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4. Sodium channel expression and transcript variation in the developing brain of human, Rhesus monkey, and mouse

Author

Heighway, J, Sedo, A, Garg, A, Eldershaw, L, Perreau, V, Berecki, G, Reid, CA, Petrou, S, Maljevic, S, Heighway, J, Sedo, A, Garg, A, Eldershaw, L, Perreau, V, Berecki, G, Reid, CA, Petrou, S, and Maljevic, S

Abstract

Genetic variation in voltage-gated sodium (NaV) channels is a significant contributor to neurodevelopmental disorders. NaV channel alpha subunits are encoded by the SCNxA family and four are predominately expressed in the brain: SCN1A, SCN2A, SCN3A, and SCN8A. Gene expression is developmentally regulated, and they are known to express functionally distinct transcript variants. Precision therapies targeting these genes and their transcript variants are currently in preclinical development, yet the developmental expression of these transcripts in the human brain is yet to be fully understood. Additionally, the functional consequences of some mutations differ depending on the studied channel isoform, suggesting differential transcript variant expression can affect disease prognoses. We characterise the expression of the four SCNxAs and their transcript variants in human, Rhesus monkey and mouse brain using publicly available RNA-sequencing data and analysis tools, demonstrating that this approach can be used to answer important biological questions of gene and transcript developmental regulation. We find that gene expression and transcript variant regulation are conserved across species at similar developmental stages and determine the developmental milestones for transcript variant expression. Our study provides a guide to researchers testing therapies and clinicians advising prognoses based on the expression of channel isoforms.

Published
2022

5. Loss-of-function variants in the KCNQ5 gene are implicated in genetic generalized epilepsies

Author

Krueger, J, Schubert, J, Kegele, J, Labalme, A, Mao, M, Heighway, J, Seebohm, G, Yan, P, Koko, M, Aslan-Kara, K, Caglayan, H, Steinhoff, BJ, Weber, YG, Keo-Kosal, P, Berkovic, SF, Hildebrand, MS, Petrou, S, Krause, R, May, P, Lesca, G, Maljevic, S, Lerche, H, Krueger, J, Schubert, J, Kegele, J, Labalme, A, Mao, M, Heighway, J, Seebohm, G, Yan, P, Koko, M, Aslan-Kara, K, Caglayan, H, Steinhoff, BJ, Weber, YG, Keo-Kosal, P, Berkovic, SF, Hildebrand, MS, Petrou, S, Krause, R, May, P, Lesca, G, Maljevic, S, and Lerche, H

Abstract

BACKGROUND: De novo missense variants in KCNQ5, encoding the voltage-gated K+ channel KV7.5, have been described to cause developmental and epileptic encephalopathy (DEE) or intellectual disability (ID). We set out to identify disease-related KCNQ5 variants in genetic generalized epilepsy (GGE) and their underlying mechanisms. METHODS: 1292 families with GGE were studied by next-generation sequencing. Whole-cell patch-clamp recordings, biotinylation and phospholipid overlay assays were performed in mammalian cells combined with homology modelling. FINDINGS: We identified three deleterious heterozygous missense variants, one truncation and one splice site alteration in five independent families with GGE with predominant absence seizures; two variants were also associated with mild to moderate ID. All missense variants displayed a strongly decreased current density indicating a loss-of-function (LOF). When mutant channels were co-expressed with wild-type (WT) KV7.5 or KV7.5 and KV7.3 channels, three variants also revealed a significant dominant-negative effect on WT channels. Other gating parameters were unchanged. Biotinylation assays indicated a normal surface expression of the variants. The R359C variant altered PI(4,5)P2-interaction. INTERPRETATION: Our study identified deleterious KCNQ5 variants in GGE, partially combined with mild to moderate ID. The disease mechanism is a LOF partially with dominant-negative effects through functional deficits. LOF of KV7.5 channels will reduce the M-current, likely resulting in increased excitability of KV7.5-expressing neurons. Further studies on network level are necessary to understand which circuits are affected and how this induces generalized seizures. FUNDING: DFG/FNR Research Unit FOR-2715 (Germany/Luxemburg), BMBF rare disease network Treat-ION (Germany), foundation 'no epilep' (Germany).

