Potential genetic modifiers of disease risk and age at onset in patients with frontotemporal lobar degeneration and GRN mutations: a genome-wide association study

Cyril Pottier; Xiaolai Zhou; Ralph B. Perkerson; Matt Baker; Gregory D. Jenkins; Daniel J. Serie; Roberta Ghidoni; Luisa Benussi; Giuliano Binetti; Adolfo López de Munain; Miren Zulaica; Fermin Moreno; Isabelle Le Ber; Florence Pasquier; Didier Hannequin; Raquel Sánchez-Valle; Anna Antonell; Albert Lladó; Tammee M. Parsons; Ni Cole A. Finch; Elizabeth C. Finger; Carol F. Lippa; Edward D. Huey; Manuela Neumann; Peter Heutink; Matthis Synofzik; Carlo Wilke; Robert A. Rissman; Jaroslaw Slawek; Emilia Sitek; Peter Johannsen; Jørgen E. Nielsen; Yingxue Ren; Marka van Blitterswijk; Mariely DeJesus-Hernandez; Elizabeth Christopher; Melissa E. Murray; Kevin F. Bieniek; Bret M. Evers; Camilla Ferrari; Sara Rollinson; Anna Richardson; Elio Scarpini; Giorgio G. Fumagalli; Alessandro Padovani; John Hardy; Parastoo Momeni; Raffaele Ferrari; Francesca Frangipane; Raffaele Maletta; Maria Anfossi; Maura Gallo; Leonard Petrucelli; Eun Ran Suh; Oscar L. Lopez; Tsz H. Wong; Jeroen G.J. van Rooij; Harro Seelaar; Simon Mead; Richard J. Caselli; Eric M. Reiman; Marwan Noel Sabbagh; Mads Kjolby; Anders Nykjaer; Anna M. Karydas; Adam L. Boxer; Lea T. Grinberg; Jordan Grafman; Salvatore Spina; Adrian Oblak; M. Marsel Mesulam; Sandra Weintraub; Changiz Geula; John R. Hodges; Olivier Piguet; William S. Brooks; David J. Irwin; John Q. Trojanowski; Edward B. Lee; Keith A. Josephs; Joseph E. Parisi; Nilüfer Ertekin-Taner; David S. Knopman; Benedetta Nacmias; Irene Piaceri; Silvia Bagnoli; Sandro Sorbi; Marla Gearing; Jonathan Glass; Thomas G. Beach; Sandra E. Black; Mario Masellis; Ekaterina Rogaeva; Jean Paul Vonsattel; Lawrence S. Honig; Julia Kofler; Amalia C. Bruni; Julie Snowden; David Mann; Stuart Pickering-Brown; Janine Diehl-Schmid; Juliane Winkelmann; Daniela Galimberti; Caroline Graff; Linn Öijerstedt; Claire Troakes; Safa Al-Sarraj; Carlos Cruchaga; Nigel J. Cairns; Jonathan D. Rohrer; Glenda M. Halliday; John B. Kwok; John C. van Swieten; Charles L. White; Bernardino Ghetti; Jill R. Murell; Ian R.A. Mackenzie; Ging Yuek R. Hsiung; Barbara Borroni; Giacomina Rossi; Fabrizio Tagliavini; Zbigniew K. Wszolek; Ronald C. Petersen; Eileen H. Bigio; Murray Grossman; Vivianna M. Van Deerlin; William W. Seeley; Bruce L. Miller; Neill R. Graff-Radford; Bradley F. Boeve; Dennis W. Dickson; Joanna M. Biernacka; Rosa Rademakers

doi:10.1016/S1474-4422(18)30126-1

Potential genetic modifiers of disease risk and age at onset in patients with frontotemporal lobar degeneration and GRN mutations: a genome-wide association study

