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2. Using next-generation sequencing to understand the aetiology of dystonia and other neurological diseases

Author

Charlesworth, G.

Subjects
612.8
Abstract

This thesis presents my work using both next-generation and traditional genetic techniques aimed at further clarifying the aetiology of hereditary neurological disorders, with a particular focus on dystonia. A large part of this was focused on the identification, clinical phenotyping, and genetic analysis of kindreds with neurological disease inherited in a Mendelian fashion but for which no causal mutation had yet been identified. My work led directly to the discovery of two new dystonia genes, ANO3 and HPCA, and the identification of two novel phenotypes for the known disease-associated genes, ATM and NUBPL. Mutations in a third novel gene, SLC25A46, was identified as the most likely cause of disease in a kindred with a complex neurological disorder consisting of optic atrophy, severe action myoclonus and peripheral neuropathy, but could not be confirmed due to lack of a second segregating kindred - it was published, a year and a half after we had first identified it, by another group, just as I was in the process of submitting thesis. Taken together, these results confirm that whole exome sequencing in combination with linkage analysis or homozygosity mapping represents a powerful means of dissecting out the genetic aetiology of Mendelian disease. In addition, this thesis summarises my foray in the world of association analyses, a technique which underpins the recent explosion in knowledge regarding the genetic architecture of so-called 'complex' disease. I use this technique to show that the association signal over MAPT in Parkinson's disease survives when affectation status is defined neuropathologically. Finally, I present my work using traditional Sanger sequencing to better understand the prevalence of already published Mendelian disease genes for both dystonia and Parkinson's disease.

Published
2016

3. “Who to Tell, How and When?”: Development and Preliminary Feasibility of an Empowerment Intervention for People Living with Dementia Who are Fearful of Disclosing Their Diagnosis

Author

Bhatt J, Ruffell TO, Scior K, and Charlesworth G

Subjects
stigma, disclosure, dementia, psychosocial, post-diagnosis, Geriatrics, RC952-954.6
Abstract

Jem Bhatt,1 Tamatha Ophelia Ruffell,1 Katrina Scior,1 Georgina Charlesworth1,2 1Research Department of Clinical, Educational and Health Psychology, University College London, London, UK; 2Research and Development, North East London Foundation Trust, London, UKCorrespondence: Jem BhattResearch Department of Clinical, Educational and Health Psychology, University College London, 1-19 Torrington Place, London WC1E7HB, UKEmail jemini.bhatt.15@ucl.ac.ukObjective: This study describes the adaptation of Honest, Open, Proud (HOP), to develop an empowerment intervention supporting disclosure decision-making for dyads of people living with dementia and their chosen supporter.Methods: Medical Research Council guidelines for developing complex interventions informed intervention development and feasibility testing. This included identifying the evidence base and theory (establishing HOP theory of change, a systematic review on decision-making in dementia, a stakeholder consultation), modelling the intervention materials with research experts (creation of version 1.0) and experts by experience (creation of version 2.0), and pilot testing the intervention recording participant observations and facilitator reflections. The final version of the intervention materials was developed with experts by experience of dementia where the accessibility of language and appropriate styles of facilitation were the focus.Results: The concept of the intervention was strongly endorsed by respondents of the stakeholder consultation (209/226). Stakeholder preferences included face-to-face delivery, a manualized workbook approach and the inclusion of the primary carer during intervention delivery. Recruitment for intervention groups took place in non-NHS settings (2 small groups recruited) and NHS settings (no groups recruited). In non-NHS settings, 7 dyads agreed to take part in one of two intervention groups. Both intervention groups had over 70% attendance by participants (group 1: 72.2% group 2: 87.5%).Conclusion: The concept of an intervention to support diagnostic disclosure was endorsed by stakeholders; however, recruitment was challenging; the “who to tell, how and when?” intervention has the potential to fill a gap in the post-diagnostic pathway.Keywords: stigma, disclosure, dementia, psychosocial, post-diagnosis

Published
2020

4. The development of the Promoting Independence in Dementia (PRIDE) intervention to enhance independence in dementia

Author

Yates L, Csipke E, Moniz-Cook E, Leung P, Walton H, Charlesworth G, Spector A, Hogervorst E, Mountain G, and Orrell M

Subjects
self-management, public patient involvement, behavior change, manual, cognitive impairment, Geriatrics, RC952-954.6
Abstract

Lauren Yates1,*, Emese Csipke2,*, Esme Moniz-Cook3, Phuong Leung2, Holly Walton4, Georgina Charlesworth5, Aimee Spector5, Eef Hogervorst6, Gail Mountain7, Martin Orrell1 1Institute of Mental Health, University of Nottingham, Nottingham, UK; 2Division of Psychiatry, University College London, London, UK; 3Department of Psychological Health and Well-Being, Faculty of Health Sciences, School of Health and Social Work, University of Hull, Hull, UK; 4Department of Applied Health Research, University College London, London, UK; 5Department of Clinical, Educational and Health Psychology, University College London, London, UK; 6National Centre for Sports and Exercise Medicine, Loughborough University, Loughborough, UK; 7Centre for Applied Dementia Studies, University of Bradford, Bradford, UK*These authors contributed equally to this workCorrespondence: Emese CsipkeDivision of Psychiatry, University College London, 149 Tottenham Court Road, London W1T 7NF, UKTel +44 207 679 9306Email e.csipke@ucl.ac.ukObjective: Support after a diagnosis of dementia may facilitate better adjustment and ongoing management of symptoms. The aim of the Promoting Independence in Dementia (PRIDE) study was to develop a postdiagnostic social intervention to help people live as well and as independently as possible. The intervention facilitates engagement in evidence-based stimulating cognitive, physical and social activities.Methods: Theories to promote adjustment to a dementia diagnosis, including theories of social learning and self-efficacy, were reviewed alongside self-management and the selective optimization model, to form the basis of the intervention. Analyses of two longitudinal databases of older adults, and qualitative analyses of interviews of older people, people with dementia, and their carers about their experiences of dementia, informed the content and focus of the intervention. Consensus expert review involving stakeholders was conducted to synthesize key components. Participants were sourced from the British NHS, voluntary services, and patient and public involvement groups. A tailored manual-based intervention was developed with the aim for this to be delivered by an intervention provider.Results: Evidence-based stimulating cognitive, physical, and social activities that have been shown to benefit people were key components of the proposed PRIDE intervention. Thirty-two participants including people with dementia (n=4), carers (n=11), dementia advisers (n=14), and older people (n=3) provided feedback on the drafts of the intervention and manual. Seven topics for activities were included (eg, “making decisions” and “getting your message across”). The manual outlines delivery of the intervention over three sessions where personalized profiles and plans for up to three activities are developed, implemented, and reviewed.Conclusion: A manualized intervention was constructed based on robust methodology and found to be acceptable to participants. Consultations with stakeholders played a key role in shaping the manualized PRIDE intervention and its delivery. Unlike most social interventions for dementia, the target audience for our intervention is the people with dementia themselves.Keywords: self-management, public patient involvement, behavior change, manual, cognitive impairment

Published
2019

14. Selling surveillance technology: semiotic themes in advertisements for ageing in place with dementia.

Author

Vermeer, Y., Higgs, P., and Charlesworth, G.

