School of Mathematics and Statistics - Research Publications

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Author: Berkovic, Samuel × Author: Broderick, Karen × Start date: 2000 × Type: Journal Article ×

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    A founder event causing a dominant childhood epilepsy survives 800 years through weak selective pressure
    Grinton, BE ; Robertson, E ; Fearnley, LG ; Scheffer, IE ; Marson, AG ; O'Brien, TJ ; Pickrell, WO ; Rees, M ; Sisodiya, SM ; Balding, DJ ; Bennett, MF ; Bahlo, M ; Berkovic, SF ; Oliver, KL (CELL PRESS, 2022-11-03)
    Genetic epilepsy with febrile seizures plus (GEFS+) is an autosomal dominant familial epilepsy syndrome characterized by distinctive phenotypic heterogeneity within families. The SCN1B c.363C>G (p.Cys121Trp) variant has been identified in independent, multi-generational families with GEFS+. Although the variant is present in population databases (at very low frequency), there is strong clinical, genetic, and functional evidence to support pathogenicity. Recurrent variants may be due to a founder event in which the variant has been inherited from a common ancestor. Here, we report evidence of a single founder event giving rise to the SCN1B c.363C>G variant in 14 independent families with epilepsy. A common haplotype was observed in all families, and the age of the most recent common ancestor was estimated to be approximately 800 years ago. Analysis of UK Biobank whole-exome-sequencing data identified 74 individuals with the same variant. All individuals carried haplotypes matching the epilepsy-affected families, suggesting all instances of the variant derive from a single mutational event. This unusual finding of a variant causing an autosomal dominant, early-onset disease in an outbred population that has persisted over many generations can be attributed to the relatively mild phenotype in most carriers and incomplete penetrance. Founder events are well established in autosomal recessive and late-onset disorders but are rarely observed in early-onset, autosomal dominant diseases. These findings suggest variants present in the population at low frequencies should be considered potentially pathogenic in mild phenotypes with incomplete penetrance and may be more important contributors to the genetic landscape than previously thought.
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    Genome-wide mega-analysis identifies 16 loci and highlights diverse biological mechanisms in the common epilepsies
    Abou-Khalil, B ; Auce, P ; Avbersek, A ; Bahlo, M ; Balding, DJ ; Bast, T ; Baum, L ; Becker, AJ ; Becker, F ; Berghuis, B ; Berkovic, SF ; Boysen, KE ; Bradfield, JP ; Brody, LC ; Buono, RJ ; Campbell, E ; Cascino, GD ; Catarino, CB ; Cavalleri, GL ; Cherny, SS ; Chinthapalli, K ; Coffey, AJ ; Compston, A ; Coppola, A ; Cossette, P ; Craig, JJ ; de Haan, G-J ; De Jonghe, P ; de Kovel, CGF ; Delanty, N ; Depondt, C ; Devinsky, O ; Dlugos, DJ ; Doherty, CP ; Elger, CE ; Eriksson, JG ; Ferraro, TN ; Feucht, M ; Francis, B ; Franke, A ; French, JA ; Freytag, S ; Gaus, V ; Geller, EB ; Gieger, C ; Glauser, T ; Glynn, S ; Goldstein, DB ; Gui, H ; Guo, Y ; Haas, KF ; Hakonarson, H ; Hallmann, K ; Haut, S ; Heinzen, EL ; Helbig, I ; Hengsbach, C ; Hjalgrim, H ; Iacomino, M ; Ingason, A ; Jamnadas-Khoda, J ; Johnson, MR ; Kalviainen, R ; Kantanen, A-M ; Kasperaviciute, D ; Trenite, DK-N ; Kirsch, HE ; Knowlton, RC ; Koeleman, BPC ; Krause, R ; Krenn, M ; Kunz, WS ; Kuzniecky, R ; Kwan, P ; Lal, D ; Lau, Y-L ; Lehesjoki, A-E ; Lerche, H ; Leu, C ; Lieb, W ; Lindhout, D ; Lo, WD ; Lopes-Cendes, I ; Lowenstein, DH ; Malovini, A ; Marson, AG ; Mayer, T ; McCormack, M ; Mills, JL ; Mirza, N ; Moerzinger, M ; Moller, RS ; Molloy, AM ; Muhle, H ; Newton, M ; Ng, P-W ; Noethen, MM ; Nuernberg, P ; O'Brien, TJ ; Oliver, KL ; Palotie, A ; Pangilinan, F ; Peter, S ; Petrovski, S ; Poduri, A ; Privitera, M ; Radtke, R ; Rau, S ; Reif, PS ; Reinthaler, EM ; Rosenow, F ; Sander, JW ; Sander, T ; Scattergood, T ; Schachter, SC ; Schankin, CJ ; Scheffer, IE ; Schmitz, B ; Schoch, S ; Sham, PC ; Shih, JJ ; Sills, GJ ; Sisodiya, SM ; Slattery, L ; Smith, A ; Smith, DF ; Smith, MC ; Smith, PE ; Sonsma, ACM ; Speed, D ; Sperling, MR ; Steinhoff, BJ ; Stephani, U ; Stevelink, R ; Strauch, K ; Striano, P ; Stroink, H ; Surges, R ; Tan, KM ; Thio, LL ; Thomas, GN ; Todaro, M ; Tozzi, R ; Vari, MS ; Vining, EPG ; Visscher, F ; von Spiczak, S ; Walley, NM ; Weber, YG ; Wei, Z ; Weisenberg, J ; Whelan, CD ; Widdess-Walsh, P ; Wolff, M ; Wolking, S ; Yang, W ; Zara, F ; Zimprich, F (NATURE PUBLISHING GROUP, 2018-12-10)
