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1. 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

2. Glycine receptor antibodies in PERM and related syndromes: characteristics, clinical features and outcomes

Author

Carvajal González, A, Leite, Mi, Waters, P, Woodhall, M, Coutinho, E, Balint, B, Lang, B, Pettingill, P, Carr, A, Sheerin, Um, Press, R, Lunn, Mp, Lim, M, Maddison, P, Meinck, Hm, Vandenberghe, W, Vincent, A, Glycine receptor antibody study group, and Durelli, Luca

Subjects

Male, Myoclonus, medicine.medical_treatment, Encephalomyelitis, Epilepsies, Myoclonic, Comorbidity, Immunoglobulin G, progressive encephalomyelitis with rigidity and myoclonus, Receptors, Glycine, Neoplasms, Outcome Assessment, Health Care, Prospective Studies, Child, Glycine receptor, biology, Glutamate Decarboxylase, Limbic encephalitis, Syndrome, Middle Aged, humanities, Potassium Channels, Voltage-Gated, Child, Preschool, Female, Stiff person syndrome, Adult, Adolescent, medicine.drug_class, Stiff-Person Syndrome, Monoclonal antibody, Antibodies, Young Adult, stiff person syndrome, medicine, Animals, Humans, Aged, Autoimmune encephalitis, business.industry, Infant, Immunotherapy, Original Articles, medicine.disease, Scientific Commentaries, autoimmune encephalitis, Muscle Rigidity, Rats, HEK293 Cells, Immunology, biology.protein, Neurology (clinical), glycine receptor, business, autoantibody

Abstract

See Martinez-Martinez et al. (doi:10.1093/brain/awu153) for a scientific commentary on this article. Carvajal-González et al. describe the first prospective cohort of patients with glycine receptor antibodies. The majority have progressive encephalomyelitis with rigidity and myoclonus. The antibodies bind to extracellular determinants on glycine receptor-α1 and to glycine receptors on spinal cord and brainstem neurons. The patients make a good recovery with immunotherapies., The clinical associations of glycine receptor antibodies have not yet been described fully. We identified prospectively 52 antibody-positive patients and collated their clinical features, investigations and immunotherapy responses. Serum glycine receptor antibody endpoint titres ranged from 1:20 to 1:60 000. In 11 paired samples, serum levels were higher than (n = 10) or equal to (n = 1) cerebrospinal fluid levels; there was intrathecal synthesis of glycine receptor antibodies in each of the six pairs available for detailed study. Four patients also had high glutamic acid decarboxylase antibodies (>1000 U/ml), and one had high voltage-gated potassium channel-complex antibody (2442 pM). Seven patients with very low titres (

Published

2014

3. Creation of an Open-Access, Mutation-Defined Fibroblast Resource for Neurological Disease Research

Author

Wray, S, Self, M, NINDS Parkinson's Disease iPSC Consortium, Gusella, NINDS Huntington's Disease iPSC Consortium James F., Macdonald, Marcy E., Wheeler, Vanessa C., Ross, Christopher A., Sergey, Akimov, Jamshid, Arjomand, Thompson, Leslie M., Alvin, King, Neal, Hermanowicz, Sara, Winokur, Svendsen, Clive N., Virginia, Mattis, Onorati, Marco, Elena, Cattaneo, Allen, Nicholas D., Kemp, Paul J., Kwang Soo Kim, Steven, Finkbeiner, NINDS ALS iPSC Consortium, Lewis, Pa, Taanman, Jw, Ryan, Ns, Mahoney, Cj, Liang, Y, Devine, Mj, Sheerin, Um, Houlden, H, Morris, Hr, Healy, D, Marti Masso JF, Preza, E, Barker, S, Sutherland, M, Corriveau, Ra, D'Andrea, M, Schapira, Ah, Uitti, Rj, Guttman, M, Opala, G, Jasinska Myga, B, Puschmann, A, Nilsson, C, Espay, Aj, Slawek, J, Gutmann, L, Boeve, Bf, Boylan, K, Stoessl, Aj, Ross, Oa, Maragakis, Nj, Van Gerpen, J, Gerstenhaber, M, Gwinn, K, Dawson, Tm, Isacson, O, Marder, Ks, Clark, Ln, Przedborski, Se, Finkbeiner, S, Rothstein, Jd, Wszolek, Zk, Rossor, Mn, Hardy, J., and Borlongan, Cesar V

Subjects

Neurology, Databases, Factual, Biopsy, Cellular differentiation, lcsh:Medicine, Disease, Bioinformatics, Motor Neuron Diseases, 0302 clinical medicine, Models, Neurobiology of Disease and Regeneration, 2.1 Biological and endogenous factors, Aetiology, lcsh:Science, NINDS ALS iPSC Consortium, Induced pluripotent stem cell, Psychiatry, 0303 health sciences, Multidisciplinary, Stem Cell Research - Induced Pluripotent Stem Cell - Human, Molecular pathology, Parkinson Disease, Cell Differentiation, Medical research, Immunohistochemistry, 3. Good health, NINDS Parkinson's Disease iPSC Consortium, Autosomal Dominant, Neurological, Medicine, Medical genetics, Alzheimer's disease, Research Article, medicine.medical_specialty, General Science & Technology, Induced Pluripotent Stem Cells, Tissue Banks, Cell Line, Access to Information, Databases, 03 medical and health sciences, Genetic, Alzheimer Disease, Genetics, medicine, Humans, QH426, Biology, Factual, Cell Proliferation, 030304 developmental biology, Clinical Genetics, Stem Cell Research - Induced Pluripotent Stem Cell, Models, Genetic, business.industry, lcsh:R, Neurosciences, Fibroblasts, Stem Cell Research, medicine.disease, R1, Brain Disorders, NINDS Huntington's Disease iPSC Consortium, Geriatrics, Mutation, lcsh:Q, Dementia, Generic health relevance, Molecular Neuroscience, Nervous System Diseases, business, 2.6 Resources and infrastructure (aetiology), 030217 neurology & neurosurgery, Neuroscience

Abstract

Our understanding of the molecular mechanisms of many neurological disorders has been greatly enhanced by the discovery of mutations in genes linked to familial forms of these diseases. These have facilitated the generation of cell and animal models that can be used to understand the underlying molecular pathology. Recently, there has been a surge of interest in the use of patient-derived cells, due to the development of induced pluripotent stem cells and their subsequent differentiation into neurons and glia. Access to patient cell lines carrying the relevant mutations is a limiting factor for many centres wishing to pursue this research. We have therefore generated an open-access collection of fibroblast lines from patients carrying mutations linked to neurological disease. These cell lines have been deposited in the National Institute for Neurological Disorders and Stroke (NINDS) Repository at the Coriell Institute for Medical Research and can be requested by any research group for use in in vitro disease modelling. There are currently 71 mutation-defined cell lines available for request from a wide range of neurological disorders and this collection will be continually expanded. This represents a significant resource that will advance the use of patient cells as disease models by the scientific community.

Published

2012