of the human genome was published in 2001 our knowledge about our genetic code has increased exponentially. In addition to high-risk genes for monogenic diseases, such as Huntington's disease and cystic fibrosis, for a number of common diseases, such as breast cancer and cardiovascular disease, many genetic variants that each have a slight increased-risk effect, have been identified via genome-wide association studies (GWAS). A polygenic risk score (PRS) can be calculated on the basis of these single-nucleotide polymorphisms (SNPs), by which an increasingly accurate prediction can be made of an individual's risk for diseases. The results of epidemiological studies in which a PRS is used to predict an individual's total genetic risk for particular diseases are promising. In the future, the PRS could be a valuable addition to traditional monogenic tests. It is, however, important that the predictive value of a genetic risk profile increases further and that it becomes more clear how a clinician must interpret this type of genetic profile - in combination with traditional risk factors.

Published

2019

9. Genetic mapping and evolutionary analysis of human-expanded cognitive networks

Author

Wei, Y. (Yongbin), de Lange, S.C. (Siemon C.), Scholtens, L.H. (Lianne H.), Watanabe, K. (Kyoko), Ardesch, D.J. (Dirk Jan), Jansen, P.R. (Philip), Savage, J.E. (Jeanne E.), Li, L. (Longchuan), Preuss, T.M. (Todd M.), Rilling, J.K. (James K.), Posthuma, D. (Danielle), Heuvel, M. (Martijn) van den, Wei, Y. (Yongbin), de Lange, S.C. (Siemon C.), Scholtens, L.H. (Lianne H.), Watanabe, K. (Kyoko), Ardesch, D.J. (Dirk Jan), Jansen, P.R. (Philip), Savage, J.E. (Jeanne E.), Li, L. (Longchuan), Preuss, T.M. (Todd M.), Rilling, J.K. (James K.), Posthuma, D. (Danielle), and Heuvel, M. (Martijn) van den

Abstract

Cognitive brain networks such as the default-mode network (DMN), frontoparietal network, and salience network, are key functional networks of the human brain. Here we show that the rapid evolutionary cortical expansion of cognitive networks in the human brain, and most pronounced the DMN, runs parallel with high expression of human-accelerated genes (HAR genes). Using comparative transcriptomics analysis, we present that HAR genes are differentially more expressed in higher-order cognitive networks in humans compared to chimpanzees and macaques and that genes with high expression in the DMN are involved in synapse and dendrite formation. Moreover, HAR and DMN genes show significant associations with individual variations in DMN functional activity, intelligence, sociability, and mental conditions such as schizophrenia and autism. Our results suggest that the expansion of higher-order functional networks subserving increasing cognitive properties has been an important locus of genetic changes in recent human brain evolution.

Published

2019

10. Population Studies of the Heritable Influences on the Mind and Brain

Author

Jansen, P.R. (Philip) and Jansen, P.R. (Philip)

Abstract

Decades of prior genetic research using twin modelling designs has shown that differences in human behavior are strongly influenced by differences in our DNA. Through advances in DNA genotyping it has become feasible to study the genetic factors that contribute to human variation by large-scale genome-wide association studies (GWAS). In this thesis, our aim was to study the genetic variants, genes and genetic pathways that explain variation in a broad diversity of behavioral outcomes making use of big data analyses in large population cohorts. By integrating GWAS results and GWAS-derived polygenic risk scores with gene-expression data, functional gene-sets and MRI imaging of the brain, this thesis provides a step forward in understanding the association between genetic variation and health-related phenotypes, including intelligence, neuroticism and depression, and insomnia, and the pathways and cell-types in the brain through which these genetic factors act.

Published

2019

11. Psychiatric Polygenic Risk Scores as Predictor for Attention Deficit/Hyperactivity Disorder and Autism Spectrum Disorder in a Clinical Child and Adolescent Sample

Author

Jansen, A.G. (Arija G.), Dieleman, G.C. (Gwen), Jansen, P.R. (Philip), Verhulst, F.C. (Frank), Posthuma, D. (Danielle), Polderman, T.J.C. (Tinca J. C.), Jansen, A.G. (Arija G.), Dieleman, G.C. (Gwen), Jansen, P.R. (Philip), Verhulst, F.C. (Frank), Posthuma, D. (Danielle), and Polderman, T.J.C. (Tinca J. C.)

Abstract

Neurodevelopmental disorders such as attention deficit/hyperactivity disorder (ADHD) and autism spectrum disorder (ASD) are highly heritable and influenced by many single nucleotide polymorphisms (SNPs). SNPs can be used to calculate individual polygenic risk scores (PRS) for a disorder. We aim to explore the association between the PRS for ADHD, ASD and for Schizophrenia (SCZ), and ADHD and ASD diagnoses in a clinical child and adolescent population. Based on the most recent genome wide association studies of ADHD, ASD and SCZ, PRS of each disorder were calculated for individuals of a clinical child and adolescent target sample (N = 688) and for adult controls (N = 943). We tested with logistic regression analyses for an association with (1) a single diagnosis of ADHD (N = 280), (2) a single diagnosis of ASD (N = 295), and (3) combining the two diagnoses, thus subjects with either ASD, ADHD or both (N = 688). Our results showed a significant association of the ADHD PRS with ADHD status (OR 1.6, P = 1.39 × 10−07) and with the combined ADHD/ASD status (OR 1.36, P = 1.211 × 10−05), but not with ASD status (OR 1.14, P = 1). No associations for the ASD and SCZ PRS were observed. In sum, the PRS of ADHD is significantly associated with the combined ADHD/ASD status. Yet, this association is primarily driven by ADHD status, suggesting disorder specific genetic effects of the ADHD PRS.

