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2. Genetic evidence of heterogeneity in intrahepatic cholestasis of pregnancy. (Liver)

Author

Savander, M., Ropponen, A., Avela, K., Weerasekera, N., Cormand, B., Hirvioja, M.L., Riikonen, S., Ylikorkala, O., Lehesjoki, A.E., Williamson, C., and Aittomaki, K.

Subjects
Genetic disorders -- Research -- Genetic aspects, Cholestasis -- Genetic aspects -- Research, Jaundice, Obstructive -- Genetic aspects -- Research, Pregnant women -- Diseases -- Research, Health, Diseases, Genetic aspects, Research
Abstract

Background and aims: The aim of this study was to investigate the genetic aetiology of intrahepatic cholestasis of pregnancy (ICP) and the impact of known cholestasis genes (BSEP, FIC1, and [...]

Published
2003

3. Rare gene deletions in genetic generalized and Rolandic epilepsies

Author

Jabbari, K. (Kamel), Bobbili, D.R. (Dheeraj R.), Lal, D. (Dennis), Reinthaler, E.M. (Eva M.), Schubert, J. (Julian), Wolking, S. (Stefan), Sinha, V. (Vishal), Motameny, S. (Susanne), Thiele, H. (Holger), Kawalia, A. (Amit), Altmüller, J. (Janine), Toliat, M.R. (Mohammad Reza), Kraaij, R. (Robert), van Rooij, J. (Jeroen), Uitterlinden, A.G. (André G.), Ikram, M.A. (Arfan), Zara, F. (Federico), Lehesjoki, A.E., Krause, R. (Roland), Zimprich, F. (Fritz), Sander, T. (Thomas), Neubauer, B.A. (Bernd A.), May, P. (Patrick), Lerche, H. (Holger), Nürnberg, P. (Peter), Jabbari, K. (Kamel), Bobbili, D.R. (Dheeraj R.), Lal, D. (Dennis), Reinthaler, E.M. (Eva M.), Schubert, J. (Julian), Wolking, S. (Stefan), Sinha, V. (Vishal), Motameny, S. (Susanne), Thiele, H. (Holger), Kawalia, A. (Amit), Altmüller, J. (Janine), Toliat, M.R. (Mohammad Reza), Kraaij, R. (Robert), van Rooij, J. (Jeroen), Uitterlinden, A.G. (André G.), Ikram, M.A. (Arfan), Zara, F. (Federico), Lehesjoki, A.E., Krause, R. (Roland), Zimprich, F. (Fritz), Sander, T. (Thomas), Neubauer, B.A. (Bernd A.), May, P. (Patrick), Lerche, H. (Holger), and Nürnberg, P. (Peter)

Abstract

Genetic Generalized Epilepsy (GGE) and benign epilepsy with centro-temporal spikes or Rolandic Epilepsy (RE) are common forms of genetic epilepsies. Rare copy number variants have been recognized as important risk factors in brain disorders. We performed a systematic survey of rare deletions affecting protein-coding genes derived from exome data of patients with common forms of genetic epilepsies. We analysed exomes from 390 European patients (196 GGE and 194 RE) and 572 population controls to identify low-frequency genic deletions. We found that 75 (32 GGE and 43 RE) patients out of 390, i.e. ~19%, carried rare genic deletions. In particular, large deletions (<400 kb) represent a higher burden in both GGE and RE syndromes as compared to controls. The detected low-frequency deletions (1) share genes with brain-expressed exons that are under negative select

Published
2018
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4. Exon-disrupting deletions ofNRXN1in idiopathic generalized epilepsy

