Your search keyword '"Jean-Louis Martineau"' showing total 40 results

1. Using rare genetic mutations to revisit structural brain asymmetry.

Author

Kopal, Jakub, Kumar, Kuldeep, Shafighi, Kimia, Saltoun, Karin, Modenato, Claudia, Moreau, Clara, Huguet, Guillaume, Jean-Louis, Martineau, Martin, Charles-Olivier, Saci, Zohra, Younis, Nadine, Douard, Elise, Jizi, Khadije, Beauchamp-Chatel, Alexis, Kushan, Leila, Silva, Ana, van den Bree, Marianne, Linden, David, Owen, Michael, Hall, Jeremy, Lippé, Sarah, Draganski, Bogdan, Sønderby, Ida, Andreassen, Ole, Glahn, David, Thompson, Paul, Zatorre, Robert, Jacquemont, Sébastien, Bzdok, Danilo, and Bearden, Carrie

Subjects

Humans, DNA Copy Number Variations, Genome-Wide Association Study, Functional Laterality, Brain Mapping, Brain, Magnetic Resonance Imaging

Abstract

Asymmetry between the left and right hemisphere is a key feature of brain organization. Hemispheric functional specialization underlies some of the most advanced human-defining cognitive operations, such as articulated language, perspective taking, or rapid detection of facial cues. Yet, genetic investigations into brain asymmetry have mostly relied on common variants, which typically exert small effects on brain-related phenotypes. Here, we leverage rare genomic deletions and duplications to study how genetic alterations reverberate in human brain and behavior. We designed a pattern-learning approach to dissect the impact of eight high-effect-size copy number variations (CNVs) on brain asymmetry in a multi-site cohort of 552 CNV carriers and 290 non-carriers. Isolated multivariate brain asymmetry patterns spotlighted regions typically thought to subserve lateralized functions, including language, hearing, as well as visual, face and word recognition. Planum temporale asymmetry emerged as especially susceptible to deletions and duplications of specific gene sets. Targeted analysis of common variants through genome-wide association study (GWAS) consolidated partly diverging genetic influences on the right versus left planum temporale structure. In conclusion, our gene-brain-behavior data fusion highlights the consequences of genetically controlled brain lateralization on uniquely human cognitive capacities.

Published

2024

2. Subcortical Brain Alterations in Carriers of Genomic Copy Number Variants.

Author

Kumar, Kuldeep, Modenato, Claudia, Moreau, Clara, Ching, Christopher, Harvey, Annabelle, Martin-Brevet, Sandra, Huguet, Guillaume, Jean-Louis, Martineau, Douard, Elise, Martin, Charles-Olivier, Younis, Nadine, Tamer, Petra, Maillard, Anne, Rodriguez-Herreros, Borja, Pain, Aurélie, Kushan, Leila, Isaev, Dmitry, Alpert, Kathryn, Ragothaman, Anjani, Turner, Jessica, Wang, Lei, Ho, Tiffany, Schmaal, Lianne, Silva, Ana, van den Bree, Marianne, Linden, David, Owen, Michael, Hall, Jeremy, Lippé, Sarah, Dumas, Guillaume, Draganski, Bogdan, Gutman, Boris, Sønderby, Ida, Andreassen, Ole, Schultz, Laura, Almasy, Laura, Glahn, David, Bearden, Carrie, Thompson, Paul, and Jacquemont, Sébastien

Subjects

Depressive Disorders, Genetics/Genomics, Neurodevelopmental Disorders, Neuroimaging, Schizophrenia Spectrum and Other Psychotic Disorders, Male, Adult, Humans, Child, Adolescent, Young Adult, Middle Aged, Aged, Aged, 80 and over, DNA Copy Number Variations, Schizophrenia, Brain, Attention Deficit Disorder with Hyperactivity, Genomics

Abstract

OBJECTIVE: Copy number variants (CNVs) are well-known genetic pleiotropic risk factors for multiple neurodevelopmental and psychiatric disorders (NPDs), including autism (ASD) and schizophrenia. Little is known about how different CNVs conferring risk for the same condition may affect subcortical brain structures and how these alterations relate to the level of disease risk conferred by CNVs. To fill this gap, the authors investigated gross volume, vertex-level thickness, and surface maps of subcortical structures in 11 CNVs and six NPDs. METHODS: Subcortical structures were characterized using harmonized ENIGMA protocols in 675 CNV carriers (CNVs at 1q21.1, TAR, 13q12.12, 15q11.2, 16p11.2, 16p13.11, and 22q11.2; age range, 6-80 years; 340 males) and 782 control subjects (age range, 6-80 years; 387 males) as well as ENIGMA summary statistics for ASD, schizophrenia, attention deficit hyperactivity disorder, obsessive-compulsive disorder, bipolar disorder, and major depression. RESULTS: All CNVs showed alterations in at least one subcortical measure. Each structure was affected by at least two CNVs, and the hippocampus and amygdala were affected by five. Shape analyses detected subregional alterations that were averaged out in volume analyses. A common latent dimension was identified, characterized by opposing effects on the hippocampus/amygdala and putamen/pallidum, across CNVs and across NPDs. Effect sizes of CNVs on subcortical volume, thickness, and local surface area were correlated with their previously reported effect sizes on cognition and risk for ASD and schizophrenia. CONCLUSIONS: The findings demonstrate that subcortical alterations associated with CNVs show varying levels of similarities with those associated with neuropsychiatric conditions, as well distinct effects, with some CNVs clustering with adult-onset conditions and others with ASD. These findings provide insight into the long-standing questions of why CNVs at different genomic loci increase the risk for the same NPD and why a single CNV increases the risk for a diverse set of NPDs.

Published

2023

3. Rare CNVs and phenome-wide profiling highlight brain structural divergence and phenotypical convergence.

Author

Kopal, Jakub, Kumar, Kuldeep, Saltoun, Karin, Modenato, Claudia, Moreau, Clara, Martin-Brevet, Sandra, Huguet, Guillaume, Jean-Louis, Martineau, Martin, Charles-Olivier, Saci, Zohra, Younis, Nadine, Tamer, Petra, Douard, Elise, Maillard, Anne, Rodriguez-Herreros, Borja, Pain, Aurèlie, Richetin, Sonia, Kushan, Leila, Silva, Ana, van den Bree, Marianne, Linden, David, Owen, Michael, Hall, Jeremy, Lippé, Sarah, Draganski, Bogdan, Sønderby, Ida, Andreassen, Ole, Glahn, David, Thompson, Paul, Jacquemont, Sébastien, Bzdok, Danilo, and Bearden, Carrie

Subjects

Humans, DNA Copy Number Variations, Brain

Abstract

Copy number variations (CNVs) are rare genomic deletions and duplications that can affect brain and behaviour. Previous reports of CNV pleiotropy imply that they converge on shared mechanisms at some level of pathway cascades, from genes to large-scale neural circuits to the phenome. However, existing studies have primarily examined single CNV loci in small clinical cohorts. It remains unknown, for example, how distinct CNVs escalate vulnerability for the same developmental and psychiatric disorders. Here we quantitatively dissect the associations between brain organization and behavioural differentiation across 8 key CNVs. In 534 CNV carriers, we explored CNV-specific brain morphology patterns. CNVs were characteristic of disparate morphological changes involving multiple large-scale networks. We extensively annotated these CNV-associated patterns with ~1,000 lifestyle indicators through the UK Biobank resource. The resulting phenotypic profiles largely overlap and have body-wide implications, including the cardiovascular, endocrine, skeletal and nervous systems. Our population-level investigation established brain structural divergences and phenotypical convergences of CNVs, with direct relevance to major brain disorders.

Published

2023

4. Rare copy number variation in posttraumatic stress disorder

Author

Maihofer, Adam X, Engchuan, Worrawat, Huguet, Guillaume, Klein, Marieke, MacDonald, Jeffrey R, Shanta, Omar, Thiruvahindrapuram, Bhooma, Jean-louis, Martineau, Saci, Zohra, Jacquemont, Sebastien, Scherer, Stephen W, Ketema, Elizabeth, Aiello, Allison E, Amstadter, Ananda B, Avdibegović, Esmina, Babic, Dragan, Baker, Dewleen G, Bisson, Jonathan I, Boks, Marco P, Bolger, Elizabeth A, Bryant, Richard A, Bustamante, Angela C, Caldas-de-Almeida, Jose Miguel, Cardoso, Graça, Deckert, Jurgen, Delahanty, Douglas L, Domschke, Katharina, Dunlop, Boadie W, Dzubur-Kulenovic, Alma, Evans, Alexandra, Feeny, Norah C, Franz, Carol E, Gautam, Aarti, Geuze, Elbert, Goci, Aferdita, Hammamieh, Rasha, Jakovljevic, Miro, Jett, Marti, Jones, Ian, Kaufman, Milissa L, Kessler, Ronald C, King, Anthony P, Kremen, William S, Lawford, Bruce R, Lebois, Lauren AM, Lewis, Catrin, Liberzon, Israel, Linnstaedt, Sarah D, Lugonja, Bozo, Luykx, Jurjen J, Lyons, Michael J, Mavissakalian, Matig R, McLaughlin, Katie A, McLean, Samuel A, Mehta, Divya, Mellor, Rebecca, Morris, Charles Phillip, Muhie, Seid, Orcutt, Holly K, Peverill, Matthew, Ratanatharathorn, Andrew, Risbrough, Victoria B, Rizzo, Albert, Roberts, Andrea L, Rothbaum, Alex O, Rothbaum, Barbara O, Roy-Byrne, Peter, Ruggiero, Kenneth J, Rutten, Bart PF, Schijven, Dick, Seng, Julia S, Sheerin, Christina M, Sorenson, Michael A, Teicher, Martin H, Uddin, Monica, Ursano, Robert J, Vinkers, Christiaan H, Voisey, Joanne, Weber, Heike, Winternitz, Sherry, Xavier, Miguel, Yang, Ruoting, McD Young, Ross, Zoellner, Lori A, Salem, Rany M, Shaffer, Richard A, Wu, Tianying, Ressler, Kerry J, Stein, Murray B, Koenen, Karestan C, Sebat, Jonathan, and Nievergelt, Caroline M