Published

2019

12. Common Polygenic Variations for Psychiatric Disorders and Cognition in Relation to Brain Morphology in the General Pediatric Population

Author

Alemany, S. (Silvia), Jansen, P.R. (Philip), Muetzel, R.L. (Ryan), Marques, N. (Natália), El Marroun, H. (Hanan), Jaddoe, V.W.V. (Vincent), Polderman, T.J.C. (Tinca), Tiemeier, H.W. (Henning), Posthuma, D. (Danielle), White, T.J.H. (Tonya), Alemany, S. (Silvia), Jansen, P.R. (Philip), Muetzel, R.L. (Ryan), Marques, N. (Natália), El Marroun, H. (Hanan), Jaddoe, V.W.V. (Vincent), Polderman, T.J.C. (Tinca), Tiemeier, H.W. (Henning), Posthuma, D. (Danielle), and White, T.J.H. (Tonya)

Abstract

___Objective:___ This study examined the relation between polygenic scores (PGSs) for 5 major psychiatric disorders and 2 cognitive traits with brain magnetic resonance imaging morphologic measurements in a l

Published

2019

13. Interaction of schizophrenia polygenic risk and cortisol level on pre-adolescent brain structure

Author

Bolhuis, K. (Koen), Tiemeier, H.W. (Henning), Jansen, P.R. (Philip), Muetzel, R.L. (Ryan), Neumann, A. (Alexander), Hillegers, M.H.J. (Manon), van den Akker, E.T.L. (Erica T.L.), Rossum, E.F.C. (Liesbeth) van, Jaddoe, V.W.V. (Vincent), Vernooij, M.W. (Meike W.), White, T. (Tonya), Kushner, S.A. (Steven A.), Bolhuis, K. (Koen), Tiemeier, H.W. (Henning), Jansen, P.R. (Philip), Muetzel, R.L. (Ryan), Neumann, A. (Alexander), Hillegers, M.H.J. (Manon), van den Akker, E.T.L. (Erica T.L.), Rossum, E.F.C. (Liesbeth) van, Jaddoe, V.W.V. (Vincent), Vernooij, M.W. (Meike W.), White, T. (Tonya), and Kushner, S.A. (Steven A.)

Abstract

The etiology of schizophrenia is multi-factorial with early neurodevelopmental antecedents, likely to result from a complex interaction of genetic and environmental risk. However, few studies have examined how schizophrenia polygenic risk scores (PRS) are moderated by environmental factors in shaping neurodevelopmental brain structure, prior to the onset of psychotic symptoms. Here, we examined whether hair cortisol, a quantitative metric of chronic stress, moderated the association between genetic risk for schizophrenia and pre-adolescent brain structure. This study was embedded within the Generation R Study, involving pre-adolescents of European ancestry assessed regarding schizophrenia PRS, hair cortisol, and brain imaging (n = 498 structural; n = 526 diffusion tensor imaging). Linear regression was performed to determine the association between schizophrenia PRS, hair cortisol level, and brain imaging outcomes. Although no single measure exceeded the multiple testing threshold, nominally significant interactions were observed for total ventricle volume (P interaction = 0.02) and global white matter microstructure (P interaction = 0.01) – two of the most well replicated brain structural findings in schizophrenia. These findings provide suggestive evidence for the joint effects of schizophrenia liability and cortisol levels on brain correlates in the pediatric general population. Given the widely replicated finding of ventricular enlargement and lower white matter integrity among schizophrenia patients, our findings generate novel hypotheses for future research on ge

Published

2019

14. Genome-wide analysis of insomnia in 1,331,010 individuals identifies new risk loci and functional pathways.

Author

Jansen, P.R., Watanabe, K., Stringer, S., Skene, N., Bryois, J., Hammerschlag, A.R., De Leeuw, C.A., Benjamins, Jeroen S, Munoz-Manchado, A.B., Nagel, M., Savage, J.E., Tiemeier, H., White, T., The 23andMe Research Team, Tung, J.Y., Hinds, D.A., Vacic, V., Wang, X., Sullivan, P.F., Van der Sluis, S., Polderman, T.J.C., Smit, A.B., Hjerling-Leffler, J., van Someren, E.J.W., Posthuma, Danielle, Jansen, P.R., Watanabe, K., Stringer, S., Skene, N., Bryois, J., Hammerschlag, A.R., De Leeuw, C.A., Benjamins, Jeroen S, Munoz-Manchado, A.B., Nagel, M., Savage, J.E., Tiemeier, H., White, T., The 23andMe Research Team, Tung, J.Y., Hinds, D.A., Vacic, V., Wang, X., Sullivan, P.F., Van der Sluis, S., Polderman, T.J.C., Smit, A.B., Hjerling-Leffler, J., van Someren, E.J.W., and Posthuma, Danielle

Abstract

Insomnia is the second most prevalent mental disorder, with no sufficient treatment available. Despite substantial heritability, insight into the associated genes and neurobiological pathways remains limited. Here, we use a large genetic association sample (n = 1,331,010) to detect novel loci and gain insight into the pathways, tissue and cell types involved in insomnia complaints. We identify 202 loci implicating 956 genes through positional, expression quantitative trait loci, and chromatin mapping. The meta-analysis explained 2.6% of the variance. We show gene set enrichments for the axonal part of neurons, cortical and subcortical tissues, and specific cell types, including striatal, hypothalamic, and claustrum neurons. We found considerable genetic correlations with psychiatric traits and sleep duration, and modest correlations with other sleep-related traits. Mendelian randomization identified the causal effects of insomnia on depression, diabetes, and cardiovascular disease, and the protective effects of educational attainment and intracranial volume. Our findings highlight key brain areas and cell types implicated in insomnia, and provide new treatment targets.

Published

2019

15. Genome-wide association meta-analysis in 269,867 individuals identifies new genetic and functional links to intelligence

Author

Savage, J.E. Jansen, P.R. Stringer, S. Watanabe, K. Bryois, J. De Leeuw, C.A. Nagel, M. Awasthi, S. Barr, P.B. Coleman, J.R.I. Grasby, K.L. Hammerschlag, A.R. Kaminski, J.A. Karlsson, R. Krapohl, E. Lam, M. Nygaard, M. Reynolds, C.A. Trampush, J.W. Young, H. Zabaneh, D. Hägg, S. Hansell, N.K. Karlsson, I.K. Linnarsson, S. Montgomery, G.W. Muñoz-Manchado, A.B. Quinlan, E.B. Schumann, G. Skene, N.G. Webb, B.T. White, T. Arking, D.E. Avramopoulos, D. Bilder, R.M. Bitsios, P. Burdick, K.E. Cannon, T.D. Chiba-Falek, O. Christoforou, A. Cirulli, E.T. Congdon, E. Corvin, A. Davies, G. Deary, I.J. Derosse, P. Dickinson, D. Djurovic, S. Donohoe, G. Conley, E.D. Eriksson, J.G. Espeseth, T. Freimer, N.A. Giakoumaki, S. Giegling, I. Gill, M. Glahn, D.C. Hariri, A.R. Hatzimanolis, A. Keller, M.C. Knowles, E. Koltai, D. Konte, B. Lahti, J. Le Hellard, S. Lencz, T. Liewald, D.C. London, E. Lundervold, A.J. Malhotra, A.K. Melle, I. Morris, D. Need, A.C. Ollier, W. Palotie, A. Payton, A. Pendleton, N. Poldrack, R.A. Räikkönen, K. Reinvang, I. Roussos, P. Rujescu, D. Sabb, F.W. Scult, M.A. Smeland, O.B. Smyrnis, N. Starr, J.M. Steen, V.M. Stefanis, N.C. Straub, R.E. Sundet, K. Tiemeier, H. Voineskos, A.N. Weinberger, D.R. Widen, E. Yu, J. Abecasis, G. Andreassen, O.A. Breen, G. Christiansen, L. Debrabant, B. Dick, D.M. Heinz, A. Hjerling-Leffler, J. Ikram, M.A. Kendler, K.S. Martin, N.G. Medland, S.E. Pedersen, N.L. Plomin, R. Polderman, T.J.C. Ripke, S. Van Der Sluis, S. Sullivan, P.F. Vrieze, S.I. Wright, M.J. Posthuma, D.