Cyril Pottier, Xiaolai Zhou, Ralph B. Perkerson, Matt Baker, Gregory D. Jenkins, Daniel J. Serie, Roberta Ghidoni, Luisa Benussi, Giuliano Binetti, Adolfo López de Munain, Miren Zulaica, Fermin Moreno, Isabelle Le Ber, Florence Pasquier, Didier Hannequin, Raquel Sánchez-Valle, Anna Antonell, Albert Lladó, Tammee M. Parsons, Ni Cole A. FinchElizabeth C. Finger, Carol F. Lippa, Edward D. Huey, Manuela Neumann, Peter Heutink, Matthis Synofzik, Carlo Wilke, Robert A. Rissman, Jaroslaw Slawek, Emilia Sitek, Peter Johannsen, Jørgen E. Nielsen, Yingxue Ren, Marka van Blitterswijk, Mariely DeJesus-Hernandez, Elizabeth Christopher, Melissa E. Murray, Kevin F. Bieniek, Bret M. Evers, Camilla Ferrari, Sara Rollinson, Anna Richardson, Elio Scarpini, Giorgio G. Fumagalli, Alessandro Padovani, John Hardy, Parastoo Momeni, Raffaele Ferrari, Francesca Frangipane, Raffaele Maletta, Maria Anfossi, Maura Gallo, Leonard Petrucelli, Eun Ran Suh, Oscar L. Lopez, Tsz H. Wong, Jeroen G.J. van Rooij, Harro Seelaar, Simon Mead, Richard J. Caselli, Eric M. Reiman, Marwan Noel Sabbagh, Mads Kjolby, Anders Nykjaer, Anna M. Karydas, Adam L. Boxer, Lea T. Grinberg, Jordan Grafman, Salvatore Spina, Adrian Oblak, M. Marsel Mesulam, Sandra Weintraub, Changiz Geula, John R. Hodges, Olivier Piguet, William S. Brooks, David J. Irwin, John Q. Trojanowski, Edward B. Lee, Keith A. Josephs, Joseph E. Parisi, Nilüfer Ertekin-Taner, David S. Knopman, Benedetta Nacmias, Irene Piaceri, Silvia Bagnoli, Sandro Sorbi, Marla Gearing, Jonathan Glass, Thomas G. Beach, Sandra E. Black, Mario Masellis, Ekaterina Rogaeva, Jean Paul Vonsattel, Lawrence S. Honig, Julia Kofler, Amalia C. Bruni, Julie Snowden, David Mann, Stuart Pickering-Brown, Janine Diehl-Schmid, Juliane Winkelmann, Daniela Galimberti, Caroline Graff, Linn Öijerstedt, Claire Troakes, Safa Al-Sarraj, Carlos Cruchaga, Nigel J. Cairns, Jonathan D. Rohrer, Glenda M. Halliday, John B. Kwok, John C. van Swieten, Charles L. White, Bernardino Ghetti, Jill R. Murell, Ian R.A. Mackenzie, Ging Yuek R. Hsiung, Barbara Borroni, Giacomina Rossi, Fabrizio Tagliavini, Zbigniew K. Wszolek, Ronald C. Petersen, Eileen H. Bigio, Murray Grossman, Vivianna M. Van Deerlin, William W. Seeley, Bruce L. Miller, Neill R. Graff-Radford, Bradley F. Boeve, Dennis W. Dickson, Joanna M. Biernacka, Rosa Rademakers^*

^*Corresponding author for this work

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

104 Scopus citations

Abstract

Background: Loss-of-function mutations in GRN cause frontotemporal lobar degeneration (FTLD). Patients with GRN mutations present with a uniform subtype of TAR DNA-binding protein 43 (TDP-43) pathology at autopsy (FTLD-TDP type A); however, age at onset and clinical presentation are variable, even within families. We aimed to identify potential genetic modifiers of disease onset and disease risk in GRN mutation carriers. Methods: The study was done in three stages: a discovery stage, a replication stage, and a meta-analysis of the discovery and replication data. In the discovery stage, genome-wide logistic and linear regression analyses were done to test the association of genetic variants with disease risk (case or control status) and age at onset in patients with a GRN mutation and controls free of neurodegenerative disorders. Suggestive loci (p<1 × 10 ⁻⁵ ) were genotyped in a replication cohort of patients and controls, followed by a meta-analysis. The effect of genome-wide significant variants at the GFRA2 locus on expression of GFRA2 was assessed using mRNA expression studies in cerebellar tissue samples from the Mayo Clinic brain bank. The effect of the GFRA2 locus on progranulin concentrations was studied using previously generated ELISA-based expression data. Co-immunoprecipitation experiments in HEK293T cells were done to test for a direct interaction between GFRA2 and progranulin. Findings: Individuals were enrolled in the current study between Sept 16, 2014, and Oct 5, 2017. After quality control measures, statistical analyses in the discovery stage included 382 unrelated symptomatic GRN mutation carriers and 1146 controls free of neurodegenerative disorders collected from 34 research centres located in the USA, Canada, Australia, and Europe. In the replication stage, 210 patients (67 symptomatic GRN mutation carriers and 143 patients with FTLD without GRN mutations pathologically confirmed as FTLD-TDP type A) and 1798 controls free of neurodegenerative diseases were recruited from 26 sites, 20 of which overlapped with the discovery stage. No genome-wide significant association with age at onset was identified in the discovery or replication stages, or in the meta-analysis. However, in the case-control analysis, we replicated the previously reported TMEM106B association (rs1990622 meta-analysis odds ratio [OR] 0·54, 95% CI 0·46–0·63; p=3·54 × 10 ⁻¹⁶ ), and identified a novel genome-wide significant locus at GFRA2 on chromosome 8p21.3 associated with disease risk (rs36196656 meta-analysis OR 1·49, 95% CI 1·30–1·71; p=1·58 × 10 ⁻⁸ ). Expression analyses showed that the risk-associated allele at rs36196656 decreased GFRA2 mRNA concentrations in cerebellar tissue (p=0·04). No effect of rs36196656 on plasma and CSF progranulin concentrations was detected by ELISA; however, co-immunoprecipitation experiments in HEK293T cells did suggest a direct binding of progranulin and GFRA2. Interpretation: TMEM106B-related and GFRA2-related pathways might be future targets for treatments for FTLD, but the biological interaction between progranulin and these potential disease modifiers requires further study. TMEM106B and GFRA2 might also provide opportunities to select and stratify patients for future clinical trials and, when more is known about their potential effects, to inform genetic counselling, especially for asymptomatic individuals. Funding: National Institute on Aging, National Institute of Neurological Disorders and Stroke, Canadian Institutes of Health Research, Italian Ministry of Health, UK National Institute for Health Research, National Health and Medical Research Council of Australia, and the French National Research Agency.