Subjects
DEMENTIA, MIND-wandering, ADVERTISING, CONTENT analysis
Abstract

Six advertisements were explored that sell surveillance technologies for people living with dementia through qualitative content analysis. Advertisements from the United Kingdom, Sweden, and the Netherlands were analysed to explore semiotic textual meaning and people living with dementia (N = 5) and carers (N = 4) responded to these advertisements. The semiotic themes report a "wanderer" discourse which signals to track people living with dementia, children pets and possessions. Mainly negative representations communicate the dangers of wandering towards younger-female carers, few positive representations show a smiling person with dementia and only one person was represented as interacting with technology. Participants did not understand the advertisements and people living with dementia felt stigmatised. There is a lack of reflexivity when people living with dementia are seen as objects. The reliance on stereotypes targeted at carers with misunderstood conceivable trackers hinders resilience for people living with dementia and implies the continuous stigmatisation that occurs when they are disregarded as human technology-users. [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
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19. Mitochondrial complex I NUBPL mutations cause combined dystonia with bilateral striatal necrosis and cerebellar atrophy

Author

Balint, B. Charlesworth, G. Stamelou, M. Carr, L. Mencacci, N.E. Wood, N.W. Bhatia, K.P.

Abstract

Background and purpose: The recent advances in genetics have helped to unravel the cause of many dystonia syndromes. With the broadening spectrum of genetically defined dystonia syndromes, distinct clinico-radiological phenotypes are a welcome handle to guide the diagnostic work-up. Methods: Exome sequencing was used to elucidate the genetic cause of a syndrome characterized by generalized dystonia, pyramidal and cerebellar involvement, with bilateral striatal necrosis (BSN) and cerebellar atrophy on magnetic resonance imaging. Homozygosity mapping and linkage analysis were used in a supportive role. Known genetic causes of BSN were excluded by use of exome data or Sanger sequencing. Results: Compound heterozygous mutations were identified in the NUBPL gene in a small UK kindred. The gene lay in a region of positive linkage and segregated with disease in a family of six individuals. Conclusion: NUBPL mutations cause early onset, autosomal recessive generalized dystonia with cerebellar ataxia, pyramidal signs, preserved cognition and a distinct magnetic resonance imaging appearance with BSN and cerebellar atrophy. © 2019 The Authors. European Journal of Neurology published by John Wiley & Sons Ltd on behalf of European Academy of Neurology.

Published
2019

20. Factors related to sense of competence in family caregivers of people living with dementia in the community: a narrative synthesis

Author

Stansfeld, J., Crellin, N., Orrell, M., Wenborn, J., Charlesworth, G., Vernooij-Dassen, M.J.F.J., Stansfeld, J., Crellin, N., Orrell, M., Wenborn, J., Charlesworth, G., and Vernooij-Dassen, M.J.F.J.

Abstract

Contains fulltext : 208495.pdf (publisher's version ) (Closed access), Objectives:Sense of competence defines a caregiver's feeling of being capable to manage the caregiving task and is an important clinical concept in the caregiving literature. The aim of this review was to identify the factors, both positive and negative, associated with a caregiver's perception of their sense of competence. DESIGN: A systematic review of the literature was conducted, retrieving both quantitative and qualitative papers from databases PsycINFO, CINAHL, EMBASE, and Medline. A quality assessment was conducted using the STROBE and CASP checklists, and the quality rating informed the inclusion of papers ensuring the evidence was robust. Narrative synthesis was employed to synthesize the findings and to generate an updated conceptual model of sense of competence. RESULTS: Seventeen papers were included in the review, all of which were moderate to high quality. These included 13 quantitative, three mixed-methods and one qualitative study. Factors associated with sense of competence included: behavioral and psychological symptoms of dementia (BPSD), caregiver depression, gratitude, and the ability to find meaning in caregiving. CONCLUSIONS: The results of this review demonstrate that both positive and negative aspects of caring are associated with caregiver sense of competence. Positive and negative aspects of caregiving act in tandem to influence caregiver perception of their competence. The proposed model of sense of competence aims to guide future research and clinical interventions aimed at improving this domain but requires further testing, as due to the observational nature of the include papers, the direction of causality could not be inferred.

Published
2019

22. Core outcome measures for interventions to prevent or slow the progress of dementia for people living with mild to moderate dementia: Systematic review and consensus recommendations

Author

Webster, L, Groskreutz, D, Grinbergs-Saull, A, Howard, R, O'Brien, JT, Mountain, G, Banerjee, S, Woods, B, Perneczky, R, Lafortune, L, Roberts, C, McCleery, J, Pickett, J, Bunn, F, Challis, D, Charlesworth, G, Featherstone, K, Fox, C, Goodman, C, Jones, R, Lamb, S, Moniz-Cook, E, Schneider, J, Shepperd, S, Surr, C, Thompson-Coon, J, Ballard, C, Brayne, C, Burns, A, Clare, L, Garrard, P, Kehoe, P, Passmore, P, Holmes, C, Maidment, I, Robinson, L, Livingston, G, and Quinn, TJ

Abstract

BACKGROUND: There are no disease-modifying treatments for dementia. There is also no consensus on disease modifying outcomes. We aimed to produce the first evidence-based consensus on core outcome measures for trials of disease modification in mild-to-moderate dementia. METHODS AND FINDINGS: We defined disease-modification interventions as those aiming to change the underlying pathology. We systematically searched electronic databases and previous systematic reviews for published and ongoing trials of disease-modifying treatments in mild-to-moderate dementia. We included 149/22,918 of the references found; with 81 outcome measures from 125 trials. Trials involved participants with Alzheimer's disease (AD) alone (n = 111), or AD and mild cognitive impairment (n = 8) and three vascular dementia. We divided outcomes by the domain measured (cognition, activities of daily living, biological markers, neuropsychiatric symptoms, quality of life, global). We calculated the number of trials and of participants using each outcome. We detailed psychometric properties of each outcome. We sought the views of people living with dementia and family carers in three cities through Alzheimer's society focus groups. Attendees at a consensus conference (experts in dementia research, disease-modification and harmonisation measures) decided on the core set of outcomes using these results. Recommended core outcomes were cognition as the fundamental deficit in dementia and to indicate disease modification, serial structural MRIs. Cognition should be measured by Mini Mental State Examination or Alzheimer's Disease Assessment Scale-Cognitive Subscale. MRIs would be optional for patients. We also made recommendations for measuring important, but non-core domains which may not change despite disease modification. LIMITATIONS: Most trials were about AD. Specific instruments may be superseded. We searched one database for psychometric properties. INTERPRETATION: This is the first review to identify the 81 outcome measures the research community uses for disease-modifying trials in mild-to-moderate dementia. Our recommendations will facilitate designing, comparing and meta-analysing disease modification trials in mild-to-moderate dementia, increasing their value. TRIAL REGISTRATION: PROSPERO no. CRD42015027346.

Published
2017

23. Discovery and functional prioritization of Parkinson's disease candidate genes from large-scale whole exome sequencing

Author

Jansen, IE, Ye, H, Heetveld, S, Lechler, MC, Michels, H, Seinstra, RI, Lubbe, SJ, Drouet, V, Lesage, S, Majounie, E, Gibbs, JR, Nalls, MA, Ryten, M, Botia, JA, Vandrovcova, J, Simon-Sanchez, J, Castillo-Lizardo, M, Rizzu, P, Blauwendraat, C, Chouhan, AK, Li, Y, Yogi, P, Amin, N, van Duijn, CM, Morris, HR, Brice, A, Singleton, AB, David, DC, Nollen, EA, Jain, S, Shulman, JM, Heutink, P, Hernandez, DG, Arepalli, S, Brooks, J, Price, R, Nicolas, A, Chong, S, Cookson, MR, Dillman, A, Moore, M, Traynor, BJ, Plagnol, V, Nicholas, WW, Sheerin, UM, Jose, MB, Charlesworth, G, Gardner, M, Guerreiro, R, Trabzuni, D, Hardy, J, Sharma, M, Saad, M, Javier, S-S, Schulte, C, Corvol, JC, Dürr, A, Vidailhet, M, Sveinbjörnsdóttir, S, Barker, R, Caroline, HW-G, Ben-Shlomo, Y, Berendse, HW, van Dijk, KD, Berg, D, Brockmann, K, Wurster, I, Mätzler, W, Gasser, T, Martinez, M, de Bie, RMA, Biffi, A, and Velseboer, D