Abstract

Intelligence is highly heritable 1 and a major determinant of human health and well-being 2 . Recent genome-wide meta-analyses have identified 24 genomic loci linked to variation in intelligence 3-7 , but much about its genetic underpinnings remains to be discovered. Here, we present a large-scale genetic association study of intelligence (n = 269,867), identifying 205 associated genomic loci (190 new) and 1,016 genes (939 new) via positional mapping, expression quantitative trait locus (eQTL) mapping, chromatin interaction mapping, and gene-based association analysis. We find enrichment of genetic effects in conserved and coding regions and associations with 146 nonsynonymous exonic variants. Associated genes are strongly expressed in the brain, specifically in striatal medium spiny neurons and hippocampal pyramidal neurons. Gene set analyses implicate pathways related to nervous system development and synaptic structure. We confirm previous strong genetic correlations with multiple health-related outcomes, and Mendelian randomization analysis results suggest protective effects of intelligence for Alzheimer's disease and ADHD and bidirectional causation with pleiotropic effects for schizophrenia. These results are a major step forward in understanding the neurobiology of cognitive function as well as genetically related neurological and psychiatric disorders. © 2018 The Author(s).

Published

2018

16. Widespread white matter microstructural differences in schizophrenia across 4322 individuals: results from the ENIGMA Schizophrenia DTI Working Group

Author

Kelly, S., Jahanshad, N., Zalesky, A., Kochunov, P., Agartz, I., Alloza, C., Andreassen, O.A., Arango, C., Banaj, N., Bouix, S., Bousman, C.A., Brouwer, R.M., Bruggemann, J., Bustillo, J., Cahn, W., Calhoun, V., Cannon, D., Carr, V., Catts, S., Chen, J., Chen, J.X., Chen, X, Chiapponi, C., Cho, K.K., Ciullo, V., Corvin, A.S., Crespo-Facorro, B., Cropley, V., Rossi, P., Diaz-Caneja, C.M., Dickie, E.W., Ehrlich, S., Fan, F.M., Faskowitz, J., Fatouros-Bergman, H., Flyckt, L., Ford, J.M., Fouche, J.P., Fukunaga, M., Gill, M., Glahn, D.C., Gollub, R., Goudzwaard, E.D., Guo, H, Gur, R.E., Gur, R.C., Gurholt, T.P., Hashimoto, R., Hatton, S.N., Henskens, F.A., Hibar, D.P., Hickie, I.B., Hong, L.E., Horacek, J., Howells, F.M., Pol, H.E., Hyde, C.L., Isaev, D., Jablensky, A., Jansen, P.R., Janssen, J, Jonsson, E.G., Jung, L.A., Kahn, R.S., Kikinis, Z., Liu, K, Klauser, P., Knochel, C., Kubicki, M., Lagopoulos, J., Langen, C., Lawrie, S., Lenroot, R.K., Lim, K.O., Lopez-Jaramillo, C., Lyall, A., Magnotta, V., Mandl, R.C.W., Mathalon, D.H., McCarley, R.W., McCarthy-Jones, S., McDonald, C., McEwen, S., McIntosh, A., Melicher, T., Mesholam-Gately, R.I., Michie, P.T., Mowry, B., Mueller, B.A., Newell, D.T., O'Donnell, P., Oertel-Knochel, V., Oestreich, L., Paciga, S.A., Pantelis, C., Pasternak, O., Pearlson, G., Pellicano, G.R., Pereira, A., Zapata, J., Sprooten, E., Thompson, P.M., Donohoe, G., Kelly, S., Jahanshad, N., Zalesky, A., Kochunov, P., Agartz, I., Alloza, C., Andreassen, O.A., Arango, C., Banaj, N., Bouix, S., Bousman, C.A., Brouwer, R.M., Bruggemann, J., Bustillo, J., Cahn, W., Calhoun, V., Cannon, D., Carr, V., Catts, S., Chen, J., Chen, J.X., Chen, X, Chiapponi, C., Cho, K.K., Ciullo, V., Corvin, A.S., Crespo-Facorro, B., Cropley, V., Rossi, P., Diaz-Caneja, C.M., Dickie, E.W., Ehrlich, S., Fan, F.M., Faskowitz, J., Fatouros-Bergman, H., Flyckt, L., Ford, J.M., Fouche, J.P., Fukunaga, M., Gill, M., Glahn, D.C., Gollub, R., Goudzwaard, E.D., Guo, H, Gur, R.E., Gur, R.C., Gurholt, T.P., Hashimoto, R., Hatton, S.N., Henskens, F.A., Hibar, D.P., Hickie, I.B., Hong, L.E., Horacek, J., Howells, F.M., Pol, H.E., Hyde, C.L., Isaev, D., Jablensky, A., Jansen, P.R., Janssen, J, Jonsson, E.G., Jung, L.A., Kahn, R.S., Kikinis, Z., Liu, K, Klauser, P., Knochel, C., Kubicki, M., Lagopoulos, J., Langen, C., Lawrie, S., Lenroot, R.K., Lim, K.O., Lopez-Jaramillo, C., Lyall, A., Magnotta, V., Mandl, R.C.W., Mathalon, D.H., McCarley, R.W., McCarthy-Jones, S., McDonald, C., McEwen, S., McIntosh, A., Melicher, T., Mesholam-Gately, R.I., Michie, P.T., Mowry, B., Mueller, B.A., Newell, D.T., O'Donnell, P., Oertel-Knochel, V., Oestreich, L., Paciga, S.A., Pantelis, C., Pasternak, O., Pearlson, G., Pellicano, G.R., Pereira, A., Zapata, J., Sprooten, E., Thompson, P.M., and Donohoe, G.