Original language	English (US)
Pages (from-to)	548-558
Number of pages	11
Journal	The Lancet Neurology
Volume	17
Issue number	6
DOIs	https://doi.org/10.1016/S1474-4422(18)30126-1
State	Published - Jun 2018

Funding

We thank all colleagues and staff at the participating centres for their help with recruitment of patients. Specifically, we thank Masood Manoochehri, Chan Foong, Huei-Hsin Chiang, Andrew King, Ivy Trinh, Jeffrey Metcalf, Silvana Archetti, Pheth Sengdy, Alice Fok, Ewa Narożańska, David Lacomis, Nick Fox, Martin Rossor, Jason Warren, Virginia Phillips, Linda Rousseau, Monica Casey-Castanedes, Michael DeTure, Rosanna Colao, Gianfranco Puccio, Sabrina A M Curcio, Livia Bernardi, Eric M Wassermann, Martin Farlow, Ann Hake, Dimitrios I Kapogiannis, Keiji Yamaguchi, Matthew Hagen, Jose Bonnin, Melissa Gener, Lina Riedl, Michael Tierney, and The French Research Network on FTD and FTD/ALS for clinical, pathological and genetic characterisation of patients. This work was supported by NIH grants from the National Institute on Aging: P30 AG019610 (MNS, EMR, NRG-R, DWD); P30 AG012300 (CLW, BME); P50 AG025688 (JGl, MGe); P50 AG08702 (LSH); P30 AG013854 (EHB, M-MM, SW, CGe); P50 AG005133 (JK, OLL); P30 AG019610 (TGB); P01 AG003991 and P50 AG005681 (NJC and CC); R01 AG044546, RF1 AG053303, and P30 AG10124 (JQT); P01 AG017586 (JQT); P01 AG026276 (CC); U01 AG045390, UO1 AG006786, and RO1 AG041797 (BFB); R01 AG037491 (KAJ); P50 AG016574 (RCP, BFB, RR, DWD, DSK, NRG-R); R01 AG051848, R21 AG051839, and P50 AG005131 (RAR); RF AG051504 and U01 AG046139 (NE-T); P50 AG023501 and P01 AG019724 (WWS); and P30 AG010133 (BG, JRM, SSp, AO). The study was in also supported in part by the following NIH grants from NINDS: R35 NS097261 (RR), R01 NS076837 (EDH), P30 NS055077 (MGe), U54 NS092089 (BFB, ALB), P01 NS084974 (DWD), U24 NS072026 (TGB), R01 NS080820 (NE-T), and P50 NS072187 (ZKW). This work was also supported by NIH grants from the National Institute on Deafness and Other Communication Disorders (R01 DC008552 to SW and M-MM) and from the Department of Veterans Affairs (I01 BX003040 to RAR). Furthermore, this work was supported by grants from the Consortium for Frontotemporal dementia (RR); the Bluefield Project to Cure FTD (XZ); the Mayo Clinic Dorothy and Harry T Mangurian Jr Lewy Body Dementia Program and the Little Family Foundation (BFB); the Carl B and Florence E King Foundation (BME, CLW); the McCune Foundation and the Winspear Family Center for Research on the Neuropathology of Alzheimer Disease (CLW); the University of Pittsburgh Brain Institute (JK); the Arizona Department of Health Services contract 211002 (TGB); Arizona Biomedical Research Commission contracts 4001, 0011, 05-901, and 1001 (TGB); the Michael J Fox Foundation for Parkinson's Research (TGB); GHR Foundation (RCP, TGB); Mayo Clinic Foundation and the Sun Health Foundation (TGB); the Arizona Department of Health Services (EMR); and The Tau Consortium and the Consortium for Frontotemporal Dementia Resesarch (WWS). We thank the Canadian Institutes of Health Research for the following support provided for this study: MOP13129 (SEB, MM); MOP137116 (MM); #179009 (G-YRH, IRAM); and #327387 (ECF). We also thank the Canadian Consortium on Neurodegeneration in Aging (SEB, ER), in particular for grant #137794 (G-YRH, IRAM); and the LC Campbell Foundation (SEB). In addition, this study was supported by the Ricerca Corrente, Italian Ministry of Health (GR, RG, LB, GB, DG, FT); the Ministry of Health Finalizzata 2011 ref 14GRSB and Fondazione Cassa di Risparmio di Firenze ref 2015-0722 (BN, CF, SB, SSo); AIRAlzh onlus – ANCC-COOP (IP, GGF); and the Telethon Foundation and Ricerca Finalizzata, Italian Ministry of Health (FT). Some of the tissue samples were supplied by The London Neurodegenerative Diseases Brain Bank, which receives funding from the UK Medical Research Council (MRC) and