Author

Møller, R.S., Weber, Y.G., Klitten, L.L., Trucks, H., Muhle, H., Kunz, W.S., Mefford, H.C., Franke, A., Kautza, M., Wolf, P., Dennig, D., Schreiber, S., Rückert, I.M., Wichmann, H.E., Ernst, J.P., Schurmann, C., Grabe, H.J., Tommerup, N., Stephani, U., Lerche, H., Hjalgrim, H., Helbig, I., Sander, T., Zimprich, F., Mörzinger, M., Feucht, M., Suls, A., Weckhuysen, S., Claes, L., Deprez, L., Smets, K., Van Dyck, T., Deconinck, T., De Jonghe, P., Velizarova, R., Dimova, P., Radionova, M., Tournev, I., Kancheva, D., Kaneva, R., Jordanova, A., Kjelgaard, D.B., Lehesjoki, A.E., Siren, A., Baulac, S., Leguern, E., Von Spiczak, S., Ostertag, P., Leber, M., Leu, C., Toliat, M.R., Nürnberg, P., Hempelmann, A., Rüschendorf, F., Elger, C.E., Kleefuß Lie, A.A., Surges, R., Gaus, V., Janz, D., Schmitz, B., Klein, K.M., Reif, P.S., Oertel, W.H., Hamer, H.M., Rosenow, F., Becker, F., Marini, C., Guerrini, R., Mei, D., Norci, V., Zara, F., Striano, P., Robbiano, A., Pezzella, M., Bianchi, A., Gambardella, A., Tinuper, P., La Neve, A., Capovilla, G., Vigliano, P., Crichiutti, G., Vanadia, F., Vignoli, A., Coppola, A., Striano, S., Giallonardo, M.T., Franceschetti, S., Belcastro, V., Benna, P., Coppola, G., De Palo, A., Ferlazzo, E., Vecchi, M., Martinelli, V., Bisulli, F., Beccaria, F., Del Giudice, E., Mancardi, M., Stranci, G., Scabar, A., Gobbi, G., Giordano, I., Koeleman, B.P.C., De Kovel, C., Lindhout, D., De Haan, G.J., Ozbeck, U., Bebek, N., Baykan, B., Ozdemir, O., Ugur, S., Kocasoy Orhan, E., Yücesan, E., Cine, N., Gokyigit, A., Gurses, C., Gul, G., Yapici, Z., Ozkara, C., Caglayan, H., Yalcin, O., Yalcin, D., Turkdogan, D., Dizdarer, G., Agan, K., R. S. Møller, Y. G. Weber, L. L. Klitten, H. Truck, H. Muhle, W. S. Kunz, H. C. Mefford, A. Franke, M. Kautza, P. Wolf, D. Dennig, S. Schreiber, I. Rückert, H. Wichmann, J. P. Ernst, C. Schurmann, H. J. Grabe, N. Tommerup, U. Stephani, H. Lerche, H. Hjalgrim, I. Helbig, T. Sander, P. Tinuper, F. Bisulli, EPICURE Consortium, Suls, Arvid, Weckhuysen, Sarah, Claes, Godelieve, Deprez, Liesbet, Smets, Katrien, Van Dyck, Tine, Deconinck, Tine, De Jonghe, Peter, Jordanova, Albena, Møller, R, Weber, Yg, Klitten, Ll, Trucks, H, Muhle, H, Kunz, W, Mefford, Hc, Franke, A, Kautza, M, Wolf, P, Dennig, D, Schreiber, S, Rückert, Im, Wichmann, He, Ernst, Jp, Schurmann, C, Grabe, Hj, Tommerup, N, Stephani, U, Lerche, H, Hjalgrim, H, Helbig, I, Sander, T, Epicure, Consortium, DEL GIUDICE, Ennio, Coppola, Antonietta, and YÜCESAN, EMRAH

Subjects
Male, Idiopathic generalized epilepsy, Neuronal, Idiopathic Generalized Epilepsy, 1q21, 1 Microdeletion, Two-hit Hypothesis, Nrxn1, Neuropsychological Tests, Immunoglobulin E, Cell Adhesion Molecules, Neuronal/genetics, Adult, Age of Onset, Anticonvulsant, Exon, 1q21.1 microdeletion, Exons/genetics, Odds Ratio, Nerve Tissue Proteins/genetics, Copy-number variation, Valproic Acid/therapeutic use, Age of Onset, Neural Cell Adhesion Molecules, genetics, DNA Copy Number Variations, Electroencephalography, Epilepsy, Genetics, biology, Triazines, Anticonvulsants/therapeutic use, Electroencephalography, genetics, Family, Female, Fructose, Exons, Middle Aged, Settore MED/39 - Neuropsichiatria Infantile, Pedigree, therapeutic use, Valproic Acid, Neurology, Settore MED/26 - Neurologia, Anticonvulsants, Epilepsy, Generalized, Female, Adult, Case-Control Studies, Cell Adhesion Molecules, Neuronal, DNA Copy Number Variations, Family, Fructose, Gene Deletion, Genotype, Humans, Infant, Microarray Analysis, Nerve Tissue Proteins, Valproic Acid, analogs /&/ derivatives/therapeutic use, Gene Deletion, Genotype, Humans, Infant, Male, Microarray Analysis, Middle Aged, Nerve Tissue Protein, therapeutic use, Case-Control Studies, Cell Adhesion Molecule, drug therapy/genetics/psychology, Exon, genetics, Neuropsychological Tests, Odds Ratio, Pedigree, Triazine, Lamotrigine, NRXN1, Topiramate, Epilepsy, Generalized/drug therapy, medicine, Allele, Biology, Gene, Generalized, Point mutation, Calcium-Binding Proteins, Odds ratio, medicine.disease, Triazines/therapeutic use, Settore MED/03 - Genetica Medica, therapeutic use, biology.protein, Fructose/analogs & derivatives, Human medicine, Neurology (clinical), Two-hit hypothesis
Abstract