Published
2022

6. Antisense oligonucleotide therapy for KCNT1 encephalopathy

Author

Burbano, LE, Li, M, Jancovski, N, Jafar-Nejad, P, Richards, K, Sedo, A, Soriano, A, Rollo, B, Jia, L, V. Gazina, E, Piltz, S, Adikusuma, F, Thomas, PQ, Kopsidas, H, Rigo, F, Reid, CA, Maljevic, S, Petrou, S, Burbano, LE, Li, M, Jancovski, N, Jafar-Nejad, P, Richards, K, Sedo, A, Soriano, A, Rollo, B, Jia, L, V. Gazina, E, Piltz, S, Adikusuma, F, Thomas, PQ, Kopsidas, H, Rigo, F, Reid, CA, Maljevic, S, and Petrou, S

Abstract

Developmental and epileptic encephalopathies (DEEs) are characterized by pharmaco-resistant seizures with concomitant intellectual disability. Epilepsy of infancy with migrating focal seizures (EIMFS) is one of the most severe of these syndromes. De novo variants in ion channels, including gain-of-function variants in KCNT1, which encodes for sodium activated potassium channel protein KNa1.1, have been found to play a major role in the etiology of EIMFS. Here, we test a potential precision therapeutic approach in KCNT1-associated DEE using a gene-silencing antisense oligonucleotide (ASO) approach. We generated a mouse model carrying the KCNT1 p.P924L pathogenic variant; only the homozygous animals presented with the frequent, debilitating seizures and developmental compromise that are seen in patients. After a single intracerebroventricular bolus injection of a Kcnt1 gapmer ASO in symptomatic mice at postnatal day 40, seizure frequency was significantly reduced, behavioral abnormalities improved, and overall survival was extended compared with mice treated with a control ASO (nonhybridizing sequence). ASO administration at neonatal age was also well tolerated and effective in controlling seizures and extending the life span of treated animals. The data presented here provide proof of concept for ASO-based gene silencing as a promising therapeutic approach in KCNT1-associated epilepsies.

Published
2022

9. Characterization of the GABRB2-Associated Neurodevelopmental Disorders

Author

Achkar, C.M. El, Harrer, M., Smith, L., Kelly, M., Iqbal, S., Maljevic, S., Niturad, C.E., Vissers, L.E.L.M., Poduri, A., Yang, E., Lal, D., Lerche, H., Møller, R.S., Olson, H.E., Achkar, C.M. El, Harrer, M., Smith, L., Kelly, M., Iqbal, S., Maljevic, S., Niturad, C.E., Vissers, L.E.L.M., Poduri, A., Yang, E., Lal, D., Lerche, H., Møller, R.S., and Olson, H.E.