Abstract

Background: Whole-exome sequencing (WES) has been successful in identifying genes that cause familial Parkinson's disease (PD). However, until now this approach has not been deployed to study large cohorts of unrelated participants. To discover rare PD susceptibility variants, we performed WES in 1148 unrelated cases and 503 control participants. Candidate genes were subsequently validated for functions relevant to PD based on parallel RNA-interference (RNAi) screens in human cell culture and Drosophila and C. elegans models. Results: Assuming autosomal recessive inheritance, we identify 27 genes that have homozygous or compound heterozygous loss-of-function variants in PD cases. Definitive replication and confirmation of these findings were hindered by potential heterogeneity and by the rarity of the implicated alleles. We therefore looked for potential genetic interactions with established PD mechanisms. Following RNAi-mediated knockdown, 15 of the genes modulated mitochondrial dynamics in human neuronal cultures and four candidates enhanced α-synuclein-induced neurodegeneration in Drosophila. Based on complementary analyses in independent human datasets, five functionally validated genes-GPATCH2L, UHRF1BP1L, PTPRH, ARSB, and VPS13C-also showed evidence consistent with genetic replication. Conclusions: By integrating human genetic and functional evidence, we identify several PD susceptibility gene candidates for further investigation. Our approach highlights a powerful experimental strategy with broad applicability for future studies of disorders with complex genetic etiologies.

Published
2017

26. Development of a core outcome set for disease modification trials in mild to moderate dementia: a systematic review, patient and public consultation and consensus recommendations.

Author

Webster, L, Groskreutz, D, Grinbergs-Saull, A, Howard, R, O'Brien, JT, Mountain, G, Banerjee, S, Woods, B, Perneczky, R, Lafortune, L, Roberts, C, McCleery, J, Pickett, J, Bunn, F, Challis, D, Charlesworth, G, Featherstone, K, Fox, C, Goodman, C, Jones, R, Lamb, S, Moniz-Cook, E, Schneider, J, Shepperd, S, Surr, C, Thompson-Coon, J, Ballard, C, Brayne, C, Burke, O, Burns, A, Clare, L, Garrard, P, Kehoe, P, Passmore, P, Holmes, C, Maidment, I, Murtagh, F, Robinson, L, Livingston, G, Webster, L, Groskreutz, D, Grinbergs-Saull, A, Howard, R, O'Brien, JT, Mountain, G, Banerjee, S, Woods, B, Perneczky, R, Lafortune, L, Roberts, C, McCleery, J, Pickett, J, Bunn, F, Challis, D, Charlesworth, G, Featherstone, K, Fox, C, Goodman, C, Jones, R, Lamb, S, Moniz-Cook, E, Schneider, J, Shepperd, S, Surr, C, Thompson-Coon, J, Ballard, C, Brayne, C, Burke, O, Burns, A, Clare, L, Garrard, P, Kehoe, P, Passmore, P, Holmes, C, Maidment, I, Murtagh, F, Robinson, L, and Livingston, G

Abstract

BACKGROUND: There is currently no disease-modifying treatment available to halt or delay the progression of the disease pathology in dementia. An agreed core set of the best-available and most appropriate outcomes for disease modification would facilitate the design of trials and ensure consistency across disease modification trials, as well as making results comparable and meta-analysable in future trials. OBJECTIVES: To agree a set of core outcomes for disease modification trials for mild to moderate dementia with the UK dementia research community and patient and public involvement (PPI). DATA SOURCES: We included disease modification trials with quantitative outcomes of efficacy from (1) references from related systematic reviews in workstream 1; (2) searches of the Cochrane Dementia and Cognitive Improvement Group study register, Cochrane Central Register of Controlled Trials, Cumulative Index to Nursing and Allied Health Literature, EMBASE, Latin American and Caribbean Health Sciences Literature and PsycINFO on 11 December 2015, and clinical trial registries [International Standard Randomised Controlled Trial Number (ISRCTN) and clinicaltrials.gov] on 22 and 29 January 2016; and (3) hand-searches of reference lists of relevant systematic reviews from database searches. REVIEW METHODS: The project consisted of four workstreams. (1) We obtained related core outcome sets and work from co-applicants. (2) We systematically reviewed published and ongoing disease modification trials to identify the outcomes used in different domains. We extracted outcomes used in each trial, recording how many used each outcome and with how many participants. We divided outcomes into the domains measured and searched for validation data. (3) We consulted with PPI participants about recommended outcomes. (4) We presented all the synthesised information at a conference attended by the wider body of National Institute for Health Research (NIHR) dementia researchers to reach consensus on