Summary Purpose Neurexins are neuronal adhesion molecules located in the presynaptic terminal, where they interact with postsynaptic neuroligins to form a transsynaptic complex required for efficient neurotransmission in the brain. Recently, deletions and point mutations of the neurexin 1 (NRXN1) gene have been associated with a broad spectrum of neuropsychiatric disorders. This study aimed to investigate if NRXN1 deletions also increase the risk of idiopathic generalized epilepsies (IGEs). Methods We screened for deletions involving the NRXN1 gene in 1,569 patients with IGE and 6,201 controls using high-density oligonucleotide microarrays. Key Findings We identified exon-disrupting deletions of NRXN1 in 5 of 1,569 patients with IGE and 2 of 6,201 control individuals (p = 0.0049; odds ratio (OR) 9.91, 95% confidence interval (CI) 1.92–51.12). A complex familial segregation pattern in the IGE families was observed, suggesting that heterozygous NRXN1 deletions are susceptibility variants. Intriguingly, we identified a second large copy number variant in three of five index patients, supporting an involvement of heterogeneous susceptibility alleles in the etiology of IGE. Significance We conclude that exon-disrupting deletions of NRXN1 represent a genetic risk factor in the genetically complex predisposition of common IGE syndromes.

Published
2013
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5. Evaluation of presumably disease causing SCN1A variants in a cohort of common epilepsy syndromes

Author

Lal, D. (Dennis), Reinthaler, E.M. (Eva M.), Dejanovic, B. (Borislav), May, P. (Patrick), Thiele, H. (Holger), Lehesjoki, A.E., Schwarz, G. (Günter), Riesch, E. (Erik), Ikram, M.A. (Arfan), Duijn, C.M. (Cornelia) van, Uitterlinden, A.G. (André), Hofman, A. (Albert), Steinböck, H. (Hannelore), Gruber-Sedlmayr, U. (Ursula), Neophytou, B. (Birgit), Zara, F. (Federico), Hahn, A. (Andreas), Gormley, A.M., Becker, F. (Felicitas), Weber, Y.G. (Yvonne G.), Cilio, M.R. (Maria Roberta), Kunz, W.S. (Wolfram S.), Krause, R. (Roland), Zimprich, F. (Fritz), Lemke, J.R. (Johannes R.), Nürnberg, P. (Peter), Sander, T. (Thomas), Lerche, H. (Holger), Neubauer, B.A. (Bernd A.), Palotie, A. (Aarno), Ruppert, A.-K. (Ann-Kathrin), Suls, A. (A.), Siren, A. (Auli), Koeleman, B.P.C. (Bobby), Haberlandt, E. (Edda), Ronen, G.M. (Gabriel M.), Caglayan, H. (Hande), Hjalgrim, H. (Helle), Muhle, H. (Hiltrud), Schulz, H. (Herbert), Helbig, I. (Ingo), Altmüller, J. (Janine), Geldner, J. (Julia), Schubert, J. (Julian), Jabbari, K. (Kamel), Everett, K. (Kate), Feucht, M. (Martha), Balestri, M. (Martina), Nothnagel, M. (Michael), Striano, P. (Pasquale), Møller, R.S. (Rikke), Nabbout, R. (Rima), Balling, R. (Rudi), Baulac, S. (Stephanie), Kunz, W. (Wolfram), Bianchi, A. (Amedeo), La Neve, A. (Angela), Minetti, C., Giuseppe, C. (Capovilla), Lal, D. (Dennis), Reinthaler, E.M. (Eva M.), Dejanovic, B. (Borislav), May, P. (Patrick), Thiele, H. (Holger), Lehesjoki, A.E., Schwarz, G. (Günter), Riesch, E. (Erik), Ikram, M.A. (Arfan), Duijn, C.M. (Cornelia) van, Uitterlinden, A.G. (André), Hofman, A. (Albert), Steinböck, H. (Hannelore), Gruber-Sedlmayr, U. (Ursula), Neophytou, B. (Birgit), Zara, F. (Federico), Hahn, A. (Andreas), Gormley, A.M., Becker, F. (Felicitas), Weber, Y.G. (Yvonne G.), Cilio, M.R. (Maria Roberta), Kunz, W.S. (Wolfram S.), Krause, R. (Roland), Zimprich, F. (Fritz), Lemke, J.R. (Johannes R.), Nürnberg, P. (Peter), Sander, T. (Thomas), Lerche, H. (Holger), Neubauer, B.A. (Bernd A.), Palotie, A. (Aarno), Ruppert, A.-K. (Ann-Kathrin), Suls, A. (A.), Siren, A. (Auli), Koeleman, B.P.C. (Bobby), Haberlandt, E. (Edda), Ronen, G.M. (Gabriel M.), Caglayan, H. (Hande), Hjalgrim, H. (Helle), Muhle, H. (Hiltrud), Schulz, H. (Herbert), Helbig, I. (Ingo), Altmüller, J. (Janine), Geldner, J. (Julia), Schubert, J. (Julian), Jabbari, K. (Kamel), Everett, K. (Kate), Feucht, M. (Martha), Balestri, M. (Martina), Nothnagel, M. (Michael), Striano, P. (Pasquale), Møller, R.S. (Rikke), Nabbout, R. (Rima), Balling, R. (Rudi), Baulac, S. (Stephanie), Kunz, W. (Wolfram), Bianchi, A. (Amedeo), La Neve, A. (Angela), Minetti, C., and Giuseppe, C. (Capovilla)