Abstract

Item does not contain fulltext, OBJECTIVE: We aimed to characterize the phenotypic spectrum and functional consequences associated with variants in the gene GABRB2, coding for the γ-aminobutyric acid type A (GABA(A) ) receptor subunit β2. METHODS: We recruited and systematically evaluated 25 individuals with variants in GABRB2, 17 of whom are newly described and 8 previously reported with additional clinical data. Functional analysis was performed using a Xenopus laevis oocyte model system. RESULTS: Our cohort of 25 individuals from 22 families with variants in GABRB2 demonstrated a range of epilepsy phenotypes from genetic generalized epilepsy to developmental and epileptic encephalopathy. Fifty-eight percent of individuals had pharmacoresistant epilepsy; response to medications targeting the GABAergic pathway was inconsistent. Developmental disability (present in 84%) ranged from mild intellectual disability to severe global disability; movement disorders (present in 44%) included choreoathetosis, dystonia, and ataxia. Disease-associated variants cluster in the extracellular N-terminus and transmembrane domains 1-3, with more severe phenotypes seen in association with variants in transmembrane domains 1 and 2 and the allosteric binding site between transmembrane domains 2 and 3. Functional analysis of 4 variants in transmembrane domains 1 or 2 (p.Ile246Thr, p.Pro252Leu, p.Ile288Ser, p.Val282Ala) revealed strongly reduced amplitudes of GABA-evoked anionic currents. INTERPRETATION: GABRB2-related epilepsy ranges broadly in severity from genetic generalized epilepsy to developmental and epileptic encephalopathies. Developmental disability and movement disorder are key features. The phenotypic spectrum is comparable to other GABA(A) receptor-encoding genes. Phenotypic severity varies by protein domain. Experimental evidence supports loss of GABAergic inhibition as the mechanism underlying GABRB2-associated neurodevelopmental disorders. ANN NEUROL 2021;89:573-586.

Published
2021

10. Kv3.1 channelopathy: a novel loss-of-function variant and the mechanistic basis of its clinical phenotypes

Author

Li, X, Zheng, Y, Li, S, Nair, U, Sun, C, Zhao, C, Lu, J, Zhang, VW, Maljevic, S, Petrou, S, Lin, J, Li, X, Zheng, Y, Li, S, Nair, U, Sun, C, Zhao, C, Lu, J, Zhang, VW, Maljevic, S, Petrou, S, and Lin, J

Abstract

BACKGROUND: KCNC1 encodes Kv3.1, a subunit of the Kv3 voltage-gated potassium channels. It is predominantly expressed in inhibitory GABAergic interneurons and cerebellar neurons. Kv3.1 channelopathy has been linked to a variety of human diseases including epilepsy, developmental delay, and ataxia. Characterization of structural and functional disturbances of this channel, and its relationship to a heterogenous group of clinical phenotypes, is a current topic of research. We herein characterize the clinical phenotype as well as the functional and structural consequences of the novel KCNC1 p.R317S variant. We further set out to explore the mechanistic basis for the spectrum of KCNC1 related channelopathies. METHODS: Variant was identified via whole-exome sequencing and its functional impact was determined using two-electrode voltage clamp recordings in Xenopus laevis oocytes. Homolog modeling and in silico structural analysis were performed on the p.R317S variant and other KCNC1 related variants. RESULTS: We identified a novel loss-of-function KCNC1 variant c.949C>A (p.R317S) presenting with symptoms similar to myoclonic epilepsy and ataxia due to potassium channel (MEAK), but with distinct radiological features. Functional analysis in the Xenopus laevis oocyte's expression system revealed that the current amplitudes were significantly decreased in the p.R317S variant compared to the wild type, indicating a dominant-negative effect. Atomic structural analysis of the KCNC1 related variants provided a possible mechanistic explanation for the heterogeneity in the clinical spectrum. CONCLUSIONS: We have identified the p.R317S loss-of-function variant in the KCNC1 gene, expanded the spectrum of potassium channelopathy and provided mechanistic insights into KCNC1 related disorders.

Published
2021

11. Genetic and Pharmacological Studies Reveal Acid Sensing Ion Channel 1a as a Novel Therapeutic Target Against Cardiac Ischaemia-Reperfusion Injury