Abstract

Contains fulltext : 193179.pdf (Publisher’s version ) (Open Access), The regional distribution of white matter (WM) abnormalities in schizophrenia remains poorly understood, and reported disease effects on the brain vary widely between studies. In an effort to identify commonalities across studies, we perform what we believe is the first ever large-scale coordinated study of WM microstructural differences in schizophrenia. Our analysis consisted of 2359 healthy controls and 1963 schizophrenia patients from 29 independent international studies; we harmonized the processing and statistical analyses of diffusion tensor imaging (DTI) data across sites and meta-analyzed effects across studies. Significant reductions in fractional anisotropy (FA) in schizophrenia patients were widespread, and detected in 20 of 25 regions of interest within a WM skeleton representing all major WM fasciculi. Effect sizes varied by region, peaking at (d=0.42) for the entire WM skeleton, driven more by peripheral areas as opposed to the core WM where regions of interest were defined. The anterior corona radiata (d=0.40) and corpus callosum (d=0.39), specifically its body (d=0.39) and genu (d=0.37), showed greatest effects. Significant decreases, to lesser degrees, were observed in almost all regions analyzed. Larger effect sizes were observed for FA than diffusivity measures; significantly higher mean and radial diffusivity was observed for schizophrenia patients compared with controls. No significant effects of age at onset of schizophrenia or medication dosage were detected. As the largest coordinated analysis of WM differences in a psychiatric disorder to date, the present study provides a robust profile of widespread WM abnormalities in schizophrenia patients worldwide. Interactive three-dimensional visualization of the results is available at www.enigma-viewer.org.

Published

2018

17. Widespread white matter microstructural differences in schizophrenia across 4322 individuals: Results from the ENIGMA Schizophrenia DTI Working Group.

Author

Faskowitz J., Jablensky A., Jansen P.R., Janssen J., Jonsson E.G., Jung L.A., Kahn R.S., Kikinis Z., Liu K., Klauser P., Knochel C., Kubicki M., Lagopoulos J., Langen C., Lawrie S., Lenroot R.K., Lim K.O., Lopez-Jaramillo C., Lyall A., Magnotta V., Mandl R.C.W., McIntosh A., Melicher T., Mesholam-Gately R.I., Michie P.T., Mowry B., Mueller B.A., Newell D.T., O'Donnell P., Oertel-Knochel V., Oestreich L., Paciga S.A., Pantelis C., Pasternak O., Pearlson G., Pellicano G.R., Pereira A., Pineda Zapata J., Piras F., Potkin S.G., Preda A., Rasser P.E., Roalf D.R., Roiz R., Roos A., Rotenberg D., Satterthwaite T.D., Savadjiev P., Schall U., Scott R.J., Seal M.L., Seidman L.J., Shannon Weickert C., Whelan C.D., Shenton M.E., Kwon J.S., Spalletta G., Spaniel F., Sprooten E., Stablein M., Stein D.J., Tan Y., Tan S., Tang S., Temmingh H.S., Westlye L.T., Tonnesen S., Tordesillas-Gutierrez D., Doan N.T., Vaidya J., Van Haren N.E.M., Vargas C.D., Vecchio D., Velakoulis D., Voineskos A., Voyvodic J.Q., Wang Z., Wan P., Wei D., Weickert T.W., Whalley H., White T., Whitford T.J., Wojcik J.D., Xiang H., Xie Z., Yamamori H., Yang F., Yao N., Zhang G., Zhao J., Van Erp T.G.M., Turner J., Thompson P.M., Donohoe G., Sundram S., Kelly S., Jahanshad N., Zalesky A., Kochunov P., Agartz I., Alloza C., Andreassen O.A., Arango C., Banaj N., Bouix S., Bousman C.A., Brouwer R.M., Bruggemann J., Bustillo J., Cahn W., Calhoun V., Cannon D., Carr V., Catts S., Chen J., Chen J.-X., Chen X., Chiapponi C., Cho K.K., Ciullo V., Corvin A.S., Crespo-Facorro B., Cropley V., De Rossi P., Diaz-Caneja C.M., Dickie E.W., Ehrlich S., Fan F.-M., Fatouros-Bergman H., Flyckt L., Ford J.M., Fouche J.-P., Fukunaga M., Gill M., Glahn D.C., Gollub R., Goudzwaard E.D., Guo H., Gur R.E., Gur R.C., Gurholt T.P., Hashimoto R., Hatton S.N., Henskens F.A., Hibar D.P., Hickie I.B., Hong L.E., Horacek J., Howells F.M., Hulshoff Pol H.E., Hyde C.L., Isaev D., Mathalon D.H., McCarley R.W., McCarthy-Jones S., McDonald C., McEwen S., Faskowitz J., Jablensky A., Jansen P.R., Janssen J., Jonsson E.G., Jung L.A., Kahn R.S., Kikinis Z., Liu K., Klauser P., Knochel C., Kubicki M., Lagopoulos J., Langen C., Lawrie S., Lenroot R.K., Lim K.O., Lopez-Jaramillo C., Lyall A., Magnotta V., Mandl R.C.W., McIntosh A., Melicher T., Mesholam-Gately R.I., Michie P.T., Mowry B., Mueller B.A., Newell D.T., O'Donnell P., Oertel-Knochel V., Oestreich L., Paciga S.A., Pantelis C., Pasternak O., Pearlson G., Pellicano G.R., Pereira A., Pineda Zapata J., Piras F., Potkin S.G., Preda A., Rasser P.E., Roalf D.R., Roiz R., Roos A., Rotenberg D., Satterthwaite T.D., Savadjiev P., Schall U., Scott R.J., Seal M.L., Seidman L.J., Shannon Weickert C., Whelan C.D., Shenton M.E., Kwon J.S., Spalletta G., Spaniel F., Sprooten E., Stablein M., Stein D.J., Tan Y., Tan S., Tang S., Temmingh H.S., Westlye L.T., Tonnesen S., Tordesillas-Gutierrez D., Doan N.T., Vaidya J., Van Haren N.E.M., Vargas C.D., Vecchio D., Velakoulis D., Voineskos A., Voyvodic J.Q., Wang Z., Wan P., Wei D., Weickert T.W., Whalley H., White T., Whitford T.J., Wojcik J.D., Xiang H., Xie Z., Yamamori H., Yang F., Yao N., Zhang G., Zhao J., Van Erp T.G.M., Turner J., Thompson P.M., Donohoe G., Sundram S., Kelly S., Jahanshad N., Zalesky A., Kochunov P., Agartz I., Alloza C., Andreassen O.A., Arango C., Banaj N., Bouix S., Bousman C.A., Brouwer R.M., Bruggemann J., Bustillo J., Cahn W., Calhoun V., Cannon D., Carr V., Catts S., Chen J., Chen J.-X., Chen X., Chiapponi C., Cho K.K., Ciullo V., Corvin A.S., Crespo-Facorro B., Cropley V., De Rossi P., Diaz-Caneja C.M., Dickie E.W., Ehrlich S., Fan F.-M., Fatouros-Bergman H., Flyckt L., Ford J.M., Fouche J.-P., Fukunaga M., Gill M., Glahn D.C., Gollub R., Goudzwaard E.D., Guo H., Gur R.E., Gur R.C., Gurholt T.P., Hashimoto R., Hatton S.N., Henskens F.A., Hibar D.P., Hickie I.B., Hong L.E., Horacek J., Howells F.M., Hulshoff Pol H.E., Hyde C.L., Isaev D., Mathalon D.H., McCarley R.W., McCarthy-Jones S., McDonald C., and McEwen S.