Published
2017

28. Serum iron levels and the risk of Parkinson Disease: a Mendelian randomization study

Author

Pichler I, Del Greco M. F, Gögele M, Lill CM, Bertram L, Do CB, Eriksson N, Foroud T, Myers RH, PD GWAS Consortium, Nalls M, Keller MF, International Parkinson's Disease Genomics Consortium, Wellcome Trust Case Control Consortium 2, Benyamin B, Whitfield JB, Genetics of Iron Status Consortium, Pramstaller PP, Hicks AA, Thompson JR, Minelli C., Plagnol V, Hernandez DG, Sharma M, Sheerin UM, Saad M, Simón Sánchez J, Schulte C, Lesage S, Arepalli S, Barker R, Ben Shlomo Y, Berendse HW, Berg D, Bhatia K, de Bie RM, Biffi A, Bloem B, Bochdanovits Z, Bonin M, Bras JM, Brockmann K, Brooks J, Burn DJ, Charlesworth G, Chen H, Chinnery PF, Chong S, Clarke CE, Cookson MR, Cooper JM, Corvol JC, Counsell C, Damier P, Dartigues JF, Deloukas P, Deuschl G, Dexter DT, van Dijk KD, Dillman A, Durif F, Dürr A, Edkins S, Evans JR, Foltynie T, Gao J, Gardner M, Gibbs JR, Goate A, Gray E, Guerreiro R, Harris C, van Hilten JJ, Hofman A, Hollenbeck A, Holton J, Hu M, Huang X, Huber H, Hudson G, Hunt SE, Illig T, Lambert JC, Langford C, Lees A, Lichtner P, Limousin P, Lopez G, Lorenz D, McNeill A, Moorby C, Moore M, Morris HR, Morrison KE, Mudanohwo E, O'Sullivan SS, Pearson J, Perlmutter JS, Pollak P, Post B, Potter S, Ravina B, Revesz T, Riess O, Rivadeneira F, Rizzu P, Ryten M, Sawcer S, Schapira A, Scheffer H, Shaw K, Shoulson I, Sidransky E, Smith C, Spencer CC, Stockton JD, Strange A, Talbot K, Tanner CM, Tashakkori Ghanbaria A, Trabzuni D, Traynor BJ, Uitterlinden AG, Velseboer D, Vidailhet M, Walker R, van de Warrenburg B, Wickremaratchi M, Williams N, Williams Gray CH, Winder Rhodes S, Martinez M, Hardy J, Heutink P, Brice A, Gasser T, Singleton AB, Wood NW, Donnelly P, Barroso I, Blackwell JM, Bramon E, Brown MA, Casas JP, Corvin A, Duncanson A, Jankowski J, Markus HS, Mathew CG, Palmer CN, Plomin R, Rautanen A, Sawcer SJ, Trembath RC, Viswanathan AC, Band G, Bellenguez C, Freeman C, Hellenthal G, Giannoulatou E, Pirinen M, Pearson R, Su Z, Vukcevic D, Gwilliam R, Blackburn H, Bumpstead SJ, Dronov S, Gillman M, Hammond N, Jayakumar A, McCann OT, Liddle J, Potter SC, Ravindrarajah R, Ricketts M, Waller M, Weston P, Widaa S, Whittaker P, McCarthy MI, Ouwehand WH, Radhakrishnan A, Sambrook J, Toniolo D, Camaschella C, Metspalu A, Esko T, Gieger C, Ried J, Meitinger T, Oexle K, Winkelmann J, Swinkels D, Vermeulen S, van Duijn C, Broer L, Beilby J, Hui J, Anderson D, Visscher P, Martin N., TRAGLIA, MICHELA, Pichler, Irene, Del Greco M, Fabiola, Gögele, Martin, Lill, Christina M, Benyamin, Beben, Minelli, Cosetta, PD GWAS Consortium, International Parkinson’s Disease Genomics Consortium, Wellcome Trust Case Control Consortium, Genetics of Iron Status Consortium, Pollak, Pierre, Functional Genomics, Neuroscience Campus Amsterdam - Brain Mechanisms in Health & Disease, Human genetics, NCA - Brain mechanisms in health and disease, ANS - Amsterdam Neuroscience, Neurology, Graduate School, Pichler, I, Del Greco M., F, Gögele, M, Lill, Cm, Bertram, L, Do, Cb, Eriksson, N, Foroud, T, Myers, Rh, PD GWAS, Consortium, Nalls, M, Keller, Mf, International Parkinson's Disease Genomics, Consortium, Wellcome Trust Case Control Consortium, 2, Benyamin, B, Whitfield, Jb, Genetics of Iron Status, Consortium, Pramstaller, Pp, Hicks, Aa, Thompson, Jr, Minelli, C., Plagnol, V, Hernandez, Dg, Sharma, M, Sheerin, Um, Saad, M, Simón Sánchez, J, Schulte, C, Lesage, S, Arepalli, S, Barker, R, Ben Shlomo, Y, Berendse, Hw, Berg, D, Bhatia, K, de Bie, Rm, Biffi, A, Bloem, B, Bochdanovits, Z, Bonin, M, Bras, Jm, Brockmann, K, Brooks, J, Burn, Dj, Charlesworth, G, Chen, H, Chinnery, Pf, Chong, S, Clarke, Ce, Cookson, Mr, Cooper, Jm, Corvol, Jc, Counsell, C, Damier, P, Dartigues, Jf, Deloukas, P, Deuschl, G, Dexter, Dt, van Dijk, Kd, Dillman, A, Durif, F, Dürr, A, Edkins, S, Evans, Jr, Foltynie, T, Gao, J, Gardner, M, Gibbs, Jr, Goate, A, Gray, E, Guerreiro, R, Harris, C, van Hilten, Jj, Hofman, A, Hollenbeck, A, Holton, J, Hu, M, Huang, X, Huber, H, Hudson, G, Hunt, Se, Illig, T, Lambert, Jc, Langford, C, Lees, A, Lichtner, P, Limousin, P, Lopez, G, Lorenz, D, Mcneill, A, Moorby, C, Moore, M, Morris, Hr, Morrison, Ke, Mudanohwo, E, O'Sullivan, S, Pearson, J, Perlmutter, J, Pollak, P, Post, B, Potter, S, Ravina, B, Revesz, T, Riess, O, Rivadeneira, F, Rizzu, P, Ryten, M, Sawcer, S, Schapira, A, Scheffer, H, Shaw, K, Shoulson, I, Sidransky, E, Smith, C, Spencer, Cc, Stockton, Jd, Strange, A, Talbot, K, Tanner, Cm, Tashakkori Ghanbaria, A, Trabzuni, D, Traynor, Bj, Uitterlinden, Ag, Velseboer, D, Vidailhet, M, Walker, R, van de Warrenburg, B, Wickremaratchi, M, Williams, N, Williams Gray, Ch, Winder Rhodes, S, Martinez, M, Hardy, J, Heutink, P, Brice, A, Gasser, T, Singleton, Ab, Wood, Nw, Donnelly, P, Barroso, I, Blackwell, Jm, Bramon, E, Brown, Ma, Casas, Jp, Corvin, A, Duncanson, A, Jankowski, J, Markus, H, Mathew, Cg, Palmer, Cn, Plomin, R, Rautanen, A, Sawcer, Sj, Trembath, Rc, Viswanathan, Ac, Band, G, Bellenguez, C, Freeman, C, Hellenthal, G, Giannoulatou, E, Pirinen, M, Pearson, R, Su, Z, Vukcevic, D, Gwilliam, R, Blackburn, H, Bumpstead, Sj, Dronov, S, Gillman, M, Hammond, N, Jayakumar, A, Mccann, Ot, Liddle, J, Potter, Sc, Ravindrarajah, R, Ricketts, M, Waller, M, Weston, P, Widaa, S, Whittaker, P, Mccarthy, Mi, Ouwehand, Wh, Radhakrishnan, A, Sambrook, J, Toniolo, D, Traglia, Michela, Camaschella, C, Metspalu, A, Esko, T, Gieger, C, Ried, J, Meitinger, T, Oexle, K, Winkelmann, J, Swinkels, D, Vermeulen, S, van Duijn, C, Broer, L, Beilby, J, Hui, J, Anderson, D, Visscher, P, and Martin, N.

Subjects
Relative risk reduction, Iron, Mendelian randomization analysis, Physiology, Genome-wide association study, Biology, Bioinformatics, 03 medical and health sciences, 0302 clinical medicine, SDG 17 - Partnerships for the Goals, Risk Factors, Mendelian randomization, medicine, Humans, Genetic Predisposition to Disease, Iron/blood, Genetic Association Studies, 030304 developmental biology, 0303 health sciences, medicine.diagnostic_test, Parkinson Disease/blood/genetics, Confounding, Parkinson Disease, Mendelian Randomization Analysis, General Medicine, Iron metabolism, 3. Good health, ddc:616.8, Parkinson disease, Meta-analysis, Hereditary hemochromatosis, Serum iron, Medicine, 030217 neurology & neurosurgery, Research Article
Abstract