as part of the Brains for Dementia Research programme, jointly funded by Alzheimer's Research UK and the Alzheimer's Society (CT). SP-B was supported by MRC grant G0701441. The Dementia Research Centre at UCL is supported by Alzheimer's Research UK, Brain Research Trust, and the Wolfson Foundation. This work is further supported by the NIHR Queen Square Dementia Biomedical Research Unit, the NIHR UCLH Biomedical Research Centre and the Leonard Wolfson Experimental Neurology Centre Clinical Research Facility. JH received funding from the Wellcome/MRC Centre on Parkinson's. RF was supported by the Alzheimer's Society Grant 284, and RM by The office of the Dean of the School of Medicine, Department of Internal Medicine, at Texas Tech University Health Sciences Center. JDR was supported by an MRC Clinician Scientist Fellowship (MR/M008525/1) and has received funding from the NIHR Rare Disease Translational Research Collaboration (BRC149/NS/MH). ILB, FP, and DH received funding from the Program “Investissements d'avenir” ANR-10-IAIHU-06 and the PHRC FTLDexome (promotion AP-HP). GMH, JBK, JRH, and OP are part of The ForeFront Brain and Mind project team, a large collaborative research group dedicated to the study of neurodegenerative diseases funded by the National Health and Medical Research Council of Australia (NHMRC) Program Grant (#1037746) and Project Grant (#1062539), Dementia Research Team Grant (#1095127), and NeuroSleep Centre of Research Excellence (#1060992), as well as the Australian Research Council Centre of Excellence in Cognition and its Disorders Memory Program (#CE110001021), and the Sydney Research Excellence Initiative 2020. OP is supported by an NHMRC Senior Research Fellowship (APP1103258). GMH is supported by an NHMRC Senior Principal Research Fellowship (630434). CGr is supported by grants provided by the Swedish Research Council (Dnr 521-2010-3134, 529-2014-7504, 2015-02926), Alzheimer Foundation Sweden, Brain Foundation Sweden, Swedish FTD Initiative, Swedish Brain Power, Karolinska Institutet doctoral funding, Gamla Tjänarinnor, Stohnes Foundation, Dementia Foundation Sweden, and the Stockholm County Council (ALF project). MN is funded by German Helmholtz Association, Nomis Foundation, and German Research Foundation. MS is funded by the Else Kröner Fresenius Stiftung. JD-S is supported by German Federal Ministry of Education and Research (FTLDc O1GI1007A). RS-V is supported by Fundació Marató de TV3, Barcelona, Spain (grant 20143810). JCvS is funded by Memorabel 2013 Presympt FTD #70-73305-98-105, JPND RiMod #733051024, and Alzheimer Nederland, de Ruiter #WE.15-2014-08. JSl is supported by the Ministry of Health, Medical University of Gdansk. MNS reports grants from Avid Radiopharmaceuticals, Genentech, Merck, Pfizer, Roche, and Suven Life Sciences; reports grants and personal fees from Axovant Sciences, Biogen, Eli Lilly, and vTv Therapeutics; reports personal fees from Grifols and Sanofi; and holds stock in Brain Health, Muses Labs, and Versanum. ALB reports grants from the National Institutes of Health (NIH), Bluefield Project to Cure Frontotemporal Dementia, CBD Solutions, the Tau Consortium, Biogen, Bristol-Myers Squibb, C2N Diagnostics, FORUM Pharmaceuticals, Genentech, Roche, TauRx Therapeutics, and Association for Frontotemporal Degeneration; personal fees from AbbVie, Delos Pharmaceuticals, Denali Therapeutics, Alector, Janssen Pharmaceutica, Celgene, Merck, Novartis, Toyama Chemical, and UCB; and grants and non-financial support from Eli Lilly. GMH reports grants from the Australian National Health and Medical Research Council (grant numbers 1037747, 1079679). ZKW reports grants from the NIH/National Institute of Neurological Disorders and Stroke (NINDS; grant number P50 NS072187). RCP reports personal fees from Roche, Merck, Genentech, and Biogen. All other authors declare no competing interests.