    The epilepsies affect around 65 million people worldwide and have a substantial missing heritability component. We report a genome-wide mega-analysis involving 15,212 individuals with epilepsy and 29,677 controls, which reveals 16 genome-wide significant loci, of which 11 are novel. Using various prioritization criteria, we pinpoint the 21 most likely epilepsy genes at these loci, with the majority in genetic generalized epilepsies. These genes have diverse biological functions, including coding for ion-channel subunits, transcription factors and a vitamin-B6 metabolism enzyme. Converging evidence shows that the common variants associated with epilepsy play a role in epigenetic regulation of gene expression in the brain. The results show an enrichment for monogenic epilepsy genes as well as known targets of antiepileptic drugs. Using SNP-based heritability analyses we disentangle both the unique and overlapping genetic basis to seven different epilepsy subtypes. Together, these findings provide leads for epilepsy therapies based on underlying pathophysiology.
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    Multiplex families with epilepsy Success of clinical and molecular genetic characterization
    Afawi, Z ; Oliver, KL ; Kivity, S ; Mazarib, A ; Blatt, I ; Neufeld, MY ; Helbig, KL ; Goldberg-Stern, H ; Misk, AJ ; Straussberg, R ; Walid, S ; Mahajnah, M ; Lerman-Sagie, T ; Ben-Zeev, B ; Kahana, E ; Masalha, R ; Kramer, U ; Ekstein, D ; Shorer, Z ; Wallace, RH ; Mangelsdorf, M ; MacPherson, JN ; Carvill, GL ; Mefford, HC ; Jackson, GD ; Scheffer, IE ; Bahlo, M ; Gecz, J ; Heron, SE ; Corbett, M ; Mulley, JC ; Dibbens, LM ; Korczyn, AD ; Berkovic, SF (LIPPINCOTT WILLIAMS & WILKINS, 2016-02-23)
    OBJECTIVE: To analyze the clinical syndromes and inheritance patterns of multiplex families with epilepsy toward the ultimate aim of uncovering the underlying molecular genetic basis. METHODS: Following the referral of families with 2 or more relatives with epilepsy, individuals were classified into epilepsy syndromes. Families were classified into syndromes where at least 2 family members had a specific diagnosis. Pedigrees were analyzed and molecular genetic studies were performed as appropriate. RESULTS: A total of 211 families were ascertained over an 11-year period in Israel. A total of 169 were classified into broad familial epilepsy syndrome groups: 61 generalized, 22 focal, 24 febrile seizure syndromes, 33 special syndromes, and 29 mixed. A total of 42 families remained unclassified. Pathogenic variants were identified in 49/211 families (23%). The majority were found in established epilepsy genes (e.g., SCN1A, KCNQ2, CSTB), but in 11 families, this cohort contributed to the initial discovery (e.g., KCNT1, PCDH19, TBC1D24). We expand the phenotypic spectrum of established epilepsy genes by reporting a familial LAMC3 homozygous variant, where the predominant phenotype was epilepsy with myoclonic-atonic seizures, and a pathogenic SCN1A variant in a family where in 5 siblings the phenotype was broadly consistent with Dravet syndrome, a disorder that usually occurs sporadically. CONCLUSION: A total of 80% of families were successfully classified, with pathogenic variants identified in 23%. The successful characterization of familial electroclinical and inheritance patterns has highlighted the value of studying multiplex families and their contribution towards uncovering the genetic basis of the epilepsies.