Subjects

Post-Traumatic Stress Disorder (PTSD), Mental Health, Human Genome, Genetics, Neurosciences, Brain Disorders, Mental health, Humans, DNA Copy Number Variations, Stress Disorders, Post-Traumatic, Genome, Brain, Genome-Wide Association Study, Polymorphism, Single Nucleotide, Genetic Predisposition to Disease, Psychiatric Genomics Consortium PTSD Working Group, Psychiatric Genomics Consortium CNV Working Group, Biological Sciences, Medical and Health Sciences, Psychology and Cognitive Sciences, Psychiatry

Abstract

Posttraumatic stress disorder (PTSD) is a heritable (h2 = 24-71%) psychiatric illness. Copy number variation (CNV) is a form of rare genetic variation that has been implicated in the etiology of psychiatric disorders, but no large-scale investigation of CNV in PTSD has been performed. We present an association study of CNV burden and PTSD symptoms in a sample of 114,383 participants (13,036 cases and 101,347 controls) of European ancestry. CNVs were called using two calling algorithms and intersected to a consensus set. Quality control was performed to remove strong outlier samples. CNVs were examined for association with PTSD within each cohort using linear or logistic regression analysis adjusted for population structure and CNV quality metrics, then inverse variance weighted meta-analyzed across cohorts. We examined the genome-wide total span of CNVs, enrichment of CNVs within specified gene-sets, and CNVs overlapping individual genes and implicated neurodevelopmental regions. The total distance covered by deletions crossing over known neurodevelopmental CNV regions was significant (beta = 0.029, SE = 0.005, P = 6.3 × 10-8). The genome-wide neurodevelopmental CNV burden identified explains 0.034% of the variation in PTSD symptoms. The 15q11.2 BP1-BP2 microdeletion region was significantly associated with PTSD (beta = 0.0206, SE = 0.0056, P = 0.0002). No individual significant genes interrupted by CNV were identified. 22 gene pathways related to the function of the nervous system and brain were significant in pathway analysis (FDR q

Published

2022

5. Copy-number variants differ in frequency across genetic ancestry groups

Author

Schultz, Laura M., Knighton, Alexys, Huguet, Guillaume, Saci, Zohra, Jean-Louis, Martineau, Mollon, Josephine, Knowles, Emma E.M., Glahn, David C., Jacquemont, Sébastien, and Almasy, Laura

Published

2024

6. Effects of eight neuropsychiatric copy number variants on human brain structure.

Author

Modenato, Claudia, Kumar, Kuldeep, Moreau, Clara, Martin-Brevet, Sandra, Huguet, Guillaume, Schramm, Catherine, Jean-Louis, Martineau, Martin, Charles-Olivier, Younis, Nadine, Tamer, Petra, Douard, Elise, Thébault-Dagher, Fanny, Côté, Valérie, Charlebois, Audrey-Rose, Deguire, Florence, Maillard, Anne M, Rodriguez-Herreros, Borja, Pain, Aurèlie, Richetin, Sonia, 16p11.2 European Consortium, Simons Searchlight Consortium, Melie-Garcia, Lester, Kushan, Leila, Silva, Ana I, van den Bree, Marianne BM, Linden, David EJ, Owen, Michael J, Hall, Jeremy, Lippé, Sarah, Chakravarty, Mallar, Bzdok, Danilo, Bearden, Carrie E, Draganski, Bogdan, and Jacquemont, Sébastien

Subjects

16p11.2 European Consortium, Simons Searchlight Consortium, Brain, Humans, Magnetic Resonance Imaging, Schizophrenia, DNA Copy Number Variations, Neuroimaging, Clinical Sciences, Public Health and Health Services, Psychology

Abstract

Many copy number variants (CNVs) confer risk for the same range of neurodevelopmental symptoms and psychiatric conditions including autism and schizophrenia. Yet, to date neuroimaging studies have typically been carried out one mutation at a time, showing that CNVs have large effects on brain anatomy. Here, we aimed to characterize and quantify the distinct brain morphometry effects and latent dimensions across 8 neuropsychiatric CNVs. We analyzed T1-weighted MRI data from clinically and non-clinically ascertained CNV carriers (deletion/duplication) at the 1q21.1 (n = 39/28), 16p11.2 (n = 87/78), 22q11.2 (n = 75/30), and 15q11.2 (n = 72/76) loci as well as 1296 non-carriers (controls). Case-control contrasts of all examined genomic loci demonstrated effects on brain anatomy, with deletions and duplications showing mirror effects at the global and regional levels. Although CNVs mainly showed distinct brain patterns, principal component analysis (PCA) loaded subsets of CNVs on two latent brain dimensions, which explained 32 and 29% of the variance of the 8 Cohen's d maps. The cingulate gyrus, insula, supplementary motor cortex, and cerebellum were identified by PCA and multi-view pattern learning as top regions contributing to latent dimension shared across subsets of CNVs. The large proportion of distinct CNV effects on brain morphology may explain the small neuroimaging effect sizes reported in polygenic psychiatric conditions. Nevertheless, latent gene brain morphology dimensions will help subgroup the rapidly expanding landscape of neuropsychiatric variants and dissect the heterogeneity of idiopathic conditions.

Published

2021

7. Impact of Copy Number Variants and Polygenic Risk Scores on Psychopathology in the UK Biobank

Author

Mollon, Josephine, Schultz, Laura M., Huguet, Guillaume, Knowles, Emma E.M., Mathias, Samuel R., Rodrigue, Amanda, Alexander-Bloch, Aaron, Saci, Zohra, Jean-Louis, Martineau, Kumar, Kuldeep, Douard, Elise, Almasy, Laura, Jacquemont, Sebastien, and Glahn, David C.

Published

2023

8. Copy-number variants in the contactin-5 gene are a potential risk factor for autism spectrum disorder

Author

Schmilovich, Zoe, Huguet, Guillaume, He, Qin, Musa-Johnson, Amélie, Douard, Elise, Loum, Mor Absa, Liao, Calwing, Ross, Jay P., Dionne-Laporte, Alexandre, Spiegelman, Dan, Jean-Louis, Martineau, Saci, Zohra, Hayward, Caroline, Banaschewski, Tobias, Bokde, Arun, Desrivieres, Sylvane, Lemaitre, Herve, Schumann, Gunter, Xiong, Lan, Dion, Patrick A., Jacquemont, Sébastien, Chaumette, Boris, and Rouleau, Guy A.

Published

2022

9. Investigating the contributions of circadian pathway and insomnia risk genes to autism and sleep disturbances

Author

Tesfaye, Rackeb, Huguet, Guillaume, Schmilovich, Zoe, Renne, Thomas, Loum, Mor Absa, Douard, Elise, Saci, Zohra, Jean-Louis, Martineau, Martineau, Jean Luc, Whelan, Rob, Desrivieres, Sylvane, Heinz, Andreas, Schumann, Gunter, Hayward, Caroline, Elsabbagh, Mayada, and Jacquemont, Sebastien

Published

2022

10. High-effect gene-coding variants impact cognition, mental well-being, and neighborhood safety substrates in brain morphology

Author

Kopal, Jakub, primary, Huguet, Guillaume, additional, Marotta, Justin, additional, Aggarwal, Shambhavi, additional, Osayande, Nicole, additional, Kumar, Kuldeep, additional, Saci, Zohra, additional, Jean-Louis, Martineau, additional, Chai, Xiaoqian J., additional, Ge, Tian, additional, Yeo, B.T. Thomas, additional, Thompson, Paul M., additional, Bearden, Carrie E., additional, Andreassen, Ole A., additional, Jacquemont, Sebastien, additional, and Bzdok, Danilo, additional

Published

2024

11. 295. Rare Variant Genetic Architecture of the Human Cortical MRI Phenotypes in General Population