Author

Redd, M, Scheuer, S, Saez, N, Yoshikawa, Y, Chiu, H, Gao, L, Hicks, M, Villanueva, J, Cuellar-Partida, G, Peart, J, Hoe, LS, Chen, X, Sun, Y, Suen, J, Hatch, R, Rollo, B, Alzubaidi, M, Maljevic, S, Quaife-Ryan, G, Hudson, J, Porrello, E, White, M, Cordwell, S, Fraser, J, Petrou, S, Reichelt, M, Thomas, W, King, G, Macdonald, P, Palpant, N, Redd, M, Scheuer, S, Saez, N, Yoshikawa, Y, Chiu, H, Gao, L, Hicks, M, Villanueva, J, Cuellar-Partida, G, Peart, J, Hoe, LS, Chen, X, Sun, Y, Suen, J, Hatch, R, Rollo, B, Alzubaidi, M, Maljevic, S, Quaife-Ryan, G, Hudson, J, Porrello, E, White, M, Cordwell, S, Fraser, J, Petrou, S, Reichelt, M, Thomas, W, King, G, Macdonald, P, and Palpant, N

Published
2021

12. Therapeutic Inhibition of Acid-Sensing Ion Channel 1a Recovers Heart Function After Ischemia-Reperfusion Injury.

Author

Redd, MA, Scheuer, SE, Saez, NJ, Yoshikawa, Y, Chiu, HS, Gao, L, Hicks, M, Villanueva, JE, Joshi, Y, Chow, CY, Cuellar-Partida, G, Peart, JN, See Hoe, LE, Chen, X, Sun, Y, Suen, JY, Hatch, RJ, Rollo, B, Xia, D, Alzubaidi, MAH, Maljevic, S, Quaife-Ryan, GA, Hudson, JE, Porrello, ER, White, MY, Cordwell, SJ, Fraser, JF, Petrou, S, Reichelt, ME, Thomas, WG, King, GF, Macdonald, PS, Palpant, NJ, Redd, MA, Scheuer, SE, Saez, NJ, Yoshikawa, Y, Chiu, HS, Gao, L, Hicks, M, Villanueva, JE, Joshi, Y, Chow, CY, Cuellar-Partida, G, Peart, JN, See Hoe, LE, Chen, X, Sun, Y, Suen, JY, Hatch, RJ, Rollo, B, Xia, D, Alzubaidi, MAH, Maljevic, S, Quaife-Ryan, GA, Hudson, JE, Porrello, ER, White, MY, Cordwell, SJ, Fraser, JF, Petrou, S, Reichelt, ME, Thomas, WG, King, GF, Macdonald, PS, and Palpant, NJ

Abstract

Background: Ischemia–reperfusion injury (IRI) is one of the major risk factors implicated in morbidity and mortality associated with cardiovascular disease. During cardiac ischemia, the buildup of acidic metabolites results in decreased intracellular and extracellular pH, which can reach as low as 6.0 to 6.5. The resulting tissue acidosis exacerbates ischemic injury and significantly affects cardiac function. Methods: We used genetic and pharmacologic methods to investigate the role of acid-sensing ion channel 1a (ASIC1a) in cardiac IRI at the cellular and whole-organ level. Human induced pluripotent stem cell–derived cardiomyocytes as well as ex vivo and in vivo models of IRI were used to test the efficacy of ASIC1a inhibitors as pre- and postconditioning therapeutic agents. Results: Analysis of human complex trait genetics indicates that variants in the ASIC1 genetic locus are significantly associated with cardiac and cerebrovascular ischemic injuries. Using human induced pluripotent stem cell–derived cardiomyocytes in vitro and murine ex vivo heart models, we demonstrate that genetic ablation of ASIC1a improves cardiomyocyte viability after acute IRI. Therapeutic blockade of ASIC1a using specific and potent pharmacologic inhibitors recapitulates this cardioprotective effect. We used an in vivo model of myocardial infarction and 2 models of ex vivo donor heart procurement and storage as clinical models to show that ASIC1a inhibition improves post-IRI cardiac viability. Use of ASIC1a inhibitors as preconditioning or postconditioning agents provided equivalent cardioprotection to benchmark drugs, including the sodium-hydrogen exchange inhibitor zoniporide. At the cellular and whole organ level, we show that acute exposure to ASIC1a inhibitors has no effect on cardiac ion channels regulating baseline electromechanical coupling and physiologic performance. Conclusions: Our data provide compelling evidence for a novel pharmacologic strategy involving ASIC1a blockade as