In this study, Mendelian randomization was used to study genes known to modify iron levels, and the effect of iron on Parkinson's disease (PD) risk was estimated. Based on estimates of the genetic effects on both iron and PD obtained from the largest sample meta-analyzed to date, the findings suggest that increased iron levels in the blood are associated with a 3% reduction in the risk of Parkinson's disease for every 10 µg/dL increase in iron. The results of this analysis have potentially important implications for future research into the prevention of Parkinson's disease. Please see later in the article for the Editors' Summary, Background Although levels of iron are known to be increased in the brains of patients with Parkinson disease (PD), epidemiological evidence on a possible effect of iron blood levels on PD risk is inconclusive, with effects reported in opposite directions. Epidemiological studies suffer from problems of confounding and reverse causation, and mendelian randomization (MR) represents an alternative approach to provide unconfounded estimates of the effects of biomarkers on disease. We performed a MR study where genes known to modify iron levels were used as instruments to estimate the effect of iron on PD risk, based on estimates of the genetic effects on both iron and PD obtained from the largest sample meta-analyzed to date. Methods and Findings We used as instrumental variables three genetic variants influencing iron levels, HFE rs1800562, HFE rs1799945, and TMPRSS6 rs855791. Estimates of their effect on serum iron were based on a recent genome-wide meta-analysis of 21,567 individuals, while estimates of their effect on PD risk were obtained through meta-analysis of genome-wide and candidate gene studies with 20,809 PD cases and 88,892 controls. Separate MR estimates of the effect of iron on PD were obtained for each variant and pooled by meta-analysis. We investigated heterogeneity across the three estimates as an indication of possible pleiotropy and found no evidence of it. The combined MR estimate showed a statistically significant protective effect of iron, with a relative risk reduction for PD of 3% (95% CI 1%–6%; p = 0.001) per 10 µg/dl increase in serum iron. Conclusions Our study suggests that increased iron levels are causally associated with a decreased risk of developing PD. Further studies are needed to understand the pathophysiological mechanism of action of serum iron on PD risk before recommendations can be made. Please see later in the article for the Editors' Summary, Editors' Summary Background Parkinson disease is a degenerative disorder of the central nervous system caused by the death of dopamine-generating cells in the substania nigra, a region of the midbrain. The earliest symptoms are usually movement-related and include tremor, slow movements, and difficulty walking, and later cognitive and behavioral problems may arise, with dementia commonly occurring in the advanced stages of the disease. Parkinson disease affects around ten million people world-wide and incidence increases with age, with men more affected than women. To date, the causes of Parkinson disease remain unknown although a combination of genetic and environmental factors is thought to play a role. Identifying possible modifiable risks is an important step in the possible prevention of Parkinson disease. Why Was This Study Done? Previous studies have shown a possible association between lower blood levels of iron in people with Parkinson disease compared with controls, although the quality of these studies makes this finding difficult to interpret. So in this study, the researchers used a mendelian randomization approach to investigate whether there was any evidence of an effect of blood iron levels on the risk of Parkinson disease and if so to further explore the direction and scale of any link. Mendelian randomization is a method of using measured variation in genes of known function to examine the causal effect of a modifiable exposure on disease in situations where it is inappropriate to perform a randomized controlled trial. What Did the Researchers Do and Find? The researchers estimated the effect of blood iron levels on the risk of Parkinson disease using three polymorphisms in two genes, HFE and TMPRSS6. For each polymorphism, they performed a meta-analysis combining the results of studies investigating the genetic effect on iron levels, which included almost 22,000 people from Europe and Australia, and a meta-analysis of studies investigating the genetic effect on the risk of Parkinson disease, which included a total of 20,809 people with Parkinson disease and 88,892 controls from Europe and North America. They then performed three separate mendelian randomization analyses to estimate the effect of iron on Parkinson disease for the three polymorphisms. By combining the three estimates, they obtained a statistically significant odds ratio of 0.97 for Parkinson disease per 10 µg/dl increase in iron, corresponding to a 3% reduction in the risk of Parkinson disease for every 10 µg/dl increase in blood iron. Since genotype influences on blood iron levels represent differences that generally persist throughout adult life, the combined mendelian randomization estimate reflects an effect of iron over the course of a lifetime. What Do These Findings Mean? These findings suggest that increased iron levels in the blood are associated with a 3% reduction in the risk of Parkinson disease for every 10 µg/dl increase in iron. This finding is important as it suggests that increased blood iron levels may have a protective effect against Parkinson disease, although the underlying mechanism remains unclear. Furthermore, although mendelian randomization is an increasingly used approach to address the issue of classical confounding, there may be remaining confounding factors specific of mendelian randomization that may influence the interpretation of this study. Nevertheless, the results of this analysis have potentially important implications for future research into the prevention of Parkinson disease. Further studies on the underlying mechanisms are needed before any specific treatment recommendations can be proposed. Additional Information Please access these Web sites via the online version of this summary at http://dx.doi.org/10.1371/journal.pmed.1001462. The National Institutes of Neurological Disorder and Stroke, MedlinePlus, and NHS Choices have several pages with comprehensive information on Parkinson disease Wikipedia gives an explanation of mendelian randomization (note that Wikipedia is a free online encyclopedia that anyone can edit; available in several languages)

Published
2013
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29. Mutations in HPCA cause autosomal-recessive primary isolated dystonia

Author

Charlesworth, G. Angelova, P.R. Bartolomé-Robledo, F. Ryten, M. Trabzuni, D. Stamelou, M. Abramov, A.Y. Bhatia, K.P. Wood, N.W.

Subjects
otorhinolaryngologic diseases
Abstract

Reports of primary isolated dystonia inherited in an autosomal-recessive (AR) manner, often lumped together as "DYT2 dystonia," have appeared in the scientific literature for several decades, but no genetic cause has been identified to date. Using a combination of homozygosity mapping and whole-exome sequencing in a consanguineous kindred affected by AR isolated dystonia, we identified homozygous mutations in HPCA, a gene encoding a neuronal calcium sensor protein found almost exclusively in the brain and at particularly high levels in the striatum, as the cause of disease in this family. Subsequently, compound-heterozygous mutations in HPCA were also identified in a second independent kindred affected by AR isolated dystonia. Functional studies suggest that hippocalcin might play a role in regulating voltage-dependent calcium channels. The identification of mutations in HPCA as a cause of AR primary isolated dystonia paves the way for further studies to assess whether "DYT2 dystonia" is a genetically homogeneous condition or not. © 2015 The American Society of Human Genetics.

Published
2015

30. Mitochondrial complex I NUBPL mutations cause combined dystonia with bilateral striatal necrosis and cerebellar atrophy.

Author

Balint, B., Charlesworth, G., Stamelou, M., Carr, L., Mencacci, N. E., Wood, N. W., and Bhatia, K. P.

Subjects
*RECESSIVE genes, *CEREBELLUM degeneration, *SPINOCEREBELLAR ataxia, *ATROPHY, *CEREBELLAR ataxia, *MAGNETIC resonance imaging, *NECROSIS, *GENETIC disorders
Abstract

Background and purpose: The recent advances in genetics have helped to unravel the cause of many dystonia syndromes. With the broadening spectrum of genetically defined dystonia syndromes, distinct clinico‐radiological phenotypes are a welcome handle to guide the diagnostic work‐up. Methods: Exome sequencing was used to elucidate the genetic cause of a syndrome characterized by generalized dystonia, pyramidal and cerebellar involvement, with bilateral striatal necrosis (BSN) and cerebellar atrophy on magnetic resonance imaging. Homozygosity mapping and linkage analysis were used in a supportive role. Known genetic causes of BSN were excluded by use of exome data or Sanger sequencing. Results: Compound heterozygous mutations were identified in the NUBPL gene in a small UK kindred. The gene lay in a region of positive linkage and segregated with disease in a family of six individuals. Conclusion: NUBPL mutations cause early onset, autosomal recessive generalized dystonia with cerebellar ataxia, pyramidal signs, preserved cognition and a distinct magnetic resonance imaging appearance with BSN and cerebellar atrophy. [ABSTRACT FROM AUTHOR]

Published
2019
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31. NeuroChip, an updated version of the NeuroX genotyping platform to rapidly screen for variants associated with neurological diseases

Author

Blauwendraat, C., Faghri, F., Pihlstrom, L., Geiger, J. T., Elbaz, A., Lesage, S., Corvol, J. -C., May, P., Nicolas, A., Abramzon, Y., Murphy, N. A., Gibbs, J. R., Ryten, M., Ferrari, R., Bras, J., Guerreiro, R., Williams, J., Sims, R., Lubbe, S., Hernandez, D. G., Mok, K. Y., Robak, L., Campbell, R. H., Rogaeva, E., Traynor, B. J., Chia, R., Chung, S. J., Hardy, J. A., Brice, A., Wood, N. W., Houlden, H., Shulman, J. M., Morris, H. R., Gasser, T., Kruger, R., Heutink, P., Sharma, M., Simon-Sanchez, J., Nalls, M. A., Singleton, A. B., Scholz, S. W., Noyce, A. J., Giri, A., Oehmig, A., Tucci, A., Schulte, C., Cookson, M. R., Kia, D., Danjou, F., Charlesworth, G., Plun-Favreau, H., Holmans, P., Jansen, I., Hardy, J., Bras, J. M., Quinn, J., Botia, J. A., Billingsley, K., R'Bibo, L., Lungu, C., Martinez, M., Escott-Price, V., Mencacci, N. E., Topley, Lewis, Denny, P., Rizzu, P., Taba, P., Lovering, R., Ogalla, R. D., Foulger, R., Finkbeiner, S., Sveinbjornsdottir, S., Scholz, S., Koks, S., Foltynie, T., Price, T. R., Sheerin, U. -M., Williams, N., Reed, X., Wang, L., Brockmann, K., Oertel, W., Klein, C., Mohamed, F., Malard, L., Corti, O., Drouet, V., Goldwurm, S., Tesei, S., Canesi, M., Valente, E. M., Petrucci, S., Ginevrino, M., Toft, M., Aasly, J., Henriksen, S. P., Saetehaug, C., Orr-Urtreger, A., Giladi, N., Ferreira, J., Guedes, L. C., Bouca-Machado, R., Coelho, M., Rosa, M. M., Tolosa, E., Fernandez-Santiago, R., Ezquerra, M., Marti, M. J., Glaab, E., Balling, R., and Chung, S. -J.