Author

Kumar, Kuldeep, primary, Kazem, Sayeh, additional, Liao, Zhijie, additional, Kopal, Jakub, additional, Huguet, Guillaume, additional, Renne, Thomas, additional, Jean-Louis, Martineau, additional, Xie, Zhe, additional, Saci, Zohra, additional, Almasy, Laura, additional, Glahn, David, additional, Paus, Tomas, additional, Dumas, Guillaume, additional, Bearden, Carrie, additional, Thompson, Paul, additional, Bethlehem, Richard, additional, Warrier, Varun, additional, and Jacquemont, Sebastien, additional

Published

2024

12. Copy-number variants and polygenic risk for intelligence confer risk for autism spectrum disorder irrespective of their effects on cognitive ability

Author

Schmilovich, Zoe, primary, Bourque, Vincent-Raphaël, additional, Douard, Elise, additional, Huguet, Guillaume, additional, Poulain, Cécile, additional, Ross, Jay P., additional, Alipour, Paria, additional, Castonguay, Charles-Étienne, additional, Younis, Nadine, additional, Jean-Louis, Martineau, additional, Saci, Zohra, additional, Pausova, Zdenka, additional, Paus, Tomas, additional, Schuman, Gunter, additional, Porteous, David, additional, Davies, Gail, additional, Redmond, Paul, additional, Harris, Sarah E., additional, Deary, Ian J., additional, Whalley, Heather, additional, Hayward, Caroline, additional, Dion, Patrick A., additional, Jacquemont, Sébastien, additional, and Rouleau, Guy A., additional

Published

2024

13. Effects of gene dosage on cognitive ability: A function-based association study across brain and non-brain processes

Author

Huguet, Guillaume, primary, Renne, Thomas, additional, Poulain, Cecile, additional, Dubuc, Alma, additional, Kumar, Kuldeep, additional, Kazem, Sayeh, additional, Engchuan, Worrawat Bank, additional, Shanta, Omar, additional, Douard, Elise, additional, Proulx, Catherine, additional, Jean-Louis, Martineau, additional, Saci, Zohra, additional, Mollon, Josephine, additional, Schultz, Laura M, additional, Knowles, Emma EM, additional, Cox, Simon R, additional, Porteous, David, additional, Davies, Gail, additional, Redmond, Paul, additional, Harris, Sarah E, additional, Schumann, Gunter, additional, Dumas, Guillaume, additional, Labbe, Aurelie, additional, Pausova, Zdenka, additional, Paus, Tomas, additional, Scherer, Stephen W., additional, Sebat, Jonathan, additional, Almasy, Laura, additional, Glahn, David C, additional, and Jacquemont, Sebastien, additional

Published

2024

14. Author Correction: Using rare genetic mutations to revisit structural brain asymmetry

Author

Kopal, Jakub, primary, Kumar, Kuldeep, additional, Shafighi, Kimia, additional, Saltoun, Karin, additional, Modenato, Claudia, additional, Moreau, Clara A., additional, Huguet, Guillaume, additional, Jean-Louis, Martineau, additional, Martin, Charles-Olivier, additional, Saci, Zohra, additional, Younis, Nadine, additional, Douard, Elise, additional, Jizi, Khadije, additional, Beauchamp-Chatel, Alexis, additional, Kushan, Leila, additional, Silva, Ana I., additional, van den Bree, Marianne B. M., additional, Linden, David E. J., additional, Owen, Michael J., additional, Hall, Jeremy, additional, Lippé, Sarah, additional, Draganski, Bogdan, additional, Sønderby, Ida E., additional, Andreassen, Ole A., additional, Glahn, David C., additional, Thompson, Paul M., additional, Bearden, Carrie E., additional, Zatorre, Robert, additional, Jacquemont, Sébastien, additional, and Bzdok, Danilo, additional

Published

2024

15. Copy number variants differ in frequency across genetic ancestry groups

Author

Schultz, Laura M., primary, Knighton, Alexys, additional, Huguet, Guillaume, additional, Saci, Zohra, additional, Jean-Louis, Martineau, additional, Mollon, Josephine, additional, Knowles, Emma E.M., additional, Glahn, David C., additional, Jacquemont, Sébastien, additional, and Almasy, Laura, additional

Published

2024

16. Genome-wide analysis of gene dosage in 24,092 individuals estimates that 10,000 genes modulate cognitive ability

Author

Huguet, Guillaume, Schramm, Catherine, Douard, Elise, Tamer, Petra, Main, Antoine, Monin, Pauline, England, Jade, Jizi, Khadije, Renne, Thomas, Poirier, Myriam, Nowak, Sabrina, Martin, Charles-Olivier, Younis, Nadine, Knoth, Inga Sophia, Jean-Louis, Martineau, Saci, Zohra, Auger, Maude, Tihy, Frédérique, Mathonnet, Géraldine, Maftei, Catalina, Léveillé, France, Porteous, David, Davies, Gail, Redmond, Paul, Harris, Sarah E., Hill, W. David, Lemyre, Emmanuelle, Schumann, Gunter, Bourgeron, Thomas, Pausova, Zdenka, Paus, Tomas, Karama, Sherif, Lippe, Sarah, Deary, Ian J., Almasy, Laura, Labbe, Aurélie, Glahn, David, Greenwood, Celia M. T., and Jacquemont, Sébastien

Published

2021

17. F66. FROM GENE TO COGNITION: MAPPING THE EFFECTS OF GENOMIC DELETIONS AND DUPLICATIONS ON COGNITIVE ABILITY

Author

Kazem, Sayeh, primary, Kumar, Kuldeep, additional, Huguet, Guillaume, additional, Lizotte, Myriam, additional, Renne, Thomas, additional, Kopal, Jakub, additional, Horoi, Stefan, additional, Jean-louis, Martineau, additional, Saci, Zohra, additional, Almasy, Laura, additional, Glahn, David, additional, Wolf, Guy, additional, Dumas, Guillaume, additional, and Jacquemont, Sebastien, additional

Published

2023

18. Brain functional connectivity mirrors genetic pleiotropy in psychiatric conditions

Author

Clara A Moreau, Kuldeep Kumar, Annabelle Harvey, Guillaume Huguet, Sebastian G W Urchs, Laura M Schultz, Hanad Sharmarke, Khadije Jizi, Charles-Olivier Martin, Nadine Younis, Petra Tamer, Jean-Louis Martineau, Pierre Orban, Ana Isabel Silva, Jeremy Hall, Marianne B M van den Bree, Michael J Owen, David E J Linden, Sarah Lippé, Carrie E Bearden, Laura Almasy, David C Glahn, Paul M Thompson, Thomas Bourgeron, Pierre Bellec, Sebastien Jacquemont, 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), Centre de recherche du CHU Sainte-Justine / Research Center of the Sainte-Justine University Hospital [Montreal, Canada], Université de Montréal (UdeM)-CHU Sainte Justine [Montréal], Centre de recherche de l'Institut universitaire de gériatrie de Montreal (CRIUGM), Université de Montréal (UdeM), McGill University = Université McGill [Montréal, Canada], Children’s Hospital of Philadelphia (CHOP ), Centre de Recherche de l'Institut Universitaire de Gériatrie de Montréal (CRIUGM), Centre de Recherche de l’Institut Universitaire en Santé Mentale de Montréal (CRIUSMM), Cardiff University, Maastricht University [Maastricht], University of California [Los Angeles] (UCLA), University of California (UC), Semel Institute for Neuroscience and Human Behavior [Los Angeles, Ca], University of California (UC)-University of California (UC), University of Pennsylvania, Keck School of Medicine [Los Angeles], University of Southern California (USC), This research was supported by Compute Canada (ID 3037 and gsf-624), the Brain Canada Multi-Investigator Research Initiative (MIRI), Canada First Research Excellence Fund, IVADO, Canada First Research Excellence Fund (Healthy Brain Healthy Lives) (S.J.). S.J. is a recipient of a Canada Research Chair in neurodevelopmental disorders, and a chair from the Jeanne et Jean Louis Levesque Foundation. This work was supported by a grant from the ‘Fondation Brain Canada’ Multi-Investigator initiative (S.J.) and a grant from The Canadian Institutes of Health Research (CIHR 400528, S.J.). The Cardiff CNV cohort was supported by the Wellcome Trust Strategic Award ‘DEFINE’ and the National Centre for Mental Health with funds from Health and Care Research Wales (code 100202/Z/12/Z). The CHUV cohort was supported by the Swiss National Science Foundation (Maillard Anne, Project, PMPDP3 171331). Data from the UCLA cohort provided by C.E.B. (participants with 22q11.2 deletions or duplications and controls) was supported through grants from the NIH (U54EB020403), NIMH (R01MH085953, R01MH100900, 1U01MH119736, R21MH116473) and the Simons Foundation (SFARI Explorer Award). Finally, data from another study were obtained through the OpenFMRI project (http://openfmri.org) from the Consortium for Neuropsychiatric Phenomics (CNP), which was supported by National Institutes of Health Roadmap for Medical Research grants UL1-DE019580, RL1MH083268, RL1MH083269, RL1DA024853, RL1MH083270, RL1LM009833, PL1MH083271 and PL1NS062410. P.B. is a fellow (‘Chercheur boursier Junior 2’) of the ‘Fonds de recherche du Québec—Santé’, Data preprocessing and analyses were supported in part by the Courtois foundation (P.B.). This work was supported by Simons Foundation grant nos. SFARI219193 and SFARI274424. We thank all of the families at the participating SVIP (VIP) sites, as well as the Simons VIP Consortium. We appreciate obtaining access to imaging and phenotypic data on SFARI Base. Approved researchers can obtain the Simons VIP population dataset described in this study by applying at https://base.sfari.org. We are grateful to all families who participated in the 16p11.2 European Consortium. P.M.T. was funded in part by the National Institutes of Health grants R01MH116147, P41EB015922, R01MH111671 and U01 AG068057. P.T. received the Canadian Institute of Health Research (CIHR) Scholarship., RS: MHeNs - R2 - Mental Health, Psychiatry 1, RS: MHeNs - R1 - Cognitive Neuropsychiatry and Clinical Neuroscience, School for Mental Health & Neuroscience, and RS: MHeNs - R3 - Neuroscience