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Clinical Neurology

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10.1016/S1474-4422(18)30126-1

Cite this

Pottier, C., Zhou, X., Perkerson, R. B., Baker, M., Jenkins, G. D., Serie, D. J., Ghidoni, R., Benussi, L., Binetti, G., López de Munain, A., Zulaica, M., Moreno, F., Le Ber, I., Pasquier, F., Hannequin, D., Sánchez-Valle, R., Antonell, A., Lladó, A., Parsons, T. M., ... Rademakers, R. (2018). Potential genetic modifiers of disease risk and age at onset in patients with frontotemporal lobar degeneration and GRN mutations: a genome-wide association study. The Lancet Neurology, 17(6), 548-558. https://doi.org/10.1016/S1474-4422(18)30126-1

@article{9d476fb09dc5474dbede92c3489e270f,

title = "Potential genetic modifiers of disease risk and age at onset in patients with frontotemporal lobar degeneration and GRN mutations: a genome-wide association study",

abstract = " Background: Loss-of-function mutations in GRN cause frontotemporal lobar degeneration (FTLD). Patients with GRN mutations present with a uniform subtype of TAR DNA-binding protein 43 (TDP-43) pathology at autopsy (FTLD-TDP type A); however, age at onset and clinical presentation are variable, even within families. We aimed to identify potential genetic modifiers of disease onset and disease risk in GRN mutation carriers. Methods: The study was done in three stages: a discovery stage, a replication stage, and a meta-analysis of the discovery and replication data. In the discovery stage, genome-wide logistic and linear regression analyses were done to test the association of genetic variants with disease risk (case or control status) and age at onset in patients with a GRN mutation and controls free of neurodegenerative disorders. Suggestive loci (p<1 × 10 −5 ) were genotyped in a replication cohort of patients and controls, followed by a meta-analysis. The effect of genome-wide significant variants at the GFRA2 locus on expression of GFRA2 was assessed using mRNA expression studies in cerebellar tissue samples from the Mayo Clinic brain bank. The effect of the GFRA2 locus on progranulin concentrations was studied using previously generated ELISA-based expression data. Co-immunoprecipitation experiments in HEK293T cells were done to test for a direct interaction between GFRA2 and progranulin. Findings: Individuals were enrolled in the current study between Sept 16, 2014, and Oct 5, 2017. After quality control measures, statistical analyses in the discovery stage included 382 unrelated symptomatic GRN mutation carriers and 1146 controls free of neurodegenerative disorders collected from 34 research centres located in the USA, Canada, Australia, and Europe. In the replication stage, 210 patients (67 symptomatic GRN mutation carriers and 143 patients with FTLD without GRN mutations pathologically confirmed as FTLD-TDP type A) and 1798 controls free of neurodegenerative diseases were recruited from 26 sites, 20 of which overlapped with the discovery stage. No genome-wide significant association with age at onset was identified in the discovery or replication stages, or in the meta-analysis. However, in the case-control analysis, we replicated the previously reported TMEM106B association (rs1990622 meta-analysis odds ratio [OR] 0·54, 95\% CI 0·46–0·63; p=3·54 × 10 −16 ), and identified a novel genome-wide significant locus at GFRA2 on chromosome 8p21.3 associated with disease risk (rs36196656 meta-analysis OR 1·49, 95\% CI 1·30–1·71; p=1·58 × 10 −8 ). Expression analyses showed that the risk-associated allele at rs36196656 decreased GFRA2 mRNA concentrations in cerebellar tissue (p=0·04). No effect of rs36196656 on plasma and CSF progranulin concentrations was detected by ELISA; however, co-immunoprecipitation experiments in HEK293T cells did suggest a direct binding of progranulin and GFRA2. Interpretation: TMEM106B-related and GFRA2-related pathways might be future targets for treatments for FTLD, but the biological interaction between progranulin and these potential disease modifiers requires further study. TMEM106B and GFRA2 might also provide opportunities to select and stratify patients for future clinical trials and, when more is known about their potential effects, to inform genetic counselling, especially for asymptomatic individuals. Funding: National Institute on Aging, National Institute of Neurological Disorders and Stroke, Canadian Institutes of Health Research, Italian Ministry of Health, UK National Institute for Health Research, National Health and Medical Research Council of Australia, and the French National Research Agency.",

author = "Cyril Pottier and Xiaolai Zhou and Perkerson, \{Ralph B.\} and Matt Baker and Jenkins, \{Gregory D.\} and Serie, \{Daniel J.\} and Roberta Ghidoni and Luisa Benussi and Giuliano Binetti and \{L{\'o}pez de Munain\}, Adolfo and Miren Zulaica and Fermin Moreno and \{Le Ber\}, Isabelle and Florence Pasquier and Didier Hannequin and Raquel S{\'a}nchez-Valle and Anna Antonell and Albert Llad{\'o} and Parsons, \{Tammee M.\} and Finch, \{Ni Cole A.\} and Finger, \{Elizabeth C.\} and Lippa, \{Carol F.\} and Huey, \{Edward D.\} and Manuela Neumann and Peter Heutink and Matthis Synofzik and Carlo Wilke and Rissman, \{Robert A.\} and Jaroslaw Slawek and Emilia Sitek and Peter Johannsen and Nielsen, \{J{\o}rgen E.\} and Yingxue Ren and \{van Blitterswijk\}, Marka and Mariely DeJesus-Hernandez and Elizabeth Christopher and Murray, \{Melissa E.\} and Bieniek, \{Kevin F.\} and Evers, \{Bret M.\} and Camilla Ferrari and Sara Rollinson and Anna Richardson and Elio Scarpini and Fumagalli, \{Giorgio G.\} and Alessandro Padovani and John Hardy and Parastoo Momeni and Raffaele Ferrari and Francesca Frangipane and Raffaele Maletta and Maria Anfossi and Maura Gallo and Leonard Petrucelli and Suh, \{Eun Ran\} and Lopez, \{Oscar L.\} and Wong, \{Tsz H.\} and \{van Rooij\}, \{Jeroen G.J.\} and Harro Seelaar and Simon Mead and Caselli, \{Richard J.\} and Reiman, \{Eric M.\} and \{Noel Sabbagh\}, Marwan and Mads Kjolby and Anders Nykjaer and Karydas, \{Anna M.\} and Boxer, \{Adam L.\} and Grinberg, \{Lea T.\} and Jordan Grafman and Salvatore Spina and Adrian Oblak and Mesulam, \{M. Marsel\} and Sandra Weintraub and Changiz Geula and Hodges, \{John R.\} and Olivier Piguet and Brooks, \{William S.\} and Irwin, \{David J.\} and Trojanowski, \{John Q.\} and Lee, \{Edward B.\} and Josephs, \{Keith A.\} and Parisi, \{Joseph E.\} and Nil{\"u}fer Ertekin-Taner and Knopman, \{David S.\} and Benedetta Nacmias and Irene Piaceri and Silvia Bagnoli and Sandro Sorbi and Marla Gearing and Jonathan Glass and Beach, \{Thomas G.\} and Black, \{Sandra E.\} and Mario Masellis and Ekaterina Rogaeva and Vonsattel, \{Jean Paul\} and Honig, \{Lawrence S.\} and Julia Kofler and Bruni, \{Amalia C.\} and Julie Snowden and David Mann and Stuart Pickering-Brown and Janine Diehl-Schmid and Juliane Winkelmann and Daniela Galimberti and Caroline Graff and Linn {\"O}ijerstedt and Claire Troakes and Safa Al-Sarraj and Carlos Cruchaga and Cairns, \{Nigel J.\} and Rohrer, \{Jonathan D.\} and Halliday, \{Glenda M.\} and Kwok, \{John B.\} and \{van Swieten\}, \{John C.\} and White, \{Charles L.\} and Bernardino Ghetti and Murell, \{Jill R.\} and Mackenzie, \{Ian R.A.\} and Hsiung, \{Ging Yuek R.\} and Barbara Borroni and Giacomina Rossi and Fabrizio Tagliavini and Wszolek, \{Zbigniew K.\} and Petersen, \{Ronald C.\} and Bigio, \{Eileen H.\} and Murray Grossman and \{Van Deerlin\}, \{Vivianna M.\} and Seeley, \{William W.\} and Miller, \{Bruce L.\} and Graff-Radford, \{Neill R.\} and Boeve, \{Bradley F.\} and Dickson, \{Dennis W.\} and Biernacka, \{Joanna M.\} and Rosa Rademakers",