Published
2021

15. In Vitro Differentiated Human Stem Cell-Derived Neurons Reproduce Synaptic Synchronicity Arising during Neurodevelopment

Author

Rosa, F, Dhingra, A, Uysal, B, Mendis, GDC, Loeffler, H, Elsen, G, Mueller, S, Schwarz, N, Castillo-Lizardo, M, Cuddy, C, Becker, F, Heutink, P, Reid, CA, Petrou, S, Lerche, H, Maljevic, S, Rosa, F, Dhingra, A, Uysal, B, Mendis, GDC, Loeffler, H, Elsen, G, Mueller, S, Schwarz, N, Castillo-Lizardo, M, Cuddy, C, Becker, F, Heutink, P, Reid, CA, Petrou, S, Lerche, H, and Maljevic, S

Abstract

Neurons differentiated from induced pluripotent stem cells (iPSCs) typically show regular spiking and synaptic activity but lack more complex network activity critical for brain development, such as periodic depolarizations including simultaneous involvement of glutamatergic and GABAergic neurotransmission. We generated human iPSC-derived neurons exhibiting spontaneous oscillatory activity after cultivation of up to 6 months, which resembles early oscillations observed in rodent neurons. This behavior was found in neurons generated using a more "native" embryoid body protocol, in contrast to a "fast" protocol based on NGN2 overexpression. A comparison with published data indicates that EB-derived neurons reach the maturity of neurons of the third trimester and NGN2-derived neurons of the second trimester of human gestation. Co-culturing NGN2-derived neurons with astrocytes only led to a partial compensation and did not reliably induce complex network activity. Our data will help selection of the appropriate iPSC differentiation assay to address specific questions related to neurodevelopmental disorders.

Published
2020

16. Genetic and Pharmacological Studies Reveal Acid Sensing Ion Channel 1a as a Novel Therapeutic Target Against Cardiac Ischaemia-Reperfusion Injury

Author

Redd, M., primary, Scheuer, S., additional, Saez, N., additional, Yoshikawa, Y., additional, Chiu, H., additional, Gao, L., additional, Hicks, M., additional, Villanueva, J., additional, Cuellar-Partida, G., additional, Peart, J., additional, See Hoe, L., additional, Chen, X., additional, Sun, Y., additional, Suen, J., additional, Hatch, R., additional, Rollo, B., additional, Alzubaidi, M., additional, Maljevic, S., additional, Quaife-Ryan, G., additional, Hudson, J., additional, Porrello, E., additional, White, M., additional, Cordwell, S., additional, Fraser, J., additional, Petrou, S., additional, Reichelt, M., additional, Thomas, W., additional, King, G., additional, Macdonald, P., additional, and Palpant, N., additional

Published
2021
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17. SCN1A gain of function in early infantile encephalopathy

Author

Berecki, G, Bryson, A, Terhag, J, Maljevic, S, Gazina, E, Hill, SL, Petrou, S, Berecki, G, Bryson, A, Terhag, J, Maljevic, S, Gazina, E, Hill, SL, and Petrou, S