Subjects

copy-number variant, pleiotropy, functional connectivity, autism spectrum disorder, [SDV.NEU]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC], Neurology (clinical), psychiatry

Abstract

Pleiotropy occurs when a genetic variant influences more than one trait. This is a key property of the genomic architecture of psychiatric disorders and has been observed for rare and common genomic variants. It is reasonable to hypothesize that the microscale genetic overlap (pleiotropy) across psychiatric conditions and cognitive traits may lead to similar overlaps at the macroscale brain level such as large-scale brain functional networks. We took advantage of brain connectivity, measured by resting-state functional MRI to measure the effects of pleiotropy on large-scale brain networks, a putative step from genes to behaviour. We processed nine resting-state functional MRI datasets including 32 726 individuals and computed connectome-wide profiles of seven neuropsychiatric copy-number-variants, five polygenic scores, neuroticism and fluid intelligence as well as four idiopathic psychiatric conditions. Nine out of 19 pairs of conditions and traits showed significant functional connectivity correlations (rFunctional connectivity), which could be explained by previously published levels of genomic (rGenetic) and transcriptomic (rTranscriptomic) correlations with moderate to high concordance: rGenetic—rFunctional connectivity = 0.71 [0.40–0.87] and rTranscriptomic—rFunctional connectivity = 0.83 [0.52; 0.94]. Extending this analysis to functional connectivity profiles associated with rare and common genetic risk showed that 30 out of 136 pairs of connectivity profiles were correlated above chance. These similarities between genetic risks and psychiatric disorders at the connectivity level were mainly driven by the overconnectivity of the thalamus and the somatomotor networks. Our findings suggest a substantial genetic component for shared connectivity profiles across conditions and traits, opening avenues to delineate general mechanisms—amenable to intervention—across psychiatric conditions and genetic risks.

Published

2023

19. Exploring the common genetic architecture of autism spectrum disorder using a novel multi-polygenic risk score approach

Author

Schmilovich, Zoe, primary, Bourque, Vincent-Raphael, additional, Huguet, Guillaume, additional, He, Qin, additional, Ross, Jay P., additional, Jean-Louis, Martineau, additional, Saci, Zohra, additional, Chaumette, Boris, additional, Dion, Patrick A., additional, Jacquemont, Sebastien, additional, and Rouleau, Guy A., additional

Published

2023

20. Using rare genetic mutations to revisit structural brain asymmetry

Author

Kopal, Jakub, primary, Kumar, Kuldeep, additional, Shafighi, Kimia, additional, Saltoun, Karin, additional, Modenato, Claudia, additional, Moreau, Clara A., additional, Huguet, Guillaume, additional, Jean-Louis, Martineau, additional, Martin, Charles-Olivier, additional, Saci, Zohra, additional, Younis, Nadine, additional, Douard, Elise, additional, Jizi, Khadije, additional, Beauchamp-Chatel, Alexis, additional, Kushan, Leila, additional, Silva, Ana I., additional, van den Bree, Marianne B. M., additional, Linden, David E. J., additional, Owen, Michael J., additional, Hall, Jeremy, additional, Lippé, Sarah, additional, Draganski, Bogdan, additional, Sønderby, Ida E., additional, Andreassen, Ole A., additional, Glahn, David C., additional, Thompson, Paul M., additional, Bearden, Carrie E., additional, Zatorre, Robert, additional, Jacquemont, Sébastien, additional, and Bzdok, Danilo, additional

Published

2023

21. Genetic Heterogeneity Shapes Brain Connectivity in Psychiatry

Author

Clara A. Moreau, Annabelle Harvey, Kuldeep Kumar, Guillaume Huguet, Sebastian G.W. Urchs, Elise A. Douard, Laura M. Schultz, Hanad Sharmarke, Khadije Jizi, Charles-Olivier Martin, Nadine Younis, Petra Tamer, Thomas Rolland, Jean-Louis Martineau, Pierre Orban, Ana Isabel Silva, Jeremy Hall, Marianne B.M. van den Bree, Michael J. Owen, David E.J. Linden, Aurelie Labbe, Sarah Lippé, Carrie E. Bearden, Laura Almasy, David C. Glahn, Paul M. Thompson, Thomas Bourgeron, Pierre Bellec, Sebastien Jacquemont, RS: MHeNs - R2 - Mental Health, Psychiatry 1, RS: MHeNs School for Mental Health and Neuroscience, RS: MHeNs - R1 - Cognitive Neuropsychiatry and Clinical Neuroscience, School for Mental Health & Neuroscience, RS: MHeNs - R3 - Neuroscience, 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), Centre de recherche du CHU Sainte-Justine / Research Center of the Sainte-Justine University Hospital [Montreal, Canada], Université de Montréal (UdeM)-CHU Sainte Justine [Montréal], Centre de Recherche de l'Institut Universitaire de Gériatrie de Montréal (CRIUGM), Montreal Neurological Institute and Hospital, McGill University = Université McGill [Montréal, Canada], Children’s Hospital of Philadelphia (CHOP ), Centre de Recherche de l’Institut Universitaire en Santé Mentale de Montréal (CRIUSMM), Université de Montréal (UdeM), Cardiff University, Maastricht University [Maastricht], HEC Montréal (HEC Montréal), Semel Institute for Neuroscience and Human Behavior [Los Angeles, Ca], University of California [Los Angeles] (UCLA), University of California (UC)-University of California (UC), University of Pennsylvania, Harvard Medical School [Boston] (HMS), Boston Children's Hospital, Centre de recherche de l'Institut universitaire de gériatrie de Montreal (CRIUGM), and This research was supported by Compute Canada (ID 3037 and gsf-624), the Brain Canada Multi investigator research initiative (MIRI), Canada First Research Excellence Fund, Institute of Data Valorization, Healthy Brain Healthy Lives (Dr. Jacquemont). Dr. Jacquemont is a recipient of a Canada Research Chair in neurodevelopmental disorders, and a chair from the Jeanne et Jean Louis Levesque Foundation. This work was supported by a grant from the Brain Canada Multi-Investigator initiative (Dr. Jacquemont) and a grant from The Canadian Institutes of Health Research (CIHR 400528, Dr. Jacquemont). Clara Moreau and Thomas Bourgeron are supported by AIMS-2-TRIALS - which received support from the Innovative Medicines Initiative 2 Joint Undertaking under grant agreement No 777394. The Cardiff CNV cohort was supported by the Wellcome Trust Strategic Award 'DEFINE' and the National Centre for Mental Health with funds from Health and Care Research Wales (code 100202/Z/12/Z). Data from the UCLA cohort provided by Dr. Bearden (participants with 22q11.2 deletions or duplications and controls) was supported through grants from the NIH (U54EB020403), NIMH (R01MH085953, R01MH100900, 1U01MH119736, R21MH116473 ), and the Simons Foundation (SFARI Explorer Award). Finally, data from another study were obtained through the OpenFMRI project (http://openfmri.org) from the Consortium for Neuropsychiatric Phenomics (CNP), which was supported by NIH Roadmap for Medical Research grants UL1-DE019580, RL1MH083268, RL1MH083269, RL1DA024853, RL1MH083270, RL1LM009833, PL1MH083271, and PL1NS062410. Dr P. Bellec is a fellow ('Chercheur boursier Junior 2') of the 'Fonds de recherche du Québec - Santé', Data preprocessing and analyses were supported in part by the Courtois foundation (Dr Bellec). This work was supported by Simons Foundation Grant Nos. SFARI219193 and SFARI274424. We thank all of the families at the participating Simons Variation in Individuals Project (VIP) sites, as well as the Simons VIP Consortium. We appreciate obtaining access to imaging and phenotypic data on SFARI Base. Approved researchers can obtain the Simons VIP population dataset described in this study by applying at https://base.sfari.org. We are grateful to all families who participated in the 16p11.2 European Consortium. Dr. P. Thompson was funded in part by the U.S. NIH grants R01MH116147, P41EB015922, R01MH111671, and U01 AG068057. Ms. Petra Tamer received the Canadian Institute of Health Research (CIHR) Scholarship.