Abstract

The regional distribution of white matter (WM) abnormalities in schizophrenia remains poorly understood, and reported disease effects on the brain vary widely between studies. In an effort to identify commonalities across studies, we perform what we believe is the first ever large-scale coordinated study of WM microstructural differences in schizophrenia. Our analysis consisted of 2359 healthy controls and 1963 schizophrenia patients from 29 independent international studies; we harmonized the processing and statistical analyses of diffusion tensor imaging (DTI) data across sites and meta-analyzed effects across studies. Significant reductions in fractional anisotropy (FA) in schizophrenia patients were widespread, and detected in 20 of 25 regions of interest within a WM skeleton representing all major WM fasciculi. Effect sizes varied by region, peaking at (d=0.42) for the entire WM skeleton, driven more by peripheral areas as opposed to the core WM where regions of interest were defined. The anterior corona radiata (d=0.40) and corpus callosum (d=0.39), specifically its body (d=0.39) and genu (d=0.37), showed greatest effects. Significant decreases, to lesser degrees, were observed in almost all regions analyzed. Larger effect sizes were observed for FA than diffusivity measures; significantly higher mean and radial diffusivity was observed for schizophrenia patients compared with controls. No significant effects of age at onset of schizophrenia or medication dosage were detected. As the largest coordinated analysis of WM differences in a psychiatric disorder to date, the present study provides a robust profile of widespread WM abnormalities in schizophrenia patients worldwide. Interactive three-dimensional visualization of the results is available at www.enigma-viewer.org.Copyright © The Author(s) 2018.

Published

2018

18. Higher Polygenetic Predisposition for Asthma in Cow's Milk Allergic Children

Author

Jansen, P.R. (Philip), Petrus, N.C.M. (Nicole C M), Venema, A. (Andrea), Posthuma, D. (Danielle), Mannens, M.M.A.M. (Marcel), Sprikkelman, A.B. (Aline), Henneman, P. (Peter), Jansen, P.R. (Philip), Petrus, N.C.M. (Nicole C M), Venema, A. (Andrea), Posthuma, D. (Danielle), Mannens, M.M.A.M. (Marcel), Sprikkelman, A.B. (Aline), and Henneman, P. (Peter)

Abstract

Cow's milk allergy (CMA) is an early-onset allergy of which the underlying genetic factors remain largely undiscovered. CMA has been found to co-occur with other allergies and immunological hypersensitivity disorders, suggesting a shared genetic etiology. We aimed to (1) investigate and (2) validate whether CMA children carry a higher genetic susceptibility for other immunological hypersensitivity disorders using polygenic risk score analysis (PRS) and prospective phenotypic data. Twenty-two CMA patients of the Dutch EuroPrevall birth cohort study and 307 reference subjects were genotyped using single nucleotide polymorphism (SNP) array. Differentially genetic susceptibility was estimated using PRS, based on multiple P-value thresholds for SNP inclusion of previously reported genome-wide association studies (GWAS) on asthma, autism spectrum disorder, atopic dermatitis, inflammatory bowel disease and rheumatoid arthritis. These associations were validated with prospective data outcomes during a six-year follow-up in 19 patients. We observed robust and significantly higher PRSs of asthma in CMA children compared to the reference set. Association analyses using the prospective data indicated significant higher PRSs in former CMA patients suffering from asthma and related traits. Our results suggest a shared genetic etiology between CMA and asthma and a considerable predictive sensitivity potential for subsequent onset of asthma which indicates a potential use for early clinical asthma intervention programs.

Published

2018

19. Widespread white matter microstructural differences in schizophrenia across 4322 individuals: Results from the ENIGMA Schizophrenia DTI Working Group