Abstract

Objective: The SCN1A gene, coding for the voltage-gated Na+ channel alpha subunit NaV1.1, is the clinically most relevant epilepsy gene. With the advent of high-throughput next-generation sequencing, clinical laboratories are generating an ever-increasing catalogue of SCN1A variants. Variants are more likely to be classified as pathogenic if they have already been identified previously in a patient with epilepsy. Here, we critically re-evaluate the pathogenicity of this class of variants in a cohort of patients with common epilepsy syndromes and subsequently ask whether a significant fraction of benign variants have been misclassified as pathogenic. Methods: We screened a discovery cohort of 448 patients with a broad range of common genetic epilepsies and 734 controls for previously reported SCN1A mutations that were assumed to be disease causing. We re-evaluated the evidence for pathogenicity of the identified variants using in silico predictions, segregation, original reports, available functional data and assessment of allele frequencies in healthy individuals as well as in a follow up cohort of 777 patients. Results and Interpretation: We identified 8 known missense mutations, previously reported as patho

Published
2016
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7. A new form of progressive myoclonus epilepsy with early ataxia and scoliosis due to mutation in the Golgi protein gosr2

Author

Berkovic, S.F., Corbett, M.A., Schwake, M., Bahlo, M., Dibbens, L.M., Lin, M., Gandolfo, L., Vears, D.F., O'Sullivan, J., Robertson, T., Bayly, M.A., Gardner, A.E., Vlaar, A.M.M., Korenke, C.G., Bloem, B.R., Coo, I.F. de, Verhagen, J.M.A., Lehesjoki, A.E., Saftig, P., and Gecz, J.

Subjects
Functional Neurogenomics [DCN 2]
Abstract

Item does not contain fulltext

Published
2011

8. 'North Sea' progressive myoclonus epilepsy: phenotype of subjects with GOSR2 mutation

Author

Boisse Lomax, L., Bayly, M.A., Hjalgrim, H., Moller, R.S., Vlaar, A.M.M., Aaberg, K.M., Marquardt, I., Gandolfo, L.C., Willemsen, M.A., Kamsteeg, E.J., O'Sullivan, J.D., Korenke, G.C., Bloem, B.R., Coo, I.F. de, Verhagen, J.M.A., Said, I., Prescott, T., Stray-Pedersen, A., Rasmussen, M., Vears, D.F., Lehesjoki, A.E., Corbett, M.A., Bahlo, M., Gecz, J., Dibbens, L.M., Berkovic, S.F., Boisse Lomax, L., Bayly, M.A., Hjalgrim, H., Moller, R.S., Vlaar, A.M.M., Aaberg, K.M., Marquardt, I., Gandolfo, L.C., Willemsen, M.A., Kamsteeg, E.J., O'Sullivan, J.D., Korenke, G.C., Bloem, B.R., Coo, I.F. de, Verhagen, J.M.A., Said, I., Prescott, T., Stray-Pedersen, A., Rasmussen, M., Vears, D.F., Lehesjoki, A.E., Corbett, M.A., Bahlo, M., Gecz, J., Dibbens, L.M., and Berkovic, S.F.

Abstract

Item does not contain fulltext, We previously identified a homozygous mutation in the Golgi SNAP receptor complex 2 gene (GOSR2) in six patients with progressive myoclonus epilepsy. To define the syndrome better we analysed the clinical and electrophysiological phenotype in 12 patients with GOSR2 mutations, including six new unrelated subjects. Clinical presentation was remarkably similar with early onset ataxia (average 2 years of age), followed by myoclonic seizures at the average age of 6.5 years. Patients developed multiple seizure types, including generalized tonic clonic seizures, absence seizures and drop attacks. All patients developed scoliosis by adolescence, making this an important diagnostic clue. Additional skeletal deformities were present, including pes cavus in four patients and syndactyly in two patients. All patients had elevated serum creatine kinase levels (median 734 IU) in the context of normal muscle biopsies. Electroencephalography revealed pronounced generalized spike and wave discharges with a posterior predominance and photosensitivity in all patients, with focal EEG features seen in seven patients. The disease course showed a relentless decline; patients uniformly became wheelchair bound (mean age 13 years) and four had died during their third or early fourth decade. All 12 cases had the same variant (c.430G>T, G144W) and haplotype analyses confirmed a founder effect. The cases all came from countries bounding the North Sea, extending to the coastal region of Northern Norway. 'North Sea' progressive myoclonus epilepsy has a homogeneous clinical presentation and relentless disease course allowing ready identification from the other progressive myoclonus epilepsies.