Abstract

OBJECTIVE: To elucidate the biophysical basis underlying the distinct and severe clinical presentation in patients with the recurrent missense SCN1A variant, p.Thr226Met. Patients with this variant show a well-defined genotype-phenotype correlation and present with developmental and early infantile epileptic encephalopathy that is far more severe than typical SCN1A Dravet syndrome. METHODS: Whole cell patch clamp and dynamic action potential clamp were used to study T226M Nav 1.1 channels expressed in mammalian cells. Computational modeling was used to explore the neuronal scale mechanisms that account for altered action potential firing. RESULTS: T226M channels exhibited hyperpolarizing shifts of the activation and inactivation curves and enhanced fast inactivation. Dynamic action potential clamp hybrid simulation showed that model neurons containing T226M conductance displayed a left shift in rheobase relative to control. At current stimulation levels that produced repetitive action potential firing in control model neurons, depolarization block and cessation of action potential firing occurred in T226M model neurons. Fully computationally simulated neuron models recapitulated the findings from dynamic action potential clamp and showed that heterozygous T226M models were also more susceptible to depolarization block. INTERPRETATION: From a biophysical perspective, the T226M mutation produces gain of function. Somewhat paradoxically, our data suggest that this gain of function would cause interneurons to more readily develop depolarization block. This "functional dominant negative" interaction would produce a more profound disinhibition than seen with haploinsufficiency that is typical of Dravet syndrome and could readily explain the more severe phenotype of patients with T226M mutation. Ann Neurol 2019;85:514-525.

Published
2019

18. Encephalopathies with KCNC1 variants: genotype-phenotype-functional correlations

Author

Cameron, JM, Maljevic, S, Nair, U, Aung, YH, Cogne, B, Bezieau, S, Blair, E, Isidor, B, Zweier, C, Reis, A, Koenig, MK, Maarup, T, Sarco, D, Afenjar, A, Huq, AHMM, Kukolich, M, de Villemeur, TB, Nava, C, Heron, B, Petrou, S, Berkovic, SF, Cameron, JM, Maljevic, S, Nair, U, Aung, YH, Cogne, B, Bezieau, S, Blair, E, Isidor, B, Zweier, C, Reis, A, Koenig, MK, Maarup, T, Sarco, D, Afenjar, A, Huq, AHMM, Kukolich, M, de Villemeur, TB, Nava, C, Heron, B, Petrou, S, and Berkovic, SF

Abstract

OBJECTIVE: To analyze clinical phenotypes associated with KCNC1 variants other than the Progressive Myoclonus Epilepsy-causing variant p.Arg320His, determine the electrophysiological functional impact of identified variants and explore genotype-phenotype-physiological correlations. METHODS: Ten cases with putative pathogenic variants in KCNC1 were studied. Variants had been identified via whole-exome sequencing or gene panel testing. Clinical phenotypic data were analyzed. To determine functional impact of variants detected in the Kv 3.1 channel encoded by KCNC1, Xenopus laevis oocyte expression system and automated two-electrode voltage clamping were used. RESULTS: Six unrelated patients had a Developmental and Epileptic Encephalopathy and a recurrent de novo variant p.Ala421Val (c.1262C > T). Functional analysis of p.Ala421Val revealed loss of function through a significant reduction in whole-cell current, but no dominant-negative effect. Three patients had a contrasting phenotype of Developmental Encephalopathy without seizures and different KCNC1 variants, all of which caused loss of function with reduced whole-cell currents. Evaluation of the variant p.Ala513Val (c.1538C > T) in the tenth case, suggested it was a variant of uncertain significance. INTERPRETATION: These are the first reported cases of Developmental and Epileptic Encephalopathy due to KCNC1 mutation. The spectrum of phenotypes associated with KCNC1 is now broadened to include not only a Progressive Myoclonus Epilepsy, but an infantile onset Developmental and Epileptic Encephalopathy, as well as Developmental Encephalopathy without seizures. Loss of function is a key feature, but definitive electrophysiological separation of these phenotypes has not yet emerged.