Subjects

Psychiatry, Multifactorial Inheritance, DNA Copy Number Variations, Brain, Copy number variant, Functional connectivity, Genetic Heterogeneity, [SDV.GEN.GH]Life Sciences [q-bio]/Genetics/Human genetics, Humans, Genetic Predisposition to Disease, Polygenic score transdiagnostic approach, Autism spectrum disorder, Biological Psychiatry, Genome-Wide Association Study

Abstract

BACKGROUND: Polygenicity and genetic heterogeneity pose great challenges for studying psychiatric conditions. Genetically informed approaches have been implemented in neuroimaging studies to address this issue. However, the effects on functional connectivity of rare and common genetic risks for psychiatric disorders are largely unknown. Our objectives were to estimate and compare the effect sizes on brain connectivity of psychiatric genomic risk factors with various levels of complexity: oligogenic copy number variants (CNVs), multigenic CNVs, and polygenic risk scores (PRSs) as well as idiopathic psychiatric conditions and traits.METHODS: Resting-state functional magnetic resonance imaging data were processed using the same pipeline across 9 datasets. Twenty-nine connectome-wide association studies were performed to characterize the effects of 15 CNVs (1003 carriers), 7 PRSs, 4 idiopathic psychiatric conditions (1022 individuals with autism, schizophrenia, bipolar conditions, or attention-deficit/hyperactivity disorder), and 2 traits (31,424 unaffected control subjects).RESULTS: Effect sizes on connectivity were largest for psychiatric CNVs (estimates: 0.2-0.65 z score), followed by psychiatric conditions (0.15-0.42), neuroticism and fluid intelligence (0.02-0.03), and PRSs (0.01-0.02). Effect sizes of CNVs on connectivity were correlated to their effects on cognition and risk for disease (r = 0.9, p = 5.93 × 10-6). However, effect sizes of CNVs adjusted for the number of genes significantly decreased from small oligogenic to large multigenic CNVs (r = -0.88, p = 8.78 × 10-6). PRSs had disproportionately low effect sizes on connectivity compared with CNVs conferring similar risk for disease.CONCLUSIONS: Heterogeneity and polygenicity affect our ability to detect brain connectivity alterations underlying psychiatric manifestations.

Published

2023

22. P414. Effect Sizes Map on General Intelligence of Coding Genes Deleted or Duplicated

Author

Huguet, Guillaume, primary, Douard, Elise, additional, Proulx, Catherine, additional, Renne, Thomas, additional, Poulain, Cécile, additional, Mollon, Josephine, additional, Schultz, Laura, additional, Jean Louis, Martineau, additional, Saci, Zohra, additional, Pausova, Zdenka, additional, Paus, Tomas, additional, Almasy, Laura, additional, Glahn, David, additional, and Jacquemont, Sebastien, additional

Published

2022

23. Whole-Exome Sequencing in Congenital Hypothyroidism Due to Thyroid Dysgenesis

Author

Larrivée-Vanier, Stéphanie, primary, Jean-Louis, Martineau, additional, Magne, Fabien, additional, Bui, Helen, additional, Rouleau, Guy A., additional, Spiegelman, Dan, additional, Samuels, Mark E., additional, Kibar, Zoha, additional, Van Vliet, Guy, additional, and Deladoëy, Johnny, additional

Published

2022

24. Atlas of functional connectivity relationships across rare and common genetic variants, traits, and psychiatric conditions

Author

Sarah Lippé, Carrie E. Bearden, Kuldeep Kumar, Elise Douard, Thomas Rolland, Jean-Louis Martineau, David Shin, Marianne Bernadette van den Bree, Hanad Sharmarke, Clara Moreau, Pierre Orban, Annabelle Harvey, Aurélie Labbe, Pierre Bellec, Laura M. Schultz, Guillaume Huguet, David Edmund Johannes Linden, Petra Tamer, Paul M. Thompson, Sebastian Urchs, Sébastien Jacquemont, Laura Almasy, Nadine Younis, David C. Glahn, Ana I. Silva, Anne M. Maillard, Tomasz J. Nowakowski, Thomas Bourgeron, Khadije Jizi, Charles-Olivier Martin, Michael John Owen, Jeremy Hall, Institut Pasteur [Paris] (IP), Centre de recherche du CHU Sainte-Justine / Research Center of the Sainte-Justine University Hospital [Montreal, Canada], Université de Montréal (UdeM)-CHU Sainte Justine [Montréal], 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), Université de Montréal (UdeM), McGill University = Université McGill [Montréal, Canada], Children’s Hospital of Philadelphia (CHOP ), Centre de Recherche de l'Institut Universitaire de Gériatrie de Montréal (CRIUGM), Centre National de la Recherche Scientifique (CNRS), University of California [San Francisco] (UC San Francisco), University of California (UC), Cardiff University, Maastricht University [Maastricht], Centre Hospitalier Universitaire Vaudois [Lausanne] (CHUV), University of California [Los Angeles] (UCLA), University of Pennsylvania, Harvard Medical School [Boston] (HMS), Boston Children's Hospital, Keck School of Medicine [Los Angeles], University of Southern California (USC), This research was supported by Compute Canada (ID 3037 and gsf-624), the Brain Canada Multi investigator research initiative (MIRI), Canada First Research Excellence Fund, Institute of Data Valorization, Healthy Brain Healthy Lives (Dr. Jacquemont). Dr. Jacquemont is a recipient of a Canada Research Chair in neurodevelopmental disorders, and a chair from the Jeanne et Jean Louis Levesque Foundation. This work was supported by a grant from the Brain Canada Multi-Investigator initiative (Dr. Jacquemont) and a grant from The Canadian Institutes of Health Research (CIHR 400528, Dr. Jacquemont). The Cardiff CNV cohort was supported by the Wellcome Trust Strategic Award 'DEFINE' and the National Centre for Mental Health with funds from Health and Care Research Wales (code 100202/Z/12/Z). The CHUV cohort was supported by the SNF (Maillard Anne, Project, PMPDP3 171331). Data from the UCLA cohort provided by Dr. Bearden (participants with 22q11.2 deletions or duplications and controls) was supported through grants from the NIH (U54EB020403), NIMH (R01MH085953, R01MH100900, 1U01MH119736, R21MH116473), and the Simons Foundation (SFARI Explorer Award). Finally, data from another study were obtained through the OpenFMRI project (http://openfmri.org) from the Consortium for Neuropsychiatric Phenomics (CNP), which was supported by NIH Roadmap for Medical Research grants UL1-DE019580, RL1MH083268, RL1MH083269, RL1DA024853, RL1MH083270, RL1LM009833, PL1MH083271, and PL1NS062410. Dr P. Bellec is a fellow ('Chercheur boursier Junior 2') of the 'Fonds de recherche du Québec - Santé', Data preprocessing and analyses were supported in part by the Courtois foundation (Dr Bellec). This work was supported by Simons Foundation Grant Nos. SFARI219193 and SFARI274424., We thank all of the families at the participating Simons Variation in Individuals Project (VIP) sites, as well as the Simons VIP Consortium. We appreciate obtaining access to imaging and phenotypic data on SFARI Base. Approved researchers can obtain the Simons VIP population dataset described in this study by applying at https://base.sfari.org. We are grateful to all families who participated in the 16p11.2 European Consortium. Dr. P. Thompson was funded in part by the U.S. NIH grants R01MH116147, P41EB015922, R01MH111671, and U01 AG068057. Ms. Petra Tamer received the Canadian Institute of Health Research (CIHR) Scholarship., Institut Pasteur [Paris], Centre de recherche du CHU Sainte-Justine [Montreal], Centre National de la Recherche Scientifique (CNRS)-Institut Pasteur [Paris]-Université de Paris (UP), University of California [San Francisco] (UCSF), University of California, and University of Pennsylvania [Philadelphia]

Subjects

0303 health sciences, medicine.medical_specialty, Multivariate analysis, Concordance, Functional connectivity, Brain morphometry, Cognition, Biology, 03 medical and health sciences, 0302 clinical medicine, [SDV.GEN.GH]Life Sciences [q-bio]/Genetics/Human genetics, Pleiotropy, medicine, Copy-number variation, Psychiatry, Gene, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Polygenicity and pleiotropy are key properties of the genomic architecture of psychiatric disorders. An optimistic interpretation of polygenicity is that genomic variants converge on a limited set of mechanisms at some level from genes to behavior. Alternatively, convergence may be minimal or absent.We took advantage of brain connectivity, measured by resting-state functional MRI (rs- fMRI), as well as rare and common genomic variants to understand the effects of polygenicity and pleiotropy on large-scale brain networks, a distal step from genes to behavior. We processed ten rs-fMRI datasets including 32,988 individuals, to examine connectome-wide effects of 16 copy number variants (CNVs), 10 polygenic scores, 6 cognitive and brain morphometry traits, and 4 idiopathic psychiatric conditions.Although effect sizes of CNVs on connectivity were correlated to cognition and number of genes, increasing polygenicity was associated with decreasing effect sizes on connectivity. Accordingly, the effect sizes of polygenic scores on connectivity were 6-fold lower compared to CNVs. Despite this heterogeneity of connectivity profiles, multivariate analysis identified convergence of genetic risks and psychiatric disorders on the thalamus and the somatomotor network. Based on spatial correlations with transcriptomic data, we hypothesize that excitatory thalamic neurons may be primary contributors to brain alteration profiles shared across genetic risks and conditions. Finally, pleiotropy measured by genetic and transcriptomic correlations between 38 pairs of conditions/traits showed significant concordance with connectomic correlations, suggesting a substantial causal genetic component for shared connectivity.Such findings open avenues to delineate general mechanisms - amenable to intervention - across conditions and genetic risks.One sentence summaryEffects of rare and common genomic variants on brain functional connectivity shed light on the impact of polygenicity and pleiotropy in psychiatry.