Published
2013

9. A mutation in the Golgi Qb-SNARE gene GOSR2 causes progressive myoclonus epilepsy with early ataxia

Author

Corbett, M., Schwake, M., Bahlo, M., Dibbens, L.M., Lin, M., Gandolfo, L.C., Vears, D.F., O'Sullivan, J.D., Robertson, T., Bayly, M.A., Gardner, A.E., Vlaar, A.M.M., Korenke, G.C., Bloem, B.R., Coo, I.F.M. de, Verhagen, J.M., Lehesjoki, A.E., Gecz, J., Berkovic, S.F., Corbett, M., Schwake, M., Bahlo, M., Dibbens, L.M., Lin, M., Gandolfo, L.C., Vears, D.F., O'Sullivan, J.D., Robertson, T., Bayly, M.A., Gardner, A.E., Vlaar, A.M.M., Korenke, G.C., Bloem, B.R., Coo, I.F.M. de, Verhagen, J.M., Lehesjoki, A.E., Gecz, J., and Berkovic, S.F.

Abstract

Item does not contain fulltext, The progressive myoclonus epilepsies (PMEs) are a group of predominantly recessive disorders that present with action myoclonus, tonic-clonic seizures, and progressive neurological decline. Many PMEs have similar clinical presentations yet are genetically heterogeneous, making accurate diagnosis difficult. A locus for PME was mapped in a consanguineous family with a single affected individual to chromosome 17q21. An identical-by-descent, homozygous mutation in GOSR2 (c.430G>T, p.Gly144Trp), a Golgi vesicle transport gene, was identified in this patient and in four apparently unrelated individuals. A comparison of the phenotypes in these patients defined a clinically distinct PME syndrome characterized by early-onset ataxia, action myoclonus by age 6, scoliosis, and mildly elevated serum creatine kinase. This p.Gly144Trp mutation is equivalent to a loss of function and results in failure of GOSR2 protein to localize to the cis-Golgi.

Published
2011

11. Variation of CNV distribution in five different ethnic populations.

Author

White, S.J., Vissers, L.E.L.M., Geurts van Kessel, A.H.M., Menezes, R.X. de, Kalay, E., Lehesjoki, A.E., Giordano, P.C., Vosse, E. van de, Breuning, M.H., Brunner, H.G., Dunnen, J.T. den, Veltman, J.A., White, S.J., Vissers, L.E.L.M., Geurts van Kessel, A.H.M., Menezes, R.X. de, Kalay, E., Lehesjoki, A.E., Giordano, P.C., Vosse, E. van de, Breuning, M.H., Brunner, H.G., Dunnen, J.T. den, and Veltman, J.A.

Abstract

Item does not contain fulltext, Recent studies have revealed a new type of variation in the human genome encompassing relatively large genomic segments ( approximately 100 kb-2.5 Mb), commonly referred to as copy number variation (CNV). The full nature and extent of CNV and its frequency in different ethnic populations is still largely unknown. In this study we surveyed a set of 12 CNVs previously detected by array-CGH. More than 300 individuals from five different ethnic populations, including three distinct European, one Asian and one African population, were tested for the occurrence of CNV using multiplex ligation-dependent probe amplification (MLPA). Seven of these loci indeed showed CNV, i.e., showed copy numbers that deviated from the population median. More precise estimations of the actual genomic copy numbers for (part of) the NSF gene locus, revealed copy numbers ranging from two to at least seven. Additionally, significant inter-population differences in the distribution of these copy numbers were observed. These data suggest that insight into absolute DNA copy numbers for loci exhibiting CNV is required to determine their potential contribution to normal phenotypic variation and, in addition, disease susceptibility.

Published
2007

13. Mutations in the O-Mannosyltransferase Gene POMT1 Give Rise to the Severe Neuronal Migration Disorder Walker-Warburg Syndrome.

Author

Beltran Valero de Bernabe, D., Currier, S., Steinbrecher, A., Celli, J., Beusekom, E. van, Zwaag, A. van der, Kayserili, H., Merlini, L., Chitayat, D., Dobyns, W.B., Cormand, B., Lehesjoki, A.E., Cruces, J., Voit, T., Walsh, C.A., Bokhoven, J.H.L.M. van, Brunner, H.G., Beltran Valero de Bernabe, D., Currier, S., Steinbrecher, A., Celli, J., Beusekom, E. van, Zwaag, A. van der, Kayserili, H., Merlini, L., Chitayat, D., Dobyns, W.B., Cormand, B., Lehesjoki, A.E., Cruces, J., Voit, T., Walsh, C.A., Bokhoven, J.H.L.M. van, and Brunner, H.G.