Published
2019

19. Using a Multiplex Nucleic Acid in situ Hybridization Technique to Determine HCN4 mRNA Expression in the Adult Rodent Brain

Author

Oyrer, J, Bleakley, LE, Richards, KL, Maljevic, S, Phillips, AM, Petrou, S, Nowell, CJ, Reid, CA, Oyrer, J, Bleakley, LE, Richards, KL, Maljevic, S, Phillips, AM, Petrou, S, Nowell, CJ, and Reid, CA

Abstract

Hyperpolarization-activated cyclic nucleotide-gated (HCN) channels carry a non-selective cationic conductance, I h , which is important for modulating neuron excitability. Four genes (HCN1-4) encode HCN channels, with each gene having distinct expression and biophysical profiles. Here we use multiplex nucleic acid in situ hybridization to determine HCN4 mRNA expression within the adult mouse brain. We take advantage of this approach to detect HCN4 mRNA simultaneously with either HCN1 or HCN2 mRNA and markers of excitatory (VGlut-positive) and inhibitory (VGat-positive) neurons, which was not previously reported. We have developed a Fiji-based analysis code that enables quantification of mRNA expression within identified cell bodies. The highest HCN4 mRNA expression was found in the habenula (medial and lateral) and the thalamus. HCN4 mRNA was particularly high in the medial habenula with essentially no co-expression of HCN1 or HCN2 mRNA. An absence of I h -mediated "sag" in neurons recorded from the medial habenula of knockout mice confirmed that HCN4 channels are the predominant subtype in this region. Analysis in the thalamus revealed HCN4 mRNA in VGlut2-positive excitatory neurons that was always co-expressed with HCN2 mRNA. In contrast, HCN4 mRNA was undetectable in the nucleus reticularis. HCN4 mRNA expression was high in a subset of VGat-positive cells in the globus pallidus external. The majority of these neurons co-expressed HCN2 mRNA while a smaller subset also co-expressed HCN1 mRNA. In the striatum, a small subset of large cells which are likely to be giant cholinergic interneurons co-expressed high levels of HCN4 and HCN2 mRNA. The amygdala, cortex and hippocampus expressed low levels of HCN4 mRNA. This study highlights the heterogeneity of HCN4 mRNA expression in the brain and provides a morphological framework on which to better investigate the functional roles of HCN4 channels.

Published
2019

20. Rare GABRA3 variants are associated with epileptic seizures, encephalopathy and dysmorphic features

Author

Niturad, C., Lev, D., Kalscheuer, V., Charzewska, A., Schubert, J., Lerman-Sagie, T., Kroes, H., Oegema, R., Traverso, M., Specchio, N., Lassota, M., Chelly, J., Bennett-Back, O., Carmi, N., Koffler-Brill, T., Iacomino, M., Trivisano, M., Capovilla, G., Striano, P., Nawara, M., Rzonca, S., Fischer, U., Bienek, M., Jensen, C., Hu, H., Thiele, H., Altmüller, J., Krause, R., May, P., Becker, F., Euro, E., Balling, R., Biskup, S., Haas, S., Nürnberg, P., van Gassen, K., Lerche, H., Zara, F., Maljevic, S., and Leshinsky-Silver, E.

Abstract

Genetic epilepsies are caused by mutations in a range of different genes, many of them encoding ion channels, receptors or transporters. While the number of detected variants and genes increased dramatically in the recent years, pleiotropic effects have also been recognized, revealing that clinical syndromes with various degrees of severity arise from a single gene, a single mutation, or from different mutations showing similar functional defects. Accordingly, several genes coding for GABAA receptor subunits have been linked to a spectrum of benign to severe epileptic disorders and it was shown that a loss of function presents the major correlated pathomechanism. Here, we identified six variants in GABRA3 encoding the alpha3-subunit of the GABAA receptor. This gene is located on chromosome Xq28 and has not been previously associated with human disease. Five missense variants and one microduplication were detected in four families and two sporadic cases presenting with a range of epileptic seizure types, a varying degree of intellectual disability and developmental delay, sometimes with dysmorphic features or nystagmus. The variants co-segregated mostly but not completely with the phenotype in the families, indicating in some cases incomplete penetrance, involvement of other genes, or presence of phenocopies. Overall, males were more severely affected and there were three asymptomatic female mutation carriers compared to only one male without a clinical phenotype. X-chromosome inactivation studies could not explain the phenotypic variability in females. Three detected missense variants are localized in the extracellular GABA-binding NH2-terminus, one in the M2-M3 linker and one in the M4 transmembrane segment of the alpha3-subunit. Functional studies in Xenopus laevis oocytes revealed a variable but significant reduction of GABA-evoked anion currents for all mutants compared to wild-type receptors. The degree of current reduction correlated partially with the phenotype. The microduplication disrupted GABRA3 expression in fibroblasts of the affected patient. In summary, our results reveal that rare loss-of-function variants in GABRA3 increase the risk for a varying combination of epilepsy, intellectual disability/developmental delay and dysmorphic features, presenting in some pedigrees with an X-linked inheritance pattern.