Published

2021

25. Investigating the contributions of circadian pathway and insomnia risk genes to autism and sleep disturbances

Author

Tesfaye, Rackeb, primary, Huguet, Guillaume, additional, Smiliovich, Zoe, additional, Loum, Mor Absa, additional, Douard, Elise, additional, Jean-Louis, Martineau, additional, Martinot, Jean Luc, additional, Whelan, Rob, additional, Desrivieres, Sylvane, additional, Heinz, Andreas, additional, Schumann, Gunter, additional, Hayward, Caroline, additional, Elsabbagh, Mayada, additional, and Jacquemont, Sebastien, additional

Published

2021

26. Neuropsychiatric copy number variants exert shared effects on human brain structure

Author

Sandra Martin-Brevet, Kuldeep Kumar, Clara Moreau, M. Mallar Chakravarty, Florence Deguire, Elise Douard, Guillaume Huguet, Sarah Lippé, Carrie E. Bearden, Sébastien Jacquemont, Fanny Thébault-Dagher, Claudia Modenato, Sonia Richetin, Charlebois A, Danilo Bzdok, Côté, Bogdan Draganski, Aurélie Pain, Lester Melie-Garcia, van den Bree Mb, Ana I. Silva, Jean-Louis Martineau, Nadine Younis, Petra Tamer, Anne M. Maillard, Charles-Olivier Martin, Jeremy Hall, Michael John Owen, Leila Kushan, David E. J. Linden, Catherine Schramm, and Borja Rodriguez-Herreros

Subjects

Genetics, 0303 health sciences, Mutation, Brain morphometry, Human brain, Biology, medicine.disease, medicine.disease_cause, 03 medical and health sciences, Brain anatomy, 0302 clinical medicine, medicine.anatomical_structure, Neuroimaging, Schizophrenia, mental disorders, medicine, Autism, Copy-number variation, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

BackgroundCopy Number Variants (CNVs) associated with autism and schizophrenia have large effects on brain anatomy. Yet, neuroimaging studies have been conducted one mutation at a time. We hypothesize that neuropsychiatric CNVs may exert general effects on brain morphometry because they confer risk for overlapping psychiatric conditions.MethodsWe analyzed T1-weighted MRIs and characterized shared patterns on brain anatomy across 8 neuropsychiatric CNVs. Clinically ascertained samples included 1q21.1 (n=48), 16p11.2 (n=156), or 22q11.2 (n=96) and 331 non-carriers. Non-clinically ascertained samples from the UK Biobank included 1q21.1 (n=19), 16p11.2 (n=8), 22q11.2 (n=9), 15q11.2 (n=148) and 965 non-carriers. Canonical correlation analysis (CCA) and univariate models were used to interrogate brain morphometry changes across 8 CNVs.ResultsEight CNVs affect regional brain volumes along two main gene-morphometry dimensions identified by CCA. While fronto-temporal regions contributed to dimension 1, dimension 2 was driven by subcortical, parietal and occipital regions. Consistently, voxel-wise whole-brain analyses identified the same regions involved in patterns of alteration present across the 4 deletions and duplications. These neuroanatomical patterns are similar to those observed in cross-psychiatric disorder meta-analyses. Deletions and duplications at all 4 loci show mirror effects at either the global and/or the regional level.ConclusionNeuropsychiatric CNVs share neuroanatomical signatures characterized by a parsimonious set of brain dimensions. The latter may underlie the risk conferred by CNVs for a similar spectrum of neuropsychiatric conditions.

Published

2020

27. Estimating the effect-size of gene dosage on cognitive ability across the coding genome

Author

Huguet, Guillaume, Schramm, Catherine, Douard, Elise, Petra, Tamer, Main, Antoine, Monin, Pauline, England, Jade, Jizi, Khadije, Renne, Thomas, Poirier, Myriam, Nowak, Sabrina, Martin, Charles-Olivier, Younis, Nadine, Knoth, Inga Sophia, Jean-Louis, Martineau, Saci, Zohra, Auger, Maude, Tihy, Frédérique, Mathonnet, Géraldine, Maftei, Catalina, Léveillé, France, Porteous, David, Davies, Gail, Redmond, Paul, Harris, Sarah E., Hill, W. David, Lemyre, Emmanuelle, Schumann, Gunter, Bourgeron, Thomas, Pausova, Zdenka, Paus, Tomas, Karama, Sherif, Lippe, Sarah, Deary, Ian J., Almasy, Laura, Labbe, Aurélie, Glahn, David, Greenwood, Celia M.T., and Jacquemont, Sébastien

Subjects

endocrine system diseases, mental disorders

Abstract

Rare genomic Copy Number Variants (CNVs) are major contributors to neurodevelopmental disorder. The vast majority of pathogenic CNVs reported back to patients are ultra-rare and their quantitative effects on traits such as intelligence are undocumented. Here, we identified all CNVs ≥ 50 kilobase in 24,092 individuals from unselected and autism cohorts. We developed statistical models to estimate the effect-size of CNVs on intelligence based on their coding and non-coding characteristics. Measures of intolerance to haploinsufficiency best explained the effect of any deletion or duplication on general intelligence. There was no heterogeneity across unselected and autism cohorts. Validation was performed using an intraclass concordance and showed that model estimates of general intelligence were 78% accurate with mean effect-sizes previously published for 47 CNVs. Inheritance data on 27,766 CNVs showed that deletions and duplications with the same large effect-size on intelligence occur de novo at the same frequency. Our first outline for the effect sizes of all coding genes on intelligence suggests that around 10,000 genes affect this trait.

Published

2020

28. The general impact of haploinsufficiency on brain connectivity underlies the pleiotropic effect of neuropsychiatric CNVs

Author

Claudia Modenato, Amy Lin, Sarah Lippé, Carrie E. Bearden, Aurélie Labbe, David Edmund Johannes Linden, Marianne Bernadette van den Bree, Jean-Louis Martineau, Nadine Younis, Pierre Bellec, Petra Tamer, Sebastian Urchs, Hanad Sharmarke, Aia E. Jønch, Elise Douard, Khadije Jizi, Sandra Martin-Brevet, Clara Moreau, Jeremy Hall, Anne M. Maillard, Sébastien Jacquemont, Charles-Olivier Martin, Celia M. T. Greenwood, Guillaume Huguet, Pierre Orban, Kumar Kuldeep, Paul M. Thompson, Michael John Owen, and Ana I. Silva

Subjects

Genetics, 0303 health sciences, congenital, hereditary, and neonatal diseases and abnormalities, endocrine system diseases, Cognition, Biology, medicine.disease, 03 medical and health sciences, 0302 clinical medicine, Autism spectrum disorder, Schizophrenia, Basal ganglia, mental disorders, medicine, Autism, Attention deficit hyperactivity disorder, Copy-number variation, Haploinsufficiency, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Large effect-size mutations such as copy number variants (CNVs) have the potential to provide key insights into the underlying biological mechanisms linking deleterious genetic variants to brain architecture and neuropsychiatric disorders. To date, the effect of CNVs on functional brain connectivity remains mostly unstudied, and findings are derived from analyses conducted one mutation at a time. The lack of systematic cross-CNV comparisons hinders our understanding of any potential general mechanisms linking CNVs to effects on brain organization. We performed connectome-wide analyses using resting-state functional MRI data from 436 carriers of neuropsychiatric CNVs at the 1q21.1, 15q11.2, 16p11.2, 22q11.2 loci, and 4 neutral-effect CNVs, 66 carriers of scarcer neuropsychiatric CNVs, 756 individuals with idiopathic autism spectrum disorder (ASD), schizophrenia, attention deficit hyperactivity disorder, and 5,377 controls. Neuropsychiatric CNVs showed global shifts of mean connectivity. The effect size of CNVs on relative connectivity (adjusted for the mean) was correlated with the known level of neuropsychiatric risk conferred by CNVs. We reported architecture similarities between individuals with idiopathic psychiatric conditions and high-risk neuropsychiatric-CNVs, predominantly in the thalamus, the posterior cingulate cortex, and the anterior insula. We identified a linear relationship between connectivity and intolerance to haploinsufficiency measured for all genes encompassed by CNVs across 18 loci. This profile involved the thalamus, the basal ganglia, somatomotor and frontoparietal networks and was correlated with lower general intelligence and higher autism severity scores. An exploratory factor analysis confirmed the contribution of these regions to three latent components shared across CNVs and neuropsychiatric disorders. We posit that deleting genes intolerant to haploinsufficiency reorganize connectivity along general dimensions irrespective of where deletions occur in the genome. This haploinsufficiency brain signature opens new avenues to understand polygenicity in psychiatric conditions and the pleiotropic effect of CNVs on cognition and risk for neuropsychiatric disorders.