Abstract

Item does not contain fulltext, Walker-Warburg syndrome (WWS) is an autosomal recessive developmental disorder characterized by congenital muscular dystrophy and complex brain and eye abnormalities. A similar combination of symptoms is presented by two other human diseases, muscle-eye-brain disease (MEB) and Fukuyama congenital muscular dystrophy (FCMD). Although the genes underlying FCMD (Fukutin) and MEB (POMGnT1) have been cloned, loci for WWS have remained elusive. The protein products of POMGnT1 and Fukutin have both been implicated in protein glycosylation. To unravel the genetic basis of WWS, we first performed a genomewide linkage analysis in 10 consanguineous families with WWS. The results indicated the existence of at least three WWS loci. Subsequently, we adopted a candidate-gene approach in combination with homozygosity mapping in 15 consanguineous families with WWS. Candidate genes were selected on the basis of the role of the FCMD and MEB genes. Since POMGnT1 encodes an O-mannoside N-acetylglucosaminyltransferase, we analyzed the possible implication of O-mannosyl glycan synthesis in WWS. Analysis of the locus for O-mannosyltransferase 1 (POMT1) revealed homozygosity in 5 of 15 families. Sequencing of the POMT1 gene revealed mutations in 6 of the 30 unrelated patients with WWS. Of the five mutations identified, two are nonsense mutations, two are frameshift mutations, and one is a missense mutation. Immunohistochemical analysis of muscle from patients with POMT1 mutations corroborated the O-mannosylation defect, as judged by the absence of glycosylation of alpha-dystroglycan. The implication of O-mannosylation in MEB and WWS suggests new lines of study in understanding the molecular basis of neuronal migration.

Published
2002

14. SCARB2mutations in progressive myoclonus epilepsy (PME) without renal failure

Author

Dibbens, L.M., primary, Michelucci, R., additional, Gambardella, A., additional, Andermann, F., additional, Rubboli, G., additional, Bayly, M.A., additional, Joensuu, T., additional, Vears, D.F., additional, Franceschetti, S., additional, Canafoglia, L., additional, Wallace, R., additional, Bassuk, A.G., additional, Power, D.A., additional, Tassinari, C.A., additional, Andermann, E., additional, Lehesjoki, A.E., additional, and Berkovic, S.F., additional

Published
2009
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15. Clinical and genetic distinction between Walker-Warburg syndrome and muscle-eye-brain disease.

Author

Cormand, B., Pihko, H., Bayes, M., Valanne, L., Santavuori, P., Talim, B., Gershoni-Baruch, R., Ahmad, A., Bokhoven, J.H.L.M. van, Brunner, H.G., Voit, T., Topaloglu, H., Dobyns, W.B., Lehesjoki, A.E., Cormand, B., Pihko, H., Bayes, M., Valanne, L., Santavuori, P., Talim, B., Gershoni-Baruch, R., Ahmad, A., Bokhoven, J.H.L.M. van, Brunner, H.G., Voit, T., Topaloglu, H., Dobyns, W.B., and Lehesjoki, A.E.

Abstract

Item does not contain fulltext, BACKGROUND: Three rare autosomal recessive disorders share the combination of congenital muscular dystrophy and brain malformations including a neuronal migration defect: muscle-eye-brain disease (MEB), Walker-Warburg syndrome (WWS), and Fukuyama congenital muscular dystrophy (FCMD). In addition, ocular abnormalities are a constant feature in MEB and WWS. Lack of consistent ocular abnormalities in FCMD has allowed a clear clinical demarcation of this syndrome, whereas the phenotypic distinction between MEB and WWS has remained controversial. The MEB gene is located on chromosome 1p32-p34. OBJECTIVES: To establish distinguishing diagnostic criteria for MEB and WWS and to determine whether MEB and WWS are allelic disorders. METHODS: The authors undertook clinical characterization followed by linkage analysis in 19 MEB/WWS families with 29 affected individuals. With use of clinical diagnostic criteria based on Finnish patients with MEB, each patient was categorized as having either MEB or WWS. A linkage and haplotype analysis using 10 markers spanning the MEB locus was performed on the entire family resource. RESULTS: Patients in 11 families were classified as having MEB and in 8 families as WWS. Strong evidence in favor of genetic heterogeneity was obtained in the 19 families. There was evidence for linkage to 1p32-p34 in all but 1 of the 11 pedigrees segregating the MEB phenotype. In contrast, linkage to the MEB locus was excluded in seven of eight of the WWS families. CONCLUSION: These results allow the classification of MEB and WWS as distinct disorders on both clinical and genetic grounds and provide a basis for the mapping of the WWS gene(s).