Author

Kelly, S. (S.), Jahanshad, N. (Neda), Zalesky, A. (A.), Kochunov, P. (P.), Agartz, I. (Ingrid), Alloza, C. (C.), Andreassen, O.A. (O. A.), Arango, C. (C.), Banaj, N. (N.), Bouix, S. (S.), Bousman, C.A. (C. A.), Brouwer, R.M. (Rachel), Bruggemann, J. (J.), Bustillo, J., Cahn, W. (Wiepke), Calhoun, V.D. (Vince), Cannon, D. (D.), Carr, V.J. (Vaughan), Catts, S.V. (Stanley), Chen, J. (J.), Chen, J.-X. (J. X.), Chen, X. (X.), Chiapponi, C. (C.), Cho, K.K. (Kl K), Ciullo, V. (V.), Corvin, A. (Aiden), Crespo-Facorro, B. (Benedicto), Cropley, V. (V.), De Rossi, P. (P.), Diaz-Caneja, C.M. (C. M.), Dickie, E.W. (E. W.), Ehrlich, S.M. (Stefan), Fan, F.-M. (F. M.), Faskowitz, J. (J.), Fatouros-Bergman, H. (H.), Flyckt, L. (L.), Ford, J.M. (J. M.), Fouche, J.-P. (J. P.), Fukunaga, M. (Masaki), Gill, M. (M.), Glahn, D.C. (David), Gollub, R.L. (Randy), Goudzwaard, E.D. (E. D.), Guo, H. (H.), Gur, R.E. (Raquel), Gur, R.C. (R. C.), Gurholt, T.P. (T. P.), Hashimoto, R. (Ryota), Hatton, W., Henskens, F.A. (Frans), Hibar, D.P. (D. P.), Hickie, I.B. (Ian), Hong, L.E. (L. E.), Horacek, J. (J.), Howells, F.M. (F. M.), Hulshoff Pol, H.E. (Hilleke), Hyde, C.L. (C. L.), Isaev, D. (D.), Jablensky, A. (A.), Jansen, P.R. (P. R.), Janssen, J. (J.), Jönsson, E.G. (Erik), Jung, L.A. (L. A.), Kahn, R.S. (R. S.), Kikinis, Z. (Z.), Liu, K. (K.), Klauser, P. (P.), Knöchel, C. (C.), Kubicki, M. (M.), Lagopoulos, J. (Jim), Langen, C.D. (Carolyn), Lawrie, S. (Stephen), Lenroot, R.K. (Rhoshel), Lim, K.O. (Kelvin), Lopez-Jaramillo, C. (C.), Lyall, A. (A.), Magnotta, V., Mandl, R. (René), Mathalon, D.H. (D. H.), McCarley, R.W. (Robert), McCarthy-Jones, S. (S.), McDonald, C. (Colm), McEwen, S. (S.), McIntosh, A.M. (Andrew), Melicher, T. (T.), Mesholam-Gately, R.I. (Raquelle), Michie, P.T. (Patricia), Mowry, B.J. (Bryan J), Mueller, B.A. (Bryon ), Newell, D.T. (D. T.), O'Donnell, P. (P.), Oertel-Knöchel, V. (V.), Oestreich, L. (L.), Paciga, S.A. (S. A.), Pantelis, C. (Christos), Pasternak, O. (O.), Pearlson, G. (G.), Pellicano, G.R. (G. R.), Pereira, A. (A.), Pineda Zapata, J. (J.), Piras, F. (F.), Potkin, S.G. (Steven), Preda, A. (A.), Rasser, P.E. (P. E.), Roalf, D.R. (D. R.), Roiz, R. (R.), Roos, A. (A.), Rotenberg, D. (D.), Satterthwaite, T.D. (Theodore), Savadjiev, P. (P.), Schall, J.D. (Jeffrey), Scott, R.J. (R. J.), Seal, M.L. (M. L.), Seidman, L.J. (Larry), Shannon Weickert, C. (C.), Whelan, C.D. (Christopher), Shenton, M.E. (M. E.), Kwon, J.S. (J. S.), Spalletta, G. (Gianfranco), Spaniel, F. (F.), Sprooten, R. (Roy), Stäblein, M. (M.), Stein, D.J. (Dan), Sundram, S. (S.), Tan, Y. (Y.), Tan, S. (S.), Tang, S. (S.), Temmingh, H.S. (H. S.), Westlye, L.T. (Lars), Tønnesen, S. (S.), Tordesillas-Gutierrez, D. (Diana), Doan, N.T. (N. T.), Vaidya, J. (J.), Van Haren, N.E.M. (N. E.M.), Vargas, C.D. (C. D.), Vecchio, D. (D.), Velakoulis, D. (D.), Voineskos, A. (A.), Voyvodic, J.Q. (J. Q.), Wang, Z. (Z.), Wan, P. (P.), Wei, D. (D.), Weickert, T.W. (T. W.), Whalley, H. (H.), White, T.J.H. (Tonya), Whitford, T.J. (T. J.), Wojcik, J.D. (J. D.), Xiang, H. (H.), Xie, Z. (Z.), Yamamori, H. (H.), Yang, F. (F.), Yao, N. (N.), Zhang, G. (G.), Zhao, J. (J.), Erp, T.G.M. (Theo G.) van, Turner, J. (Jessica), Thompson, P.M. (P. M.), Donohoe, D.J. (Dennis), Kelly, S. (S.), Jahanshad, N. (Neda), Zalesky, A. (A.), Kochunov, P. (P.), Agartz, I. (Ingrid), Alloza, C. (C.), Andreassen, O.A. (O. A.), Arango, C. (C.), Banaj, N. (N.), Bouix, S. (S.), Bousman, C.A. (C. A.), Brouwer, R.M. (Rachel), Bruggemann, J. (J.), Bustillo, J., Cahn, W. (Wiepke), Calhoun, V.D. (Vince), Cannon, D. (D.), Carr, V.J. (Vaughan), Catts, S.V. (Stanley), Chen, J. (J.), Chen, J.-X. (J. X.), Chen, X. (X.), Chiapponi, C. (C.), Cho, K.K. (Kl K), Ciullo, V. (V.), Corvin, A. (Aiden), Crespo-Facorro, B. (Benedicto), Cropley, V. (V.), De Rossi, P. (P.), Diaz-Caneja, C.M. (C. M.), Dickie, E.W. (E. W.), Ehrlich, S.M. (Stefan), Fan, F.-M. (F. M.), Faskowitz, J. (J.), Fatouros-Bergman, H. (H.), Flyckt, L. (L.), Ford, J.M. (J. M.), Fouche, J.-P. (J. P.), Fukunaga, M. (Masaki), Gill, M. (M.), Glahn, D.C. (David), Gollub, R.L. (Randy), Goudzwaard, E.D. (E. D.), Guo, H. (H.), Gur, R.E. (Raquel), Gur, R.C. (R. C.), Gurholt, T.P. (T. P.), Hashimoto, R. (Ryota), Hatton, W., Henskens, F.A. (Frans), Hibar, D.P. (D. P.), Hickie, I.B. (Ian), Hong, L.E. (L. E.), Horacek, J. (J.), Howells, F.M. (F. M.), Hulshoff Pol, H.E. (Hilleke), Hyde, C.L. (C. L.), Isaev, D. (D.), Jablensky, A. (A.), Jansen, P.R. (P. R.), Janssen, J. (J.), Jönsson, E.G. (Erik), Jung, L.A. (L. A.), Kahn, R.S. (R. S.), Kikinis, Z. (Z.), Liu, K. (K.), Klauser, P. (P.), Knöchel, C. (C.), Kubicki, M. (M.), Lagopoulos, J. (Jim), Langen, C.D. (Carolyn), Lawrie, S. (Stephen), Lenroot, R.K. (Rhoshel), Lim, K.O. (Kelvin), Lopez-Jaramillo, C. (C.), Lyall, A. (A.), Magnotta, V., Mandl, R. (René), Mathalon, D.H. (D. H.), McCarley, R.W. (Robert), McCarthy-Jones, S. (S.), McDonald, C. (Colm), McEwen, S. (S.), McIntosh, A.M. (Andrew), Melicher, T. (T.), Mesholam-Gately, R.I. (Raquelle), Michie, P.T. (Patricia), Mowry, B.J. (Bryan J), Mueller, B.A. (Bryon ), Newell, D.T. (D. T.), O'Donnell, P. (P.), Oertel-Knöchel, V. (V.), Oestreich, L. (L.), Paciga, S.A. (S. A.), Pantelis, C. (Christos), Pasternak, O. (O.), Pearlson, G. (G.), Pellicano, G.R. (G. R.), Pereira, A. (A.), Pineda Zapata, J. (J.), Piras, F. (F.), Potkin, S.G. (Steven), Preda, A. (A.), Rasser, P.E. (P. E.), Roalf, D.R. (D. R.), Roiz, R. (R.), Roos, A. (A.), Rotenberg, D. (D.), Satterthwaite, T.D. (Theodore), Savadjiev, P. (P.), Schall, J.D. (Jeffrey), Scott, R.J. (R. J.), Seal, M.L. (M. L.), Seidman, L.J. (Larry), Shannon Weickert, C. (C.), Whelan, C.D. (Christopher), Shenton, M.E. (M. E.), Kwon, J.S. (J. S.), Spalletta, G. (Gianfranco), Spaniel, F. (F.), Sprooten, R. (Roy), Stäblein, M. (M.), Stein, D.J. (Dan), Sundram, S. (S.), Tan, Y. (Y.), Tan, S. (S.), Tang, S. (S.), Temmingh, H.S. (H. S.), Westlye, L.T. (Lars), Tønnesen, S. (S.), Tordesillas-Gutierrez, D. (Diana), Doan, N.T. (N. T.), Vaidya, J. (J.), Van Haren, N.E.M. (N. E.M.), Vargas, C.D. (C. D.), Vecchio, D. (D.), Velakoulis, D. (D.), Voineskos, A. (A.), Voyvodic, J.Q. (J. Q.), Wang, Z. (Z.), Wan, P. (P.), Wei, D. (D.), Weickert, T.W. (T. W.), Whalley, H. (H.), White, T.J.H. (Tonya), Whitford, T.J. (T. J.), Wojcik, J.D. (J. D.), Xiang, H. (H.), Xie, Z. (Z.), Yamamori, H. (H.), Yang, F. (F.), Yao, N. (N.), Zhang, G. (G.), Zhao, J. (J.), Erp, T.G.M. (Theo G.) van, Turner, J. (Jessica), Thompson, P.M. (P. M.), and Donohoe, D.J. (Dennis)