Published

2020

29. Effect Sizes of Deletions and Duplications on Autism Risk Across the Genome

Author

Douard, Elise, primary, Zeribi, Abderrahim, additional, Schramm, Catherine, additional, Tamer, Petra, additional, Loum, Mor Absa, additional, Nowak, Sabrina, additional, Saci, Zohra, additional, Lord, Marie-Pier, additional, Rodríguez-Herreros, Borja, additional, Jean-Louis, Martineau, additional, Moreau, Clara, additional, Loth, Eva, additional, Schumann, Gunter, additional, Pausova, Zdenka, additional, Elsabbagh, Mayada, additional, Almasy, Laura, additional, Glahn, David C., additional, Bourgeron, Thomas, additional, Labbe, Aurélie, additional, Paus, Tomas, additional, Mottron, Laurent, additional, Greenwood, Celia M.T., additional, Huguet, Guillaume, additional, and Jacquemont, Sébastien, additional

Published

2021

30. The genetics-BIDS extension: Easing the search for genetic data associated with human brain imaging

Author

Moreau, Clara A, primary, Jean-Louis, Martineau, additional, Blair, Ross, additional, Markiewicz, Christopher J, additional, Turner, Jessica A, additional, Calhoun, Vince D, additional, Nichols, Thomas E, additional, and Pernet, Cyril R, additional

Published

2020

31. Estimating the effects of copy‐number variants on intelligence using hierarchical Bayesian models

Author

Jiang, Lai, primary, Huguet, Guillaume, additional, Schramm, Catherine, additional, Ciampi, Antonio, additional, Main, Antoine, additional, Passo, Claudine, additional, Jean‐Louis, Martineau, additional, Auger, Maude, additional, Schumann, Gunter, additional, Porteous, David, additional, Jacquemont, Sébastien, additional, and Greenwood, Celia M. T., additional

Published

2020

32. Genome wide analysis of gene dosage in 24,092 individuals shows that 10,000 genes modulate cognitive ability

Author

Huguet, Guillaume, primary, Schramm, Catherine, additional, Douard, Elise, additional, Petra, Tamer, additional, Main, Antoine, additional, Monin, Pauline, additional, England, Jade, additional, Jizi, Khadije, additional, Renne, Thomas, additional, Poirier, Myriam, additional, Nowak, Sabrina, additional, Martin, Charles-Olivier, additional, Younis, Nadine, additional, Knoth, Inga Sophia, additional, Jean-Louis, Martineau, additional, Saci, Zohra, additional, Auger, Maude, additional, Tihy, Frédérique, additional, Mathonnet, Géraldine, additional, Maftei, Catalina, additional, Léveillé, France, additional, Porteous, David, additional, Davies, Gail, additional, Redmond, Paul, additional, Harris, Sarah E., additional, Hill, W. David, additional, Lemyre, Emmanuelle, additional, Schumann, Gunter, additional, Bourgeron, Thomas, additional, Pausova, Zdenka, additional, Paus, Tomas, additional, Karama, Sherif, additional, Lippe, Sarah, additional, Deary, Ian J., additional, Almasy, Laura, additional, Labbe, Aurélie, additional, Glahn, David, additional, Greenwood, Celia M.T., additional, and Jacquemont, Sébastien, additional

Published

2020

33. OR22-01 NF-κB Pathway Is Implicated in Thyroid Embryogenesis

Author

Vanier, Stéphanie Larrivée, primary, Magne, Fabien, primary, Jean-Louis, Martineau, primary, Samuels, Mark E, primary, Van Vliet, Guy, primary, and Deladoey, Johnny Yvan, primary

Published

2020

34. Effects-sizes of deletions and duplications on autism risk across the genome

Author

Douard, Elise, primary, Zeribi, Abderrahim, additional, Schramm, Catherine, additional, Tamer, Petra, additional, Loum, Mor Absa, additional, Nowak, Sabrina, additional, Saci, Zohra, additional, Lord, Marie-Pier, additional, Rodríguez-Herreros, Borja, additional, Jean-Louis, Martineau, additional, Moreau, Clara, additional, Loth, Eva, additional, Schumann, Gunter, additional, Pausova, Zdenka, additional, Elsabbagh, Mayada, additional, Almasy, Laura, additional, Glahn, David C., additional, Bourgeron, Thomas, additional, Labbe, Aurélie, additional, Paus, Tomas, additional, Mottron, Laurent, additional, Greenwood, Célia M. T., additional, Huguet, Guillaume, additional, and Jacquemont, Sébastien, additional

Published

2020

35. Séquençage d’exomes d’une cohorte de familles caucasiennes simplex dont les patients sont atteints du syndrome d’interruption de la tige hypophysaire

Author

Jean-Louis, Martineau and Samuels, Mark E.

Subjects

Séquençage, PSIS, Magnetic, CNV, BWA, SNP, CoNIFER, Growth, Resonance, Pituitary stalk, Pipeline, Disorder, Exome, fishingCNV, Freebayes, Tige hypophysaire, SAMtools, GATK, Syndrome, Hormone, xHmm, GH, SNP, Génomique, Rare, Désordre, NGS, Mutation, Genomic, WES, Bowtie2, Endocrine, IRM, MRI

Abstract

Le syndrome d’interruption de la tige hypophysaire (PSIS) est un désordre rare qui affecte la fonction du système endocrinien. Jusqu’à nos jours, l’imagerie par la résonance magnétique (IRM) demeure la méthode la plus entreprise afin d’évaluer in vivo l’anomalie d’organogenèse de la tige hypophysaire chez les patients. L’absence de la tige caractérise une déficience permanente en hormone de croissance (GH) pendant que l’étiologie du syndrome demeure inconnue. PSIS se définit comme l’hypopituitarisme congénital et il se caractérise soit par une ectopique post- hypophysaire, soit par une hypoplasie antéhypophysaire, ou encore par une hypoplasie de la tige hypophysaire. Notre objectif consiste à déterminer les mutations génétiques partagées entre les sujets affectés de l’étude et qui pourraient expliquer les causes du syndrome. Pour y parvenir, nous avons analysé les données de séquençage d’exomes (WES) provenant de sept familles caucasiennes simplex, une famille d’origine arabique et cinq autres dont la généalogie est incomplète. Ces données ont été précédemment analysées, pour le même but, par d’autres membres de l’équipe en utilisant le pipeline bio-informatique standard basé sur l’utilisation du logiciel GATK. Nous avons préférentiellement opté pour une nouvelle analyse en utilisant deux différents pipelines bio-informatiques indépendants, pour ensuite comparer conjointement les résultats obtenus. Notre protocole consiste à assembler : d’abord, deux pipelines alternatifs de détection de mutations génétiques ponctuelles (SNV). Ils sont composés d’un logiciel d’alignement de séquence (Bowtie2) et deux logiciels d’appel de variantes (Freebayes et SAMtools). Ensuite, nous avons assemblé trois pipelines de détection de variations du nombre de copies (CNV) génomiques composés communément d’un logiciel d’alignement de séquence (BWA) et trois logiciels d’appel de CNV (CoNIFER, fishingCNV, xHmm). Nos résultats nous ont permis d’identifier des mutations candidates additionnelles qui n’ont jamais été identifiées. De plus, notre méthodologie nous a permis de caractériser certains résultats faux positifs, par conséquent elle pourra nous aider à améliorer la performance des pipelines de détection de variations génomiques existantes., Pituitary stalk interruption syndrome (PSIS) is a rare disorder that affects the function of the endocrine system of the affected individuals. The absence of the pituitary stalk, assessed by MRI, characterizes patients with permanent growth hormone deficiency while the etiology of the syndrome remains unknown. PSIS is defined by clinical hypopituitarism together with anatomical findings including a hypoplastic anterior pituitary, ectopic posterior pituitary and reduced or hypoplastic pituitary stalk. We aim to find shared variations (SNP, CNV) among affected patients in coding regions which could explain the origin of the syndrome. We analyzed the exome NGS data from 8 affected French Canadian trio families, with one additional consanguineous Arabic trio family and 5 families with incomplete pedigree. These data were previously analyzed, for the same objective, by other members of the team using a standardize GATK based bioinformatics pipeline. It was desired to reanalyze the complete data set with two other independent pipelines, followed by a comparison of the SNP discovery results. In the present aspect of the study, we built two SNP discovery pipelines, both composed of a different NGS data aligners (Bowtie2) and each composed a different variant caller (Freebayes, SAMtools), then a CNV discovery pipeline which is composed of three different CNV callers (CoNIFER, fishingCNV, xHmm). In addition to the candidate mutations identified in the previous analysis, we identified additional candidate mutations which had not been detected and never been reported. Furthermore, our method helps to discover the sources of variation false discovery which could help to improve existing genomic mutation discovery pipelines.