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    Diagnosis and misdiagnosis of adult neuronal ceroid lipofuscinosis (Kufs disease)
    Berkovic, SF ; Staropoli, JF ; Carpenter, S ; Oliver, KL ; Kmoch, S ; Anderson, GW ; Damiano, JA ; Hildebrand, MS ; Sims, KB ; Cotman, SL ; Bahlo, M ; Smith, KR ; Cadieux-Dion, M ; Cossette, P ; Jedlickova, I ; Pristoupilova, A ; Mole, SE (LIPPINCOTT WILLIAMS & WILKINS, 2016-08-09)
    OBJECTIVE: To critically re-evaluate cases diagnosed as adult neuronal ceroid lipofuscinosis (ANCL) in order to aid clinicopathologic diagnosis as a route to further gene discovery. METHODS: Through establishment of an international consortium we pooled 47 unsolved cases regarded by referring centers as ANCL. Clinical and neuropathologic experts within the Consortium established diagnostic criteria for ANCL based on the literature to assess each case. A panel of 3 neuropathologists independently reviewed source pathologic data. Cases were given a final clinicopathologic classification of definite ANCL, probable ANCL, possible ANCL, or not ANCL. RESULTS: Of the 47 cases, only 16 fulfilled the Consortium's criteria of ANCL (5 definite, 2 probable, 9 possible). Definitive alternate diagnoses were made in 10, including Huntington disease, early-onset Alzheimer disease, Niemann-Pick disease, neuroserpinopathy, prion disease, and neurodegeneration with brain iron accumulation. Six cases had features suggesting an alternate diagnosis, but no specific condition was identified; in 15, the data were inadequate for classification. Misinterpretation of normal lipofuscin as abnormal storage material was the commonest cause of misdiagnosis. CONCLUSIONS: Diagnosis of ANCL remains challenging; expert pathologic analysis and recent molecular genetic advances revealed misdiagnoses in >1/3 of cases. We now have a refined group of cases that will facilitate identification of new causative genes.
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    Harnessing Gene Expression Networks to Prioritize Candidate Epileptic Encephalopathy Genes
    Oliver, KL ; Lukic, V ; Thorne, NP ; Berkovic, SF ; Scheffer, IE ; Bahlo, M ; Zhou, F (PUBLIC LIBRARY SCIENCE, 2014-07-09)
    We apply a novel gene expression network analysis to a cohort of 182 recently reported candidate Epileptic Encephalopathy genes to identify those most likely to be true Epileptic Encephalopathy genes. These candidate genes were identified as having single variants of likely pathogenic significance discovered in a large-scale massively parallel sequencing study. Candidate Epileptic Encephalopathy genes were prioritized according to their co-expression with 29 known Epileptic Encephalopathy genes. We utilized developing brain and adult brain gene expression data from the Allen Human Brain Atlas (AHBA) and compared this to data from Celsius: a large, heterogeneous gene expression data warehouse. We show replicable prioritization results using these three independent gene expression resources, two of which are brain-specific, with small sample size, and the third derived from a heterogeneous collection of tissues with large sample size. Of the nineteen genes that we predicted with the highest likelihood to be true Epileptic Encephalopathy genes, two (GNAO1 and GRIN2B) have recently been independently reported and confirmed. We compare our results to those produced by an established in silico prioritization approach called Endeavour, and finally present gene expression networks for the known and candidate Epileptic Encephalopathy genes. This highlights sub-networks of gene expression, particularly in the network derived from the adult AHBA gene expression dataset. These networks give clues to the likely biological interactions between Epileptic Encephalopathy genes, potentially highlighting underlying mechanisms and avenues for therapeutic targets.