note = "Publisher Copyright: {\textcopyright} 2018 Elsevier Ltd",

year = "2018",

month = jun,

doi = "10.1016/S1474-4422(18)30126-1",

language = "English (US)",

volume = "17",

pages = "548--558",

journal = "The Lancet Neurology",

issn = "1474-4422",

publisher = "Elsevier Ltd",

number = "6",

}

Pottier, C, Zhou, X, Perkerson, RB, Baker, M, Jenkins, GD, Serie, DJ, Ghidoni, R, Benussi, L, Binetti, G, López de Munain, A, Zulaica, M, Moreno, F, Le Ber, I, Pasquier, F, Hannequin, D, Sánchez-Valle, R, Antonell, A, Lladó, A, Parsons, TM, Finch, NCA, Finger, EC, Lippa, CF, Huey, ED, Neumann, M, Heutink, P, Synofzik, M, Wilke, C, Rissman, RA, Slawek, J, Sitek, E, Johannsen, P, Nielsen, JE, Ren, Y, van Blitterswijk, M, DeJesus-Hernandez, M, Christopher, E, Murray, ME, Bieniek, KF, Evers, BM, Ferrari, C, Rollinson, S, Richardson, A, Scarpini, E, Fumagalli, GG, Padovani, A, Hardy, J, Momeni, P, Ferrari, R, Frangipane, F, Maletta, R, Anfossi, M, Gallo, M, Petrucelli, L, Suh, ER, Lopez, OL, Wong, TH, van Rooij, JGJ, Seelaar, H, Mead, S, Caselli, RJ, Reiman, EM, Noel Sabbagh, M, Kjolby, M, Nykjaer, A, Karydas, AM, Boxer, AL, Grinberg, LT, Grafman, J, Spina, S, Oblak, A, Mesulam, MM , Weintraub, S , Geula, C, Hodges, JR, Piguet, O, Brooks, WS, Irwin, DJ, Trojanowski, JQ, Lee, EB, Josephs, KA, Parisi, JE, Ertekin-Taner, N, Knopman, DS, Nacmias, B, Piaceri, I, Bagnoli, S, Sorbi, S, Gearing, M, Glass, J, Beach, TG, Black, SE, Masellis, M, Rogaeva, E, Vonsattel, JP, Honig, LS, Kofler, J, Bruni, AC, Snowden, J, Mann, D, Pickering-Brown, S, Diehl-Schmid, J, Winkelmann, J, Galimberti, D, Graff, C, Öijerstedt, L, Troakes, C, Al-Sarraj, S, Cruchaga, C, Cairns, NJ, Rohrer, JD, Halliday, GM, Kwok, JB, van Swieten, JC, White, CL, Ghetti, B, Murell, JR, Mackenzie, IRA, Hsiung, GYR, Borroni, B, Rossi, G, Tagliavini, F, Wszolek, ZK, Petersen, RC, Bigio, EH, Grossman, M, Van Deerlin, VM, Seeley, WW, Miller, BL, Graff-Radford, NR, Boeve, BF, Dickson, DW, Biernacka, JM & Rademakers, R 2018, 'Potential genetic modifiers of disease risk and age at onset in patients with frontotemporal lobar degeneration and GRN mutations: a genome-wide association study', The Lancet Neurology, vol. 17, no. 6, pp. 548-558. https://doi.org/10.1016/S1474-4422(18)30126-1

TY - JOUR

T1 - Potential genetic modifiers of disease risk and age at onset in patients with frontotemporal lobar degeneration and GRN mutations

T2 - a genome-wide association study

AU - Pottier, Cyril

AU - Zhou, Xiaolai

AU - Perkerson, Ralph B.

AU - Baker, Matt

AU - Jenkins, Gregory D.

AU - Serie, Daniel J.

AU - Ghidoni, Roberta

AU - Benussi, Luisa

AU - Binetti, Giuliano

AU - López de Munain, Adolfo

AU - Zulaica, Miren

AU - Moreno, Fermin

AU - Le Ber, Isabelle

AU - Pasquier, Florence

AU - Hannequin, Didier

AU - Sánchez-Valle, Raquel

AU - Antonell, Anna

AU - Lladó, Albert

AU - Parsons, Tammee M.

AU - Finch, Ni Cole A.

AU - Finger, Elizabeth C.

AU - Lippa, Carol F.

AU - Huey, Edward D.

AU - Neumann, Manuela

AU - Heutink, Peter

AU - Synofzik, Matthis

AU - Wilke, Carlo

AU - Rissman, Robert A.

AU - Slawek, Jaroslaw

AU - Sitek, Emilia

AU - Johannsen, Peter

AU - Nielsen, Jørgen E.