Published

2019

36. Integrating genomic variants and developmental milestones to predict cognitive and adaptive outcomes in autistic children.

Author

Bourque VR, Schmilovich Z, Huguet G, England J, Okewole A, Poulain C, Renne T, Jean-Louis M, Saci Z, Zhang X, Rolland T, Labbé A, Vorstman J, Rouleau GA, Baron-Cohen S, Mottron L, Bethlehem RAI, Warrier V, and Jacquemont S

Abstract

Although the first signs of autism are often observed as early as 18-36 months of age, there is a broad uncertainty regarding future development, and clinicians lack predictive tools to identify those who will later be diagnosed with co-occurring intellectual disability (ID). Here, we developed predictive models of ID in autistic children (n=5,633 from three cohorts), integrating different classes of genetic variants alongside developmental milestones. The integrated model yielded an AUC ROC=0.65, with this predictive performance cross-validated and generalised across cohorts. Positive predictive values reached up to 55%, accurately identifying 10% of ID cases. The ability to stratify the probabilities of ID using genetic variants was up to twofold greater in individuals with delayed milestones compared to those with typical development. These findings underscore the potential of models in neurodevelopmental medicine that integrate genomics and clinical observations to predict outcomes and target interventions.

Published

2024

37. High-effect gene-coding variants impact cognition, mental well-being, and neighborhood safety substrates in brain morphology.

Author

Kopal J, Huguet G, Marotta J, Aggarwal S, Osayande N, Kumar K, Saci Z, Jean-Louis M, Chai XJ, Ge T, Yeo BTT, Thompson PM, Bearden CE, Andreassen OA, Jacquemont S, and Bzdok D

Abstract

Our genetic makeup, together with environmental and social influences, shape our brain's development. Yet, the imaging genetics field has struggled to integrate all these modalities to investigate the interplay between genetic blueprint, environment, human health, daily living skills and outcomes. Hence, we interrogated the Adolescent Brain Cognitive Development (ABCD) cohort to outline the effects of rare high-effect genetic variants on brain architecture and corresponding implications on cognitive, behavioral, psychosocial, and socioeconomic traits. Specifically, we designed a holistic pattern-learning algorithm that quantitatively dissects the impacts of copy number variations (CNVs) on brain structure and 962 behavioral variables spanning 20 categories in 7,657 adolescents. Our results reveal associations between genetic alterations, higher-order brain networks, and specific parameters of the family well-being (increased parental and child stress, anxiety and depression) or neighborhood dynamics (decreased safety); effects extending beyond the impairment of cognitive ability or language capacity, dominantly reported in the CNV literature. Our investigation thus spotlights a far-reaching interplay between genetic variation and subjective life quality in adolescents and their families.

Published

2024

38. Copy-number variants and polygenic risk for intelligence confer risk for autism spectrum disorder irrespective of their effects on cognitive ability.

Author

Schmilovich Z, Bourque VR, Douard E, Huguet G, Poulain C, Ross JP, Alipour P, Castonguay CÉ, Younis N, Jean-Louis M, Saci Z, Pausova Z, Paus T, Schuman G, Porteous D, Davies G, Redmond P, Harris SE, Deary IJ, Whalley H, Hayward C, Dion PA, Jacquemont S, and Rouleau GA

Abstract

Rare copy number variants (CNVs) and polygenic risk for intelligence (PRS-IQ) both confer risk for autism spectrum disorder (ASD) but have opposing effects on cognitive ability. The field has struggled to disentangle the effects of these two classes of genomic variants on cognitive ability from their effects on ASD risk, in part because previous studies did not include controls with cognitive measures. We aim to investigate the impact of these genomic variants on ASD risk while adjusting for their known effects on cognitive ability. In a cohort of 8,426 subjects with ASD and 169,804 controls with cognitive assessments, we found that rare coding CNVs and PRS-IQ increased ASD risk, even after adjusting for their effects on cognitive ability. Bottom decile PRS-IQ and CNVs both decreased cognitive ability but had opposing effects on ASD risk. Models combining both classes of variants showed that the effects of rare CNVs and PRS-IQ on ASD risk and cognitive ability were largely additive, further suggesting that risk for ASD is conferred independently from its effects on cognitive ability. Despite imparting mostly additive effects on ASD risk, rare CNVs and PRS-IQ showed opposing effects on core and associated features and developmental history among subjects with ASD. Our findings suggest that cognitive ability itself may not be the factor driving the underlying risk for ASD conferred by these two classes of genomic variants. In other words, ASD risk and cognitive ability may be two distinct manifestations of CNVs and PRS-IQ. This study also highlights the challenge of understanding how genetic risk for ASD maps onto its dimensional traits., Competing Interests: CONFLICT OF INTEREST The authors have no conflicts of interest to declare.

Published

2023

39. Using rare genetic mutations to revisit structural brain asymmetry.

Author

Kopal J, Kumar K, Shafighi K, Saltoun K, Modenato C, Moreau CA, Huguet G, Jean-Louis M, Martin CO, Saci Z, Younis N, Douard E, Jizi K, Beauchamp-Chatel A, Kushan L, Silva AI, van den Bree MBM, Linden DEJ, Owen MJ, Hall J, Lippé S, Draganski B, Sønderby IE, Andreassen OA, Glahn DC, Thompson PM, Bearden CE, Zatorre R, Jacquemont S, and Bzdok D

Abstract

Asymmetry between the left and right brain is a key feature of brain organization. Hemispheric functional specialization underlies some of the most advanced human-defining cognitive operations, such as articulated language, perspective taking, or rapid detection of facial cues. Yet, genetic investigations into brain asymmetry have mostly relied on common variant studies, which typically exert small effects on brain phenotypes. Here, we leverage rare genomic deletions and duplications to study how genetic alterations reverberate in human brain and behavior. We quantitatively dissected the impact of eight high-effect-size copy number variations (CNVs) on brain asymmetry in a multi-site cohort of 552 CNV carriers and 290 non-carriers. Isolated multivariate brain asymmetry patterns spotlighted regions typically thought to subserve lateralized functions, including language, hearing, as well as visual, face and word recognition. Planum temporale asymmetry emerged as especially susceptible to deletions and duplications of specific gene sets. Targeted analysis of common variants through genome-wide association study (GWAS) consolidated partly diverging genetic influences on the right versus left planum temporale structure. In conclusion, our gene-brain-behavior mapping highlights the consequences of genetically controlled brain lateralization on human-defining cognitive traits.

Published

2023

40. Subcortical brain alterations in carriers of genomic copy number variants.

Author

Kumar K, Modenato C, Moreau C, Ching CRK, Harvey A, Martin-Brevet S, Huguet G, Jean-Louis M, Douard E, Martin CO, Younis N, Tamer P, Maillard AM, Rodriguez-Herreros B, Pain A, Richetin S, Kushan L, Isaev D, Alpert K, Ragothaman A, Turner JA, Wang L, Ho TC, Schmaal L, Silva AI, van den Bree MBM, Linden DEJ, Owen MJ, Hall J, Lippé S, Dumas G, Draganski B, Gutman BA, Sønderby IE, Andreassen OA, Schultz L, Almasy L, Glahn DC, Bearden CE, Thompson PM, and Jacquemont S

Abstract

Objectives: Copy number variants (CNVs) are well-known genetic pleiotropic risk factors for multiple neurodevelopmental and psychiatric disorders (NPDs) including autism (ASD) and schizophrenia (SZ). Overall, little is known about how different CNVs conferring risk for the same condition may affect subcortical brain structures and how these alterations relate to the level of disease risk conferred by CNVs. To fill this gap, we investigated gross volume, and vertex level thickness and surface maps of subcortical structures in 11 different CNVs and 6 different NPDs., Methods: Subcortical structures were characterized using harmonized ENIGMA protocols in 675 CNV carriers (at the following loci: 1q21.1, TAR, 13q12.12, 15q11.2, 16p11.2, 16p13.11, and 22q11.2) and 782 controls (Male/Female: 727/730; age-range: 6-80 years) as well as ENIGMA summary-statistics for ASD, SZ, ADHD, Obsessive-Compulsive-Disorder, Bipolar-Disorder, and Major-Depression., Results: Nine of the 11 CNVs affected volume of at least one subcortical structure. The hippocampus and amygdala were affected by five CNVs. Effect sizes of CNVs on subcortical volume, thickness and local surface area were correlated with their previously reported effect sizes on cognition and risk for ASD and SZ. Shape analyses were able to identify subregional alterations that were averaged out in volume analyses. We identified a common latent dimension - characterized by opposing effects on basal ganglia and limbic structures - across CNVs and across NPDs., Conclusion: Our findings demonstrate that subcortical alterations associated with CNVs show varying levels of similarities with those associated with neuropsychiatric conditions. We also observed distinct effects with some CNVs clustering with adult conditions while others clustered with ASD. This large cross-CNV and NPDs analysis provide insight into the long-standing questions of why CNVs at different genomic loci increase the risk for the same NPD, as well as why a single CNV increases the risk for a diverse set of NPDs.

Published

2023