Subjects
0301 basic medicine, Aging, methods [Genome-Wide Association Study], 0302 clinical medicine, Corticobasal degeneration, neurodegenerative diseases, humans, risk, high-throughput screening assays, education.field_of_study, General Neuroscience, neurodegeneration, genetics [Genetic Variation], 3. Good health, Neurochip, alleles, methods [Genotyping Techniques], Frontotemporal dementia, Risk, Population, methods [High-Throughput Screening Assays], Computational biology, Genetic screening, genotyping, NeuroChip, NeuroX, apolipoproteins E, genetic variation, genome-wide association study, genotyping techniques, Article, Progressive supranuclear palsy, 03 medical and health sciences, Apolipoproteins E, medicine, Humans, Dementia, ddc:610, education, Genotyping, Alleles, business.industry, medicine.disease, 030104 developmental biology, genetics [Neurodegenerative Diseases], genetics [Apolipoproteins E], Neurology (clinical), Geriatrics and Gerontology, business, Neuroscience, 030217 neurology & neurosurgery, Imputation (genetics), Developmental Biology
Abstract

Genetics has proven to be a powerful approach in neurodegenerative diseases research, resulting in the identification of numerous causal and risk variants. Previously, we introduced the NeuroX Illumina genotyping array, a fast and efficient genotyping platform designed for the investigation of genetic variation in neurodegenerative diseases. Here, we present its updated version, named NeuroChip. The NeuroChip is a low-cost, custom-designed array containing a tagging variant backbone of about 306,670 variants complemented with a manually curated custom content comprised of 179,467 variants implicated in diverse neurological diseases, including Alzheimer's disease, Parkinson's disease, Lewy body dementia, amyotrophic lateral sclerosis, frontotemporal dementia, progressive supranuclear palsy, corticobasal degeneration, and multiple system atrophy. The tagging backbone was chosen because of the low cost and good genome-wide resolution; the custom content can be combined with other backbones, like population or drug development arrays. Using the NeuroChip, we can accurately identify rare variants and impute over 5.3 million common SNPs from the latest release of the Haplotype Reference Consortium. In summary, we describe the design and usage of the NeuroChip array and show its capability for detecting rare pathogenic variants in numerous neurodegenerative diseases. The NeuroChip has a more comprehensive and improved content, which makes it a reliable, high-throughput, cost-effective screening tool for genetic research and molecular diagnostics in neurodegenerative diseases.

Published
2017
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32. Large-scale meta-analysis of genome-wide association data identifies six new risk loci for Parkinson's disease