Abstract

The regional distribution of white matter (WM) abnormalities in schizophrenia remains poorly understood, and reported disease effects on the brain vary widely between studies. In an effort to identify commonalities across studies, we perform what we believe is the first ever large-scale coordinated study of WM microstructural differences in schizophrenia. Our analysis consisted of 2359 healthy controls and 1963 schizophrenia patients from 29 independent international studies; we harmonized the processing and statistical analyses of diffusion tensor imaging (DTI) data across sites and meta-analyzed effects across studies. Significant reductions in fractional anisotropy (FA) in schizophrenia patients were widespread, and detected in 20 of 25 regions of interest within a WM skeleton representing all major WM fasciculi. Effect sizes varied by region, peaking at (d=0.42) for the entire WM skeleton, driven more by peripheral areas as opposed to the core WM where regions of interest were defined. The anterior corona radiata (d=0.40) and corpus callosum (d=0.39), specifically its body (d=0.39) and genu (d=0.37), showed greatest effects. Significant decreases, to lesser degrees, were observed in almost all regions analyzed. Larger effect sizes were observed for FA than diffusivity measures; significantly higher mean and radial diffusivity was observed for schizophrenia patients compared with controls. No significant effects of age at onset of schizophrenia or medication dosage were detected. As the largest coordinated analysis of WM differences in a psychiatric disorder to date, the present study provides a robust profile of widespread WM abnormalities in schizophrenia patients worldwide. Interactive three-dimensional visualization of the results is available at www.enigma-viewer.org.

Published

2018

20. Genome-wide association meta- Analysis of 78,308 individuals identifies new loci and genes influencing human intelligence

Author

Sniekers, S. (Suzanne), Stringer, S. (Sven), Watanabe, K. (Kyoko), Jansen, P.R. (Philip), Coleman, J.R.I. (Jonathan R I), Krapohl, E. (Eva), Taskesen, E. (Erdogan), Hammerschlag, A.R. (Anke R.), Okbay, A. (Aysu), Zabaneh, D. (Delilah), Amin, N. (Najaf), Breen, G. (Gerome), Cesarini, D. (David), Chabris, C.F. (Christopher F), Iacono, W.G. (William), Ikram, M.A. (Arfan), Johannesson, M. (Magnus), Koellinger, P. (Philipp), Lee, J.J. (James J.), Magnusson, P.K. (Patrik), McGue, M. (Matt), Miller, M. (Mike), Ollier, W.E.R. (William), Payton, A. (Antony), Pendleton, N. (Neil), Plomin, R. (Robert), Rietveld, C.A. (Niels), Tiemeier, H.W. (Henning), Duijn, C.M. (Cornelia) van, Posthuma, D. (Danielle), Sniekers, S. (Suzanne), Stringer, S. (Sven), Watanabe, K. (Kyoko), Jansen, P.R. (Philip), Coleman, J.R.I. (Jonathan R I), Krapohl, E. (Eva), Taskesen, E. (Erdogan), Hammerschlag, A.R. (Anke R.), Okbay, A. (Aysu), Zabaneh, D. (Delilah), Amin, N. (Najaf), Breen, G. (Gerome), Cesarini, D. (David), Chabris, C.F. (Christopher F), Iacono, W.G. (William), Ikram, M.A. (Arfan), Johannesson, M. (Magnus), Koellinger, P. (Philipp), Lee, J.J. (James J.), Magnusson, P.K. (Patrik), McGue, M. (Matt), Miller, M. (Mike), Ollier, W.E.R. (William), Payton, A. (Antony), Pendleton, N. (Neil), Plomin, R. (Robert), Rietveld, C.A. (Niels), Tiemeier, H.W. (Henning), Duijn, C.M. (Cornelia) van, and Posthuma, D. (Danielle)

Abstract

Intelligence is associated with important economic and health-related life outcomes. Despite intelligence having substantial heritability (0.54) and a confirmed polygenic nature, initial genetic studies were mostly underpowered. Here we report a meta- A nalysis for intelligence of 78,308 individuals. We identify 336 associated SNPs (METAL P < 5 × 10-8) in 18 genomic loci, of which 15 are new. Around half of the SNPs are located inside a gene, implicating 22 genes, of which 11 are new findings. Gene-based analyses identified an additional 30 genes (MAGMA P < 2.73 × 10-6), of which all but one had not been implicated previously. We show that the identified genes are predominantly expressed in brain tissue, and pathway analysis indicates the involvement of genes regulating cell development (MAGMA competitive P = 3.5 × 10-6). Despite the well-known difference in twin-based heritability for intelligence in childhood (0.45) and adulthood (0.80), we show substantial genetic correlation (rg = 0.89, LD score regression P = 5.4 × 10-29). These findings provide new insight into the genetic architecture of intelligence.