Published
2017

21. Gain-of-function HCN2 variants in genetic epilepsy

Author

Li, M, Maljevic, S, Phillips, AM, Petrovski, S, Hildebrand, MS, Burgess, R, Mount, T, Zara, F, Striano, P, Schubert, J, Thiele, H, Nuernberg, P, Wong, M, Weisenberg, JL, Thio, LL, Lerche, H, Scheffer, IE, Berkovic, SF, Petrou, S, Reid, CA, Li, M, Maljevic, S, Phillips, AM, Petrovski, S, Hildebrand, MS, Burgess, R, Mount, T, Zara, F, Striano, P, Schubert, J, Thiele, H, Nuernberg, P, Wong, M, Weisenberg, JL, Thio, LL, Lerche, H, Scheffer, IE, Berkovic, SF, Petrou, S, and Reid, CA

Abstract

Genetic generalized epilepsy (GGE) is a common epilepsy syndrome that encompasses seizure disorders characterized by spike-and-wave discharges (SWDs). Pacemaker hyperpolarization-activated cyclic nucleotide-gated channels (HCN) are considered integral to SWD genesis, making them an ideal gene candidate for GGE. We identified HCN2 missense variants from a large cohort of 585 GGE patients, recruited by the Epilepsy Phenome-Genome Project (EPGP), and performed functional analysis using two-electrode voltage clamp recordings from Xenopus oocytes. The p.S632W variant was identified in a patient with idiopathic photosensitive occipital epilepsy and segregated in the family. This variant was also independently identified in an unrelated patient with childhood absence seizures from a European cohort of 238 familial GGE cases. The p.V246M variant was identified in a patient with photo-sensitive GGE and his father diagnosed with juvenile myoclonic epilepsy. Functional studies revealed that both p.S632W and p.V246M had an identical functional impact including a depolarizing shift in the voltage dependence of activation that is consistent with a gain-of-function. In contrast, no biophysical changes resulted from the introduction of common population variants, p.E280K and p.A705T, and the p.R756C variant from EPGP that did not segregate with disease. Our data suggest that HCN2 variants can confer susceptibility to GGE via a gain-of-function mechanism.

Published
2018

22. Development of a rapid functional assay that predicts GLUT1 disease severity

Author

Zaman, SM, Mullen, SA, Petrovski, S, Maljevic, S, Gazina, E, Phillips, AM, Jones, GD, Hildebrand, MS, Damiano, J, Auvin, S, Lerche, H, Weber, YG, Berkovic, SF, Scheffer, IE, Reid, CA, Petrou, S, Zaman, SM, Mullen, SA, Petrovski, S, Maljevic, S, Gazina, E, Phillips, AM, Jones, GD, Hildebrand, MS, Damiano, J, Auvin, S, Lerche, H, Weber, YG, Berkovic, SF, Scheffer, IE, Reid, CA, and Petrou, S

Abstract

OBJECTIVE: To examine the genotype to phenotype connection in glucose transporter type 1 (GLUT1) deficiency and whether a simple functional assay can predict disease outcome from genetic sequence alone. METHODS: GLUT1 deficiency, due to mutations in SLC2A1, causes a wide range of epilepsies. One possible mechanism for this is variable