Author

Nalls, M.A. Pankratz, N. Lill, C.M. Do, C.B. Hernandez, D.G. Saad, M. Destefano, A.L. Kara, E. Bras, J. Sharma, M. Schulte, C. Keller, M.F. Arepalli, S. Letson, C. Edsall, C. Stefansson, H. Liu, X. Pliner, H. Lee, J.H. Cheng, R. Ikram, M.A. Ioannidis, J.P.A. Hadjigeorgiou, G.M. Bis, J.C. Martinez, M. Perlmutter, J.S. Goate, A. Marder, K. Fiske, B. Sutherland, M. Xiromerisiou, G. Myers, R.H. Clark, L.N. Stefansson, K. Hardy, J.A. Heutink, P. Chen, H. Wood, N.W. Houlden, H. Payami, H. Brice, A. Scott, W.K. Gasser, T. Bertram, L. Eriksson, N. Foroud, T. Singleton, A.B. Plagnol, V. Sheerin, U.-M. Simón-Sánchez, J. Lesage, S. Sveinbjörnsdóttir, S. Barker, R. Ben-Shlomo, Y. Berendse, H.W. Berg, D. Bhatia, K. de Bie, R.M.A. Biffi, A. Bloem, B. Bochdanovits, Z. Bonin, M. Bras, J.M. Brockmann, K. Brooks, J. Burn, D.J. Charlesworth, G. Chinnery, P.F. Chong, S. Clarke, C.E. Cookson, M.R. Cooper, J.M. Corvol, J.C. Counsell, C. Damier, P. Dartigues, J.-F. Deloukas, P. Deuschl, G. Dexter, D.T. van Dijk, K.D. Dillman, A. Durif, F. Dürr, A. Edkins, S. Evans, J.R. Foltynie, T. Dong, J. Gardner, M. Gibbs, J.R. Gray, E. Guerreiro, R. Harris, C. van Hilten, J.J. Hofman, A. Hollenbeck, A. Holton, J. Hu, M. Huang, X. Wurster, I. Mätzler, W. Hudson, G. Hunt, S.E. Huttenlocher, J. Illig, T. Jónsson, P.V. Lambert, J.-C. Langford, C. Lees, A. Lichtner, P. Limousin, P. Lopez, G. Lorenz, D. McNeill, A. Moorby, C. Moore, M. Morris, H.R. Morrison, K.E. Mudanohwo, E. O’sullivan, S.S. Pearson, J. Pétursson, H. Pollak, P. Post, B. Potter, S. Ravina, B. Revesz, T. Riess, O. Rivadeneira, F. Rizzu, P. Ryten, M. Sawcer, S. Schapira, A. Scheffer, H. Shaw, K. Shoulson, I. Sidransky, E. Smith, C. Spencer, C.C.A. Stefánsson, H. Bettella, F. Stockton, J.D. Strange, A. Talbot, K. Tanner, C.M. Tashakkori-Ghanbaria, A. Tison, F. Trabzuni, D. Traynor, B.J. Uitterlinden, A.G. Velseboer, D. Vidailhet, M. Walker, R. van de Warrenburg, B. Wickremaratchi, M. Williams, N. Williams-Gray, C.H. Winder-Rhodes, S. Stefánsson, K. Hardy, J. Factor, S. Higgins, D. Evans, S. Shill, H. Stacy, M. Danielson, J. Marlor, L. Williamson, K. Jankovic, J. Hunter, C. Simon, D. Ryan, P. Scollins, L. Saunders-Pullman, R. Boyar, K. Costan-Toth, C. Ohmann, E. Sudarsky, L. Joubert, C. Friedman, J. Chou, K. Fernandez, H. Lannon, M. Galvez-Jimenez, N. Podichetty, A. Thompson, K. Lewitt, P. Deangelis, M. O'brien, C. Seeberger, L. Dingmann, C. Judd, D. Marder, K. Fraser, J. Harris, J. Bertoni, J. Peterson, C. Rezak, M. Medalle, G. Chouinard, S. Panisset, M. Hall, J. Poiffaut, H. Calabrese, V. Roberge, P. Wojcieszek, J. Belden, J. Jennings, D. Marek, K. Mendick, S. Reich, S. Dunlop, B. Jog, M. Horn, C. Uitti, R. Turk, M. Ajax, T. Mannetter, J. Sethi, K. Carpenter, J. Dill, B. Hatch, L. Ligon, K. Narayan, S. Blindauer, K. Abou-Samra, K. Petit, J. Elmer, L. Aiken, E. Davis, K. Schell, C. Wilson, S. Velickovic, M. Koller, W. Phipps, S. Feigin, A. Gordon, M. Hamann, J. Licari, E. Marotta-Kollarus, M. Shannon, B. Winnick, R. Simuni, T. Videnovic, A. Kaczmarek, A. Williams, K. Wolff, M. Rao, J. Cook, M. Fernandez, M. Kostyk, S. Hubble, J. Campbell, A. Reider, C. Seward, A. Camicioli, R. Carter, J. Nutt, J. Andrews, P. Morehouse, S. Stone, C. Mendis, T. Grimes, D. Alcorn-Costa, C. Gray, P. Haas, K. Vendette, J. Sutton, J. Hutchinson, B. Young, J. Rajput, A. Klassen, L. Shirley, T. Manyam, B. Simpson, P. Whetteckey, J. Wulbrecht, B. Truong, D. Pathak, M. Frei, K. Luong, N. Tra, T. Tran, A. Vo, J. Lang, A. Kleiner-Fisman, G. Nieves, A. Johnston, L. So, J. Podskalny, G. Giffin, L. Atchison, P. Allen, C. Martin, W. Wieler, M. Suchowersky, O. Furtado, S. Klimek, M. Hermanowicz, N. Niswonger, S. Shults, C. Fontaine, D. Aminoff, M. Christine, C. Diminno, M. Hevezi, J. Dalvi, A. Kang, U. Richman, J. Uy, S. Sahay, A. Gartner, M. Schwieterman, D. Hall, D. Leehey, M. Culver, S. Derian, T. Demarcaida, T. Thurlow, S. Rodnitzky, R. Dobson, J. Lyons, K. Pahwa, R. Gales, T. Thomas, S. Shulman, L. Weiner, W. Dustin, K. Singer, C. Zelaya, L. Tuite, P. Hagen, V. Rolandelli, S. Schacherer, R. Kosowicz, J. Gordon, P. Werner, J. Serrano, C. Roque, S. Kurlan, R. Berry, D. Gardiner, I. Hauser, R. Sanchez-Ramos, J. Zesiewicz, T. Delgado, H. Price, K. Rodriguez, P. Wolfrath, S. Pfeiffer, R. Davis, L. Pfeiffer, B. Dewey, R. Hayward, B. Johnson, A. Meacham, M. Estes, B. Walker, F. Hunt, V. O'neill, C. Racette, B. Swisher, L. Dijamco, C. Conley, E.D. Dorfman, E. Tung, J.Y. Hinds, D.A. Mountain, J.L. Wojcicki, A. Lew, M. Klein, C. Golbe, L. Growdon, J. Wooten, G.F. Watts, R. Guttman, M. Goldwurm, S. Saint-Hilaire, M.H. Baker, K. Litvan, I. Nicholson, G. Nance, M. Drasby, E. Isaacson, S. Burn, D. Pramstaller, P. Al-Hinti, J. Moller, A. Sherman, S. Roxburgh, R. Slevin, J. Perlmutter, J. Mark, M.H. Huggins, N. Pezzoli, G. Massood, T. Itin, I. Corbett, A. Chinnery, P. Ostergaard, K. Snow, B. Cambi, F. Kay, D. Samii, A. Agarwal, P. Roberts, J.W. Higgins, D.S. Molho, E. Rosen, A. Montimurro, J. Martinez, E. Griffith, A. Kusel, V. Yearout, D. Factor, S. Zabetian, C. Clark, L.N. Liu, X. Lee, J.H. Cheng Taub, R. Louis, E.D. Cote, L.J. Waters, C. Ford, B. Fahn, S. Vance, J.M. Beecham, G.W. Martin, E.R. Nuytemans, K. Pericak-Vance, M.A. Haines, J.L. Destefano, A. Seshadri, S. Choi, S.H. Frank, S. Bis, J.C. Psaty, B.M. Rice, K. Longstreth, W.T., Jr. Ton, T.G.N. Jain, S. van Duijn, C.M. Uitterlinden, A.G. Verlinden, V.J. Koudstaal, P.J. Singleton, A. Cookson, M. Gibbs, J.R. Hernandez, D. Nalls, M. Zonderman, A. Ferrucci, L. Johnson, R. Longo, D. O'brien, R. Traynor, B. Troncoso, J. van der Brug, M. Zielke, R. Weale, M. Ramasamy, A. Dardiotis, E. Tsimourtou, V. Spanaki, C. Plaitakis, A. Bozi, M. Stefanis, L. Vassilatis, D. Koutsis, G. Panas, M. Hadjigeorgiou, G.M. Lunnon, K. Lupton, M. Powell, J. Parkkinen, L. Ansorge, O. International Parkinson's Disease Genomics Consortium (IPDGC) Parkinson's Study Group (PSG) Parkinson's Research: The Organized GENetics Initiative (PROGENI) 23andMe GenePD NeuroGenetics Research Consortium (NGRC) Hussman Institute of Human Genomics (HIHG) The Ashkenazi Jewish Dataset Investigator Cohorts for Health Aging Research in Genetic Epidemiology (CHARGE) North American Brain Expression Consortium (NABEC) United Kingdom Brain Expression Consortium (UKBEC) Greek Parkinson's Disease Consortium Alzheimer Genetic Analysis Group

Abstract

We conducted a meta-analysis of Parkinson's disease genome-wide association studies using a common set of 7,893,274 variants across 13,708 cases and 95,282 controls. Twenty-six loci were identified as having genome-wide significant association; these and 6 additional previously reported loci were then tested in an independent set of 5,353 cases and 5,551 controls. Of the 32 tested SNPs, 24 replicated, including 6 newly identified loci. Conditional analyses within loci showed that four loci, including GBA, GAK-DGKQ, SNCA and the HLA region, contain a secondary independent risk variant. In total, we identified and replicated 28 independent risk variants for Parkinson's disease across 24 loci. Although the effect of each individual locus was small, risk profile analysis showed substantial cumulative risk in a comparison of the highest and lowest quintiles of genetic risk (odds ratio (OR) = 3.31, 95% confidence interval (CI) = 2.55-4.30; P = 2 × 10-16). We also show six risk loci associated with proximal gene expression or DNA methylation. © 2014 Nature America, Inc. All rights reserved.

Published
2014

33. Ataxia telangiectasia presenting as dopa-responsive cervical dystonia

Author

Charlesworth, G. Mohire, M.D. Schneider, S.A. Stamelou, M. Wood, N.W. Bhatia, K.P.

Abstract

Objective: To identify the cause of cervical dopa-responsive dystonia (DRD) in a Muslim Indian family inherited in an apparently autosomal recessive fashion, as previously described in this journal. Methods: Previous testing for mutations in the genes known to cause DRD (GCH1, TH, and SPR) had been negative. Whole exome sequencing was performed on all 3 affected individuals for whom DNA was available to identify potentially pathogenic shared variants. Genotyping data obtained for all 3 affected individuals using the OmniExpress single nucleotide polymorphism chip (Illumina, San Diego, CA) were used to perform linkage analysis, autozygosity mapping, and copy number variation analysis. Sanger sequencing was used to confirm all variants. Results: After filtering of the variants, exome sequencing revealed 2 genes harboring potentially pathogenic compound heterozygous variants (ATM and LRRC16A). Of these, the variants in ATM segregated perfectly with the cervical DRD. Both mutations detected in ATM have been shown to be pathogenic, and a-fetoprotein, a marker of ataxia telangiectasia, was increased in all affected individuals. Conclusion: Biallelic mutations in ATM can cause DRD, and mutations in this gene should be considered in the differential diagnosis of unexplained DRD, particularly if the dystonia is cervical and if there is a recessive family history. ATM has previously been reported to cause isolated cervical dystonia, but never, to our knowledge, DRD. Individuals with dystonia related to ataxia telangiectasia may benefit from a trial of levodopa. © 2013 American Academy of Neurology.