Published

2017

21. A predictive sourcing model for multi Export Credit Agency financed large industrial projects

Author

Jansen, P.R. (author) and Jansen, P.R. (author)

Abstract

CB&I is experiencing an issue in a new project to be executed in Russia, named NKNK. Despite the rich experience CB&I has with projects, there is a continuous struggle with the sourcing process in projects which it involves financing by multiple export credit agencies. The issue at stake is, CB&I does not know beforehand in which countries it is most likely to source its equipment to achieve to lowest possible sourcing costs. However, budgets available in countries will be set in an inception phase of a project. A preliminary estimation method is needed to determine the amount of budget needed in multiple countries, in order to increase the probability of minimizing total sourcing costs. In order to accomplish this, a new cost estimation methodology is needed. This combines strategic sourcing theory, descriptive statistics on suppliers, cost differentials among countries of manufacturing, macroeconomic theory, the role of export credit agencies in trade finance, conventional cost estimation methods, linear optimization, and Monte Carlo simulations. The importance of strategic sourcing is underpinned in this thesis. Theoretical optimal sourcing strategies are suggested on the basis of the level of perceived competition. The perceived level of competition within different industries is acquired through questionnaires with industry experts. The suggested sourcing strategies are tested on their practical applicability in large industrial projects. It turns out that there are serious limitations in applying multiple sourcing strategies, due to the nature of the highly customized equipment needed in these projects. Predominantly, single sourcing strategies are used, in which a number of suppliers is inquired for a bid. It is shown, through a linear regression analysis, there is a significant positive correlation between the perceived level of competition and the number of suppliers inquired for a bid. Descriptive statistics on suppliers involve per equipment type (more fo, Management of Technology, Policy Analysis, Technology, Policy and Management

Published

2013

22. The usefulness of brain natriuretic peptide in complex congenital heart disease: A systematic review

Author

Eindhoven, J.A. (Jannet), Bosch, A.E. (Annemien) van den, Jansen, P.R. (Philip), Boersma, H. (Eric), Roos-Hesselink, J.W. (Jolien), Eindhoven, J.A. (Jannet), Bosch, A.E. (Annemien) van den, Jansen, P.R. (Philip), Boersma, H. (Eric), and Roos-Hesselink, J.W. (Jolien)

Abstract

Brain natriuretic peptide (BNP) and N-terminal pro-brain natriuretic peptide (NT-proBNP) are well-established markers for heart failure in the general population. However, the value of BNP as a diagnostic and prognostic marker for patients with structural congenital heart disease (CHD) is still unclear. Therefore, the purpose of this study was to evaluate the clinical utility of BNP in patients with CHD. We executed a PubMed literature search and included 49 articles that focused on complex congenital heart defects such as tetralogy of Fallot, systemic right ventricle, and univentricular hearts. Data on BNP measurements and cardiac function parameters were extracted. In all patients after correction for tetralogy of Fallot, BNP levels were elevated and correlated significantly with right ventricular end-diastolic dimensions and severity of pulmonary valve regurgitation. Patients with a systemic right ventricle had elevated BNP levels, and positive correlations between BNP and right ventricular function were seen. In patients with a univentricular heart, elevated BNP levels were observed before completion of the Fontan circulation or when patients were symptomatic; a clear association between BNP and New York Heart Association functional class was demonstrated. In conclusion, this review shows an

Published

2012

23. Association studies of up to 1.2 million individuals yield new insights into the genetic etiology of tobacco and alcohol use

Author

Polderman, T.J.C., Stefansson, K., Zuccolo, L., Wall, T.L., Stan����kov��, A., Zhan, X., Hunter, D.J., Davila-Velderrain, J., Palviainen, T., Brazel, D.M., 23andMe Research Team, Haller, T., Chen, F., Jiang, Y., Johnson, E.O., Rose, R.J., Martin, N.G., Wedow, R., Rice, J.P., Boehnke, M., Jorgenson, E., Posthuma, D., Haessler, J., Kellis, M., Young, K.A., Jansen, P.R., Bjornsdottir, G., Kardia, S.L.R., Metspalu, A., Chen, C., Eaton, C.B., Madden, P.A.F., Gillespie, N.A., McGue, M., Choquet, H., McMahon, G., Jang, S.-K., Faul, J.D., Nielsen, J.B., Fritsche, L.G., Yin, J., Cucca, F., Medland, S.E., Vrieze, S., Thorgeirsson, T.E., Loukola, A., Reginsson, G.W., Tian, C., Orr��, V., HUNT All-In Psychiatry, Iacono, W.G., Gordon, S.D., Kraft, P., Fiorillo, E., Reiner, A.P., Willer, C.J., Boomsma, D.I., Munaf��, M.R., Tyrfingsson, T., Kaprio, J., Laakso, M., Zajac, G.J.M., Willemsen, G., Hickie, I.B., Runarsdottir, V., Li, Y., Hottenga, J.-J., McQueen, M.B., Ehringer, M.A., Zhou, W., Smith, J.A., Taylor, A.E., Tindle, H.A., Kooperberg, C., Boardman, J.D., Lee, J.J., McGuire, D., Zhao, W., Mulas, A., Cornelis, M.C., Lind, P.A., Hveem, K., Weisner, C., Datta, G., Gudbjartsson, D.F., Lutz, S.M., M��gi, R., Hewitt, J.K., Turman, C., Thai, K.K., Stallings, M.C., Kamatani, Y., Hopfer, C.J., David, S.P., Young, H., Rimm, E., Bierut, L.J., Ling, Y., Foerster, J.R., Harris, K.M., Davies, G.E., Krauter, K.S., Matoba, N., Abecasis, G., Esko, T., Keller, M.C., Whitfield, J.B., Liu, D.J., Huang, H., Stitzel, J.A., Liu, M., Peters, U., Saccone, N.L., Docherty, A.R., Pandit, A., Stefansson, H., Hokanson, J.E., Heath, A.C., Okada, Y., Weir, D.R., and Mohlke, K.L.

Subjects

3. Good health

Abstract

Tobacco and alcohol use are leading causes of mortality that influence risk for many complex diseases and disorders. They are heritable and etiologically related behaviors that have been resistant to gene discovery efforts. In sample sizes up to 1.2 million individuals, we discovered 566 genetic variants in 406 loci associated with multiple stages of tobacco use (initiation, cessation, and heaviness) as well as alcohol use, with 150 loci evidencing pleiotropic association. Smoking phenotypes were positively genetically correlated with many health conditions, whereas alcohol use was negatively correlated with these conditions, such that increased genetic risk for alcohol use is associated with lower disease risk. We report evidence for the involvement of many systems in tobacco and alcohol use, including genes involved in nicotinic, dopaminergic, and glutamatergic neurotransmission. The results provide a solid starting point to evaluate the effects of these loci in model organisms and more precise substance use measures.