Published
2001

17. Variation of CNV distribution in five different ethnic populations

Author

White, S.J., primary, Vissers, L.E.L.M., additional, Geurts van Kessel, A., additional, de Menezes, R.X., additional, Kalay, E., additional, Lehesjoki, A.E., additional, Giordano, P.C., additional, van de Vosse, E., additional, Breuning, M.H., additional, Brunner, H.G., additional, den Dunnen, J.T., additional, and Veltman, J.A., additional

Published
2007
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18. SCARB2 mutations in progressive myoclonus epilepsy (PME) without renal failure.

Author

Dibbens, L.M., Michelucci, R., Gambardella, A., Andermann, F., Rubboli, G., Bayly, M.A., Joensuu, T., Vears, D.F., Franceschetti, S., Canafoglia, L., Wallace, R., Bassuk, A.G., Power, D.A., Tassinari, C.A., Andermann, E., Lehesjoki, A.E., and Berkovic, S.F.

Abstract

Objective Mutations in SCARB2 were recently described as causing action myoclonus renal failure syndrome (AMRF). We hypothesized that mutations in SCARB2 might account for unsolved cases of progressive myoclonus epilepsy (PME) without renal impairment, especially those resembling Unverricht-Lundborg disease (ULD). Additionally, we searched for mutations in the PRICKLE1 gene, newly recognized as a cause of PME mimicking ULD. Methods We reviewed cases of PME referred for diagnosis over two decades in which a molecular diagnosis had not been reached. Patients were classified according to age of onset, clinical pattern, and associated neurological signs into 'ULD-like' and 'not ULD-like.' After exclusion of mutations in cystatin B (CSTB), DNA was examined for sequence variation in SCARB2 and PRICKLE1. Results Of 71 cases evaluated, 41 were 'ULD-like' and five had SCARB2 mutations. None of 30 'not ULD-like' cases were positive. The five patients with SCARB2 mutations had onset between 14 and 26 years of age, with no evidence of renal failure during 5.5 to 15 years of follow-up; four were followed until death. One living patient had slight proteinuria. A subset of 25 cases were sequenced for PRICKLE1 and no mutations were found. Interpretation Mutations in SCARB2 are an important cause of hitherto unsolved cases of PME resembling ULD at onset. SCARB2 should be evaluated even in the absence of renal involvement. Onset is in teenage or young adult life. Molecular diagnosis is important for counseling the patient and family, particularly as the prognosis is worse than classical ULD. Ann Neurol 2009;66:532-536 [ABSTRACT FROM AUTHOR]

Published
2009
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19. Turkish variant late infantile neuronal ceroid lipofuscinosis (CLN7) may be allelic to CLN8

Author

Mitchell, W.A., Wheeler, R.B., Sharp, J.D., Bate, S.L., Gardiner, R.M., Ranta, U.S., Lonka, L., Williams, R.E., Lehesjoki, A.E., and Mole, S.E.

Abstract

One variant form of late infantile neuronal ceroid lipofuscinosis (LINCL) is found predominantly within the Turkishpopulation (CLN7). Exclusion mapping showed that CLN7 was not an allelic variant of known NCL loci (CLN1, CLN2, CLN3, CLN5 or CLN6). Using the method of homozygosity mapping, a genome-wide search was undertaken and a total of 358 microsatellite markers were typed at an average distance of about 10cM. A region of shared homozygosity was identified on chromosome 8p23. This telomeric region contained the recently identified CLN8 gene. A missense mutation in CLN8 causes progressive epilepsy with mental retardation (EPMR) or Northern epilepsy, which has so far been reported only from Finland and is now classified as an NCL. The mouse model mnd has been shown to carry a 1 by insertion in the orthologous CIn8 gene. Statistically significant evidence for linkage was obtained in this region, with LOD scores > 3, assuming either homogeneity or heterogeneity. Flanking recombinants defined a critical region of 14 cM between D8S504 and D8S1458 which encompasses CLN8. This suggests that Turkish variant LINCL, despite having an earlier onset and more severe phenotype, may be an allelic variant of Northern epilepsy. However mutation analysis has not so far identified a disease causing mutation within the coding or non-coding exons of CLN8 in the families. The Turkish variant LINCL disease-causing mutation remains to be delineated.

