Salla Markkinen scite author profile

Progressive myoclonus epilepsies (PMEs) are a group of rare, inherited disorders manifesting with action myoclonus, tonic-clonic seizures, and ataxia. We exome-sequenced 84 unrelated PME patients of unknown cause and molecularly solved 26 cases (31%). Remarkably, a recurrent de novo mutation c.959G>A (p.Arg320His) in KCNC1 was identified as a novel major cause for PME. Eleven unrelated exome-sequenced (13%) and two patients in a secondary cohort (7%) had this mutation. KCNC1 encodes K V 3.1, a subunit of the K V 3 voltage-gated K + channels, major determinants of high-frequency neuronal firing. Functional analysis of the p.Arg320His mutant channel revealed a dominant-negative loss-of-function effect. Ten patients had pathogenic mutations in known PME-associated genes (NEU1, NHLRC1, AFG3L2, EPM2A, CLN6, SERPINI1). Identification of mutations in PRNP, SACS, and TBC1D24 expand their phenotypic spectrum to PME. These findings provide important insights into the molecular genetic basis of PME and reveal the role of de novo mutations in this disease entity.Correspondence should be addressed to Anna-Elina Lehesjoki (anna-elina.lehesjoki@helsinki.fi). Author Contributions Accession codesMutation nomenclatures correspond to the following canonical Ensembl transcripts: KCNC1, ENST00000265969.6; NEU1, ENST00000375631.4; NHLRC1, ENST00000340650.3; EPM2A, ENST00000367519.3; CLN6, ENST00000249806.5; AFG3L2, ENST00000269143.3; TBC1D24, ENST00000293970.5; SACS, ENST00000382298.3; SERPINI1, ENST00000295777.5; PRNP, ENST00000379440.4; SCN1A, ENST00000303395.4. The raw aligned sequence reads were submitted to the European Genome-phenome Archive (https://www.ebi.ac.uk/ega/home) by Wellcome Trust Sanger Institute under study accession numbers EGAS00001000048 and EGAS00001000386. Competing Financial InterestsAuthors declare no potential competing financial interests. Europe PMC Funders GroupAuthor Manuscript Nat Genet. Author manuscript; available in PMC 2015 July 01. Published in final edited form as:Nat Genet. 5,6 and GOSR2 7 also contribute to cases of PME with preserved cognition. Other PMEs may have additional features, particularly dementia. PME-associated genes encode a variety of proteins, many of them being associated with endosomal and lysosomal function 8,9 , but the associated disease mechanisms are generally poorly understood.The precise clinical diagnosis of specific forms of PME is challenging due to their genetic heterogeneity, phenotypic similarities and overlap of symptoms with other epileptic and neurodegenerative diseases. In many cases, there are no distinguishing clinical features or biomarkers. Consequently, a substantial proportion of PME cases remain without a molecular diagnosis 3 .Here, we aimed to identify the causative genes for unsolved PME cases by employing exome sequencing in unrelated patients assembled from multiple centers in Europe, North America, Asia, and Australia over a 25-year period. The extent of previous molecular studies varied, but all cases were negative for mutations in the ...

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BAP1 Germline Mutations in Finnish Patients with Uveal Melanoma

Turunen

Markkinen

Wilska

et al. 2016

Ophthalmology

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Population-based analysis of BAP1 germline variations in patients with uveal melanoma

Repo

Järvinen

Jäntti

et al. 2019

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Pathogenic germline variants in the BRCA1-associated protein 1 (BAP1) gene cause the BAP1 tumor predisposition syndrome (BAP1-TPDS) with increased risk of several cancers, the most frequent of which is uveal melanoma (UM). Pathogenicity of loss-of-function (LOF) BAP1 variants is clear, as opposed to that of missense and regulatory region variants. We sequenced the coding, promoter, untranslated region (UTR) and intronic regions of BAP1 and analyzed copy number variations (CNVs). In this nationwide study, the cohort comprised UM patients diagnosed between 2010 and 2017. These included 432 of 520 consecutive Finnish UM patients, 16 of whom were familial, and one additional patient from a Finnish–Swedish family. Twenty-one different rare variants were found: seven exonic, seven intronic, four 3′ UTR and three promoter. We considered five variants likely to be pathogenic by effect on splicing, nuclear localization or deubiquitination activity. Intron 2 (c.67+1G>T) and exon 14 (c.1780_1781insT) LOF variants were presumed founder mutations, occurring in two and four families, respectively; both abolished nuclear localization in vitro. Intron 2, exons 5 (c.281A>G) and 9 (c.680G>A) missense variants markedly reduced deubiquitinating activity. A deep intronic 25 base pair deletion in intron 1 caused aberrant splicing in vitro. On the basis of functional studies and family cancer history, we classified four exon 13 missense variants as benign. No CNVs were found. The prevalence of pathogenic variants was 9/433 (2%) and 4/16 (25%) in Finnish UM families. Family cancer history and functional assays are indispensable when establishing the pathogenicity of BAP1 variants. Deep intronic variants can cause BAP1-TPDS.

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BAP1 germline mutations in Finnish uveal melanoma patients

Turunen

Markkinen

Wilska

et al. 2014

Acta Ophthalmologica

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Purpose To estimate the frequency of germline mutations in the BRCA‐1 associated protein‐1 (BAP1) gene that predisposes to a range of cancer types, including uveal melanoma. Methods In Finland, all uveal melanoma patients are referred to the Ocular Oncology Service, Helsinki University Central Hospital. We collected clinical data and genomic DNA from 146 patients treated between 2011 and 2013. In addition, we identified 12 families each with two uveal melanoma patients. We were able to collect genomic DNA from 14 members of uveal melanoma families. All 17 exons of the BAP1 gene were sequenced in a total of 160 patients. Results We found two possible dominant mutations: a sporadic mutation in a highly conserved donor splice site after exon 2 and a frameshift insertion mutation in exon 14 in three patients. The latter mutation was found in a mother and son both diagnosed with uveal melanoma. The third patient, who shared the same mutation, is potentially a distant relative of this family. These mutations were not present in 3,325 Finnish controls from the Sisu project (www.sisuproject.fi). Conclusion BAP1 germline mutations in Finland contribute to uveal melanoma in only 1.4% of patients (2 mutations, 147 patients; 95% CI 0.2 ‐ 4.8) based on our non‐selected sample, excluding second cases in families. The BAP1 syndrome exists but does not seem to be particularly prevalent in Finland in spite that Northern Europe is a high risk region for this cancer.

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Salla Markkinen

A recurrent de novo mutation in KCNC1 causes progressive myoclonus epilepsy

BAP1 Germline Mutations in Finnish Patients with Uveal Melanoma

Population-based analysis of BAP1 germline variations in patients with uveal melanoma

BAP1 germline mutations in Finnish uveal melanoma patients

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