AU - Ren, Yingxue

AU - van Blitterswijk, Marka

AU - DeJesus-Hernandez, Mariely

AU - Christopher, Elizabeth

AU - Murray, Melissa E.

AU - Bieniek, Kevin F.

AU - Evers, Bret M.

AU - Ferrari, Camilla

AU - Rollinson, Sara

AU - Richardson, Anna

AU - Scarpini, Elio

AU - Fumagalli, Giorgio G.

AU - Padovani, Alessandro

AU - Hardy, John

AU - Momeni, Parastoo

AU - Ferrari, Raffaele

AU - Frangipane, Francesca

AU - Maletta, Raffaele

AU - Anfossi, Maria

AU - Gallo, Maura

AU - Petrucelli, Leonard

AU - Suh, Eun Ran

AU - Lopez, Oscar L.

AU - Wong, Tsz H.

AU - van Rooij, Jeroen G.J.

AU - Seelaar, Harro

AU - Mead, Simon

AU - Caselli, Richard J.

AU - Reiman, Eric M.

AU - Noel Sabbagh, Marwan

AU - Kjolby, Mads

AU - Nykjaer, Anders

AU - Karydas, Anna M.

AU - Boxer, Adam L.

AU - Grinberg, Lea T.

AU - Grafman, Jordan

AU - Spina, Salvatore

AU - Oblak, Adrian

AU - Mesulam, M. Marsel

AU - Weintraub, Sandra

AU - Geula, Changiz

AU - Hodges, John R.

AU - Piguet, Olivier

AU - Brooks, William S.

AU - Irwin, David J.

AU - Trojanowski, John Q.

AU - Lee, Edward B.

AU - Josephs, Keith A.

AU - Parisi, Joseph E.

AU - Ertekin-Taner, Nilüfer

AU - Knopman, David S.

AU - Nacmias, Benedetta

AU - Piaceri, Irene

AU - Bagnoli, Silvia

AU - Sorbi, Sandro

AU - Gearing, Marla

AU - Glass, Jonathan

AU - Beach, Thomas G.

AU - Black, Sandra E.

AU - Masellis, Mario

AU - Rogaeva, Ekaterina

AU - Vonsattel, Jean Paul

AU - Honig, Lawrence S.

AU - Kofler, Julia

AU - Bruni, Amalia C.

AU - Snowden, Julie

AU - Mann, David

AU - Pickering-Brown, Stuart

AU - Diehl-Schmid, Janine

AU - Winkelmann, Juliane

AU - Galimberti, Daniela

AU - Graff, Caroline

AU - Öijerstedt, Linn

AU - Troakes, Claire

AU - Al-Sarraj, Safa

AU - Cruchaga, Carlos

AU - Cairns, Nigel J.

AU - Rohrer, Jonathan D.

AU - Halliday, Glenda M.

AU - Kwok, John B.

AU - van Swieten, John C.

AU - White, Charles L.

AU - Ghetti, Bernardino

AU - Murell, Jill R.

AU - Mackenzie, Ian R.A.

AU - Hsiung, Ging Yuek R.

AU - Borroni, Barbara

AU - Rossi, Giacomina

AU - Tagliavini, Fabrizio

AU - Wszolek, Zbigniew K.

AU - Petersen, Ronald C.

AU - Bigio, Eileen H.

AU - Grossman, Murray

AU - Van Deerlin, Vivianna M.

AU - Seeley, William W.

AU - Miller, Bruce L.

AU - Graff-Radford, Neill R.

AU - Boeve, Bradley F.

AU - Dickson, Dennis W.

AU - Biernacka, Joanna M.

AU - Rademakers, Rosa

PY - 2018/6

Y1 - 2018/6

N2 - Background: Loss-of-function mutations in GRN cause frontotemporal lobar degeneration (FTLD). Patients with GRN mutations present with a uniform subtype of TAR DNA-binding protein 43 (TDP-43) pathology at autopsy (FTLD-TDP type A); however, age at onset and clinical presentation are variable, even within families. We aimed to identify potential genetic modifiers of disease onset and disease risk in GRN mutation carriers. Methods: The study was done in three stages: a discovery stage, a replication stage, and a meta-analysis of the discovery and replication data. In the discovery stage, genome-wide logistic and linear regression analyses were done to test the association of genetic variants with disease risk (case or control status) and age at onset in patients with a GRN mutation and controls free of neurodegenerative disorders. Suggestive loci (p<1 × 10 −5 ) were genotyped in a replication cohort of patients and controls, followed by a meta-analysis. The effect of genome-wide significant variants at the GFRA2 locus on expression of GFRA2 was assessed using mRNA expression studies in cerebellar tissue samples from the Mayo Clinic brain bank. The effect of the GFRA2 locus on progranulin concentrations was studied using previously generated ELISA-based expression data. Co-immunoprecipitation experiments in HEK293T cells were done to test for a direct interaction between GFRA2 and progranulin. Findings: Individuals were enrolled in the current study between Sept 16, 2014, and Oct 5, 2017. After quality control measures, statistical analyses in the discovery stage included 382 unrelated symptomatic GRN mutation carriers and 1146 controls free of neurodegenerative disorders collected from 34 research centres located in the USA, Canada, Australia, and Europe. In the replication stage, 210 patients (67 symptomatic GRN mutation carriers and 143 patients with FTLD without GRN mutations pathologically confirmed as FTLD-TDP type A) and 1798 controls free of neurodegenerative diseases were recruited from 26 sites, 20 of which overlapped with the discovery stage. No genome-wide significant association with age at onset was identified in the discovery or replication stages, or in the meta-analysis. However, in the case-control analysis, we replicated the previously reported TMEM106B association (rs1990622 meta-analysis odds ratio [OR] 0·54, 95% CI 0·46–0·63; p=3·54 × 10 −16 ), and identified a novel genome-wide significant locus at GFRA2 on chromosome 8p21.3 associated with disease risk (rs36196656 meta-analysis OR 1·49, 95% CI 1·30–1·71; p=1·58 × 10 −8 ). Expression analyses showed that the risk-associated allele at rs36196656 decreased GFRA2 mRNA concentrations in cerebellar tissue (p=0·04). No effect of rs36196656 on plasma and CSF progranulin concentrations was detected by ELISA; however, co-immunoprecipitation experiments in HEK293T cells did suggest a direct binding of progranulin and GFRA2. Interpretation: TMEM106B-related and GFRA2-related pathways might be future targets for treatments for FTLD, but the biological interaction between progranulin and these potential disease modifiers requires further study. TMEM106B and GFRA2 might also provide opportunities to select and stratify patients for future clinical trials and, when more is known about their potential effects, to inform genetic counselling, especially for asymptomatic individuals. Funding: National Institute on Aging, National Institute of Neurological Disorders and Stroke, Canadian Institutes of Health Research, Italian Ministry of Health, UK National Institute for Health Research, National Health and Medical Research Council of Australia, and the French National Research Agency.

AB - Background: Loss-of-function mutations in GRN cause frontotemporal lobar degeneration (FTLD). Patients with GRN mutations present with a uniform subtype of TAR DNA-binding protein 43 (TDP-43) pathology at autopsy (FTLD-TDP type A); however, age at onset and clinical presentation are variable, even within families. We aimed to identify potential genetic modifiers of disease onset and disease risk in GRN mutation carriers. Methods: The study was done in three stages: a discovery stage, a replication stage, and a meta-analysis of the discovery and replication data. In the discovery stage, genome-wide logistic and linear regression analyses were done to test the association of genetic variants with disease risk (case or control status) and age at onset in patients with a GRN mutation and controls free of neurodegenerative disorders. Suggestive loci (p<1 × 10 −5 ) were genotyped in a replication cohort of patients and controls, followed by a meta-analysis. The effect of genome-wide significant variants at the GFRA2 locus on expression of GFRA2 was assessed using mRNA expression studies in cerebellar tissue samples from the Mayo Clinic brain bank. The effect of the GFRA2 locus on progranulin concentrations was studied using previously generated ELISA-based expression data. Co-immunoprecipitation experiments in HEK293T cells were done to test for a direct interaction between GFRA2 and progranulin. Findings: Individuals were enrolled in the current study between Sept 16, 2014, and Oct 5, 2017. After quality control measures, statistical analyses in the discovery stage included 382 unrelated symptomatic GRN mutation carriers and 1146 controls free of neurodegenerative disorders collected from 34 research centres located in the USA, Canada, Australia, and Europe. In the replication stage, 210 patients (67 symptomatic GRN mutation carriers and 143 patients with FTLD without GRN mutations pathologically confirmed as FTLD-TDP type A) and 1798 controls free of neurodegenerative diseases were recruited from 26 sites, 20 of which overlapped with the discovery stage. No genome-wide significant association with age at onset was identified in the discovery or replication stages, or in the meta-analysis. However, in the case-control analysis, we replicated the previously reported TMEM106B association (rs1990622 meta-analysis odds ratio [OR] 0·54, 95% CI 0·46–0·63; p=3·54 × 10 −16 ), and identified a novel genome-wide significant locus at GFRA2 on chromosome 8p21.3 associated with disease risk (rs36196656 meta-analysis OR 1·49, 95% CI 1·30–1·71; p=1·58 × 10 −8 ). Expression analyses showed that the risk-associated allele at rs36196656 decreased GFRA2 mRNA concentrations in cerebellar tissue (p=0·04). No effect of rs36196656 on plasma and CSF progranulin concentrations was detected by ELISA; however, co-immunoprecipitation experiments in HEK293T cells did suggest a direct binding of progranulin and GFRA2. Interpretation: TMEM106B-related and GFRA2-related pathways might be future targets for treatments for FTLD, but the biological interaction between progranulin and these potential disease modifiers requires further study. TMEM106B and GFRA2 might also provide opportunities to select and stratify patients for future clinical trials and, when more is known about their potential effects, to inform genetic counselling, especially for asymptomatic individuals. Funding: National Institute on Aging, National Institute of Neurological Disorders and Stroke, Canadian Institutes of Health Research, Italian Ministry of Health, UK National Institute for Health Research, National Health and Medical Research Council of Australia, and the French National Research Agency.

UR - https://www.scopus.com/pages/publications/85046353036

UR - https://www.scopus.com/inward/citedby.url?scp=85046353036&partnerID=8YFLogxK

U2 - 10.1016/S1474-4422(18)30126-1

DO - 10.1016/S1474-4422(18)30126-1

M3 - Article

C2 - 29724592

AN - SCOPUS:85046353036

SN - 1474-4422

VL - 17

SP - 548

EP - 558

JO - The Lancet Neurology

JF - The Lancet Neurology

IS - 6

ER -

Potential genetic modifiers of disease risk and age at onset in patients with frontotemporal lobar degeneration and GRN mutations: a genome-wide association study

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