Published
2001
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20. Genome-wide linkage meta-analysis identifies susceptibility loci at 2q34 and 13q31.3 for genetic generalized epilepsies

Author

EPICURE Consortium, Leu C., de Kovel C. G., Zara F., Striano P., Pezzella M., Robbiano A., Bianchi A., Coppola A., Giallonardo A. T., Beccaria F., Trenité D. K., Lindhout D., Gaus V., Schmitz B., Janz D., Weber Y. G., Becker F., Lerche H., Kleefuss Lie A. A., Hallman K., Kunz W. S., Elger C. E., Muhle H., Stephani U., Møller R. S., Hjalgrim H., Mullen S., Scheffer I. E., Berkovic S. F., Everett K. V., Gardiner M. R., Marini C., Guerrini R., Lehesjoki A. E., Siren A., Nabbout R., Baulac S., Leguern E., Serratosa J. M., Rosenow F., Feucht M., Unterberger I., Covanis A., Suls A., Weckhuysen S., Kaneva R., Caglayan H., Turkdogan D., Baykan B., Bebek N., Ozbek U., Hempelmann A., Schulz H., Rüschendorf F., Trucks H., Nürnberg P., Avanzini G., Koeleman B. P., Sander T., BISULLI, FRANCESCA, TINUPER, PAOLO, YÜCESAN, EMRAH, EPICURE Consortium, Leu C., de Kovel C.G., Zara F., Striano P., Pezzella M., Robbiano A., Bianchi A., Bisulli F., Coppola A., Giallonardo A.T., Beccaria F., Trenité D.K., Lindhout D., Gaus V., Schmitz B., Janz D., Weber Y.G., Becker F., Lerche H., Kleefuss-Lie A.A., Hallman K., Kunz W.S., Elger C.E., Muhle H., Stephani U., Møller R.S., Hjalgrim H., Mullen S., Scheffer I.E., Berkovic S.F., Everett K.V., Gardiner M.R., Marini C., Guerrini R., Lehesjoki A.E., Siren A., Nabbout R., Baulac S., Leguern E., Serratosa J.M., Rosenow F., Feucht M., Unterberger I., Covanis A., Suls A., Weckhuysen S., Kaneva R., Caglayan H., Turkdogan D., Baykan B., Bebek N., Ozbek U., Hempelmann A., Schulz H., Rüschendorf F., Trucks H., Nürnberg P., Avanzini G., Koeleman B.P., Sander T., and Tinuper P.

Subjects
Male, Chromosomes, Human, Pair 13, Genotype, Genetic Linkage, Chromosome Mapping, complex inheritance, Pedigree, genetic generalized epilepsy, myoclonic seizure, Phenotype, Genetic Loci, Chromosomes, Human, Pair 2, Humans, Epilepsy, Generalized, Family, Female, Genetic Predisposition to Disease, linkage analysis, absence seizure, Genome-Wide Association Study
Abstract

PURPOSE: Genetic generalized epilepsies (GGEs) have a lifetime prevalence of 0.3% with heritability estimates of 80%. A considerable proportion of families with siblings affected by GGEs presumably display an oligogenic inheritance. The present genome-wide linkage meta-analysis aimed to map: (1) susceptibility loci shared by a broad spectrum of GGEs, and (2) seizure type-related genetic factors preferentially predisposing to either typical absence or myoclonic seizures, respectively. METHODS: Meta-analysis of three genome-wide linkage datasets was carried out in 379 GGE-multiplex families of European ancestry including 982 relatives with GGEs. To dissect out seizure type-related susceptibility genes, two family subgroups were stratified comprising 235 families with predominantly genetic absence epilepsies (GAEs) and 118 families with an aggregation of juvenile myoclonic epilepsy (JME). To map shared and seizure type-related susceptibility loci, both nonparametric loci (NPL) and parametric linkage analyses were performed for a broad trait model (GGEs) in the entire set of GGE-multiplex families and a narrow trait model (typical absence or myoclonic seizures) in the subgroups of JME and GAE families. KEY FINDINGS: For the entire set of 379 GGE-multiplex families, linkage analysis revealed six loci achieving suggestive evidence for linkage at 1p36.22, 3p14.2, 5q34, 13q12.12, 13q31.3, and 19q13.42. The linkage finding at 5q34 was consistently supported by both NPL and parametric linkage results across all three family groups. A genome-wide significant nonparametric logarithm of odds score of 3.43 was obtained at 2q34 in 118 JME families. Significant parametric linkage to 13q31.3 was found in 235 GAE families assuming recessive inheritance (heterogeneity logarithm of odds = 5.02). SIGNIFICANCE: Our linkage results support an oligogenic predisposition of familial GGE syndromes. The genetic risk factor at 5q34 confers risk to a broad spectrum of familial GGE syndromes, whereas susceptibility loci at 2q34 and 13q31.3 preferentially predispose to myoclonic seizures or absence seizures, respectively. Phenotype- genotype strategies applying narrow trait definitions in phenotypic homogeneous subgroups of families improve the prospects of disentangling the genetic basis of common familial GGE syndromes.

Published
2012

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