Published
2013

34. A two-stage meta-analysis identifies several new loci for Parkinson's disease

Author

Plagnol, V., Nalls, M.A., Bras, J.M., Hernandez, D., Sharma, M., Sheerin, U.M., Saad, M., Simon-Sanchez, J., Schulte, C., Lesage, S., Sveinbjornsdottir, S., Amouyel, P., Arepalli, S., Band, G., Barker, R.A., Bellinguez, C., Ben-Shlomo, Y., Berendse, H.W., Berg, D., Bhatia, K.P., Bie, R.M. de, Biffi, A., Bloem, B.R., Bochdanovits, Z., Bonin, M., Brockmann, K., Brooks, J., Burn, D.J., Charlesworth, G., Chen, H., Chinnery, P.F., Chong, S., Clarke, C.E., Cookson, M.R., Cooper, J.M., Corvol, J.C., Counsell, J., Damier, P., Dartigues, J.F., Deloukas, P., Deuschl, G., Dexter, D.T., Dijk, K.D. van, Dillman, A., Durif, F., Durr, A., Edkins, S., Evans, J.R., Foltynie, T., Freeman, C., Gao, J., Gardner, M., Gibbs, J.R., Goate, A., Gray, E., Guerreiro, R., Gustafsson, O., Harris, C., Hellenthal, G., Hilten, J.J. van, Hofman, A., Hollenbeck, A., Holton, J.L., Hu, M., Huang, X., Huber, H, Hudson, G., Hunt, S.E., Huttenlocher, J., Illig, T., Jonsson, P.V., Langford, C., Lees, A.J., Lichtner, P., Limousin, P., Lopez, G., McNeill, A., Moorby, C., Moore, M., Morris, H.A., Morrison, K.E., Mudanohwo, E., O'Sullivan, S.S, Pearson, J., Pearson, R., Perlmutter, J., Petursson, H., Pirinen, M., Polnak, P., Post, B., Potter, S.C., Ravina, B., Revesz, T., Riess, O., Rivadeneira, F., Rizzu, P., Ryten, M., Sawcer, S.J., Schapira, A., Scheffer, H., Shaw, K., Shoulson, I., Sidransky, E., Silva, R. de, Smith, C., Spencer, C.C., Stefansson, H., Steinberg, S., Stockton, J.D., Strange, A., Su, Z., Talbot, K., Tanner, C.M., Tashakkori-Ghanbaria, A., Tison, F., Trabzuni, D., Traynor, B.J., Uitterlinden, A.G., Vandrovcova, J., Velseboer, D., Vidailhet, M., Vukcevic, D., Walker, R., Warrenburg, B.P.C. van de, Weale, M.E., Wickremaratchi, M., Williams, N., Williams-Gray, C.H., Winder-Rhodes, S., Stefansson, K., Martinez, M., Donnelly, P., Singleton, A.B., Hardy, J., Heutink, P., Brice, A., Gasser, T., and Wood, N.W.

Subjects
Functional Neurogenomics Human Movement & Fatigue [DCN 2], Genomic disorders and inherited multi-system disorders Functional Neurogenomics [IGMD 3], Functional Neurogenomics [DCN 2]
Abstract

Contains fulltext : 97597.pdf (Publisher’s version ) (Open Access) A previous genome-wide association (GWA) meta-analysis of 12,386 PD cases and 21,026 controls conducted by the International Parkinson's Disease Genomics Consortium (IPDGC) discovered or confirmed 11 Parkinson's disease (PD) loci. This first analysis of the two-stage IPDGC study focused on the set of loci that passed genome-wide significance in the first stage GWA scan. However, the second stage genotyping array, the ImmunoChip, included a larger set of 1,920 SNPs selected on the basis of the GWA analysis. Here, we analyzed this set of 1,920 SNPs, and we identified five additional PD risk loci (combined p

Published
2011

36. E1350

Author

Court, N. A., Fettis, H. E., and Charlesworth, G. B.

Published
1959
Full Text
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37. E1187

Author

Goode, James, Charlesworth, G. B., Danese, A. E., Stanaitis, O. E., and Wilansky, Albert

Published
1956
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40. Design and construction: temporary support for low cover driven tunnels, Clem7 tunnel, Brisbane.

Author

Charlesworth G., Hong Kong tunnelling conference 2009 20-Nov-0921-Nov-09, Ashley J., Campbell A., Gong R., Ma T.C.W., Stabler J., Charlesworth G., Hong Kong tunnelling conference 2009 20-Nov-0921-Nov-09, Ashley J., Campbell A., Gong R., Ma T.C.W., and Stabler J.

Abstract

The tunnel will be the longest road tunnel in Australia and is due for completion in October 2010. The project consists of two parallel twin-lane tunnels which extend for 6.8 km, and the design includes about 3 km of roadheader tunnels, with the rest being excavated by tunnel boring machine. The southern roadheader sections are through areas of mixed ground and low rock cover at the south portal and involve the construction of adjacent tunnel spans of 18 and 15 m for the northbound and southbound tunnels, respectively. A thin pillar of weathered rock separates the tunnel drives, and construction of the south portal tunnel openings has been carried out with less than 5 m of cover to the finished surface of the existing South East freeway. The design of the excavation and the initial support schemes for the southern roadheader tunnels are described. Significant support elements from north to south included the rock pillar between the two tunnels which was anticipated to be of good quality tuff with widely spaced joints, fore-poling in areas where the rock cover in the tunnel crown was 0-5 m, a shotcrete and lattice girder support designed to allow for the shotcrete to gain strength in step with the anticipated rate of advance and to enable the fore-poling elements to span the distance between the support and the face being excavated, installation of bored piles in the gap between the two tunnels to carry the arch loads down into competent ground, and installation of fore-poling above the tunnel crown from the portal. A comprehensive instrumentation and monitoring scheme was used to investigate support performance. Observed settlements were in line with predicted behaviour., The tunnel will be the longest road tunnel in Australia and is due for completion in October 2010. The project consists of two parallel twin-lane tunnels which extend for 6.8 km, and the design includes about 3 km of roadheader tunnels, with the rest being excavated by tunnel boring machine. The southern roadheader sections are through areas of mixed ground and low rock cover at the south portal and involve the construction of adjacent tunnel spans of 18 and 15 m for the northbound and southbound tunnels, respectively. A thin pillar of weathered rock separates the tunnel drives, and construction of the south portal tunnel openings has been carried out with less than 5 m of cover to the finished surface of the existing South East freeway. The design of the excavation and the initial support schemes for the southern roadheader tunnels are described. Significant support elements from north to south included the rock pillar between the two tunnels which was anticipated to be of good quality tuff with widely spaced joints, fore-poling in areas where the rock cover in the tunnel crown was 0-5 m, a shotcrete and lattice girder support designed to allow for the shotcrete to gain strength in step with the anticipated rate of advance and to enable the fore-poling elements to span the distance between the support and the face being excavated, installation of bored piles in the gap between the two tunnels to carry the arch loads down into competent ground, and installation of fore-poling above the tunnel crown from the portal. A comprehensive instrumentation and monitoring scheme was used to investigate support performance. Observed settlements were in line with predicted behaviour.

Published
2009

42. C9ORF72 expansions, parkinsonism, and Parkinson disease: A clinicopathologic study

Author

Cooper-Knock, J., primary, Frolov, A., additional, Highley, J. R., additional, Charlesworth, G., additional, Kirby, J., additional, Milano, A., additional, Hartley, J., additional, Ince, P. G., additional, McDermott, C. J., additional, Lashley, T., additional, Revesz, T., additional, Shaw, P. J., additional, Wood, N. W., additional, and Bandmann, O., additional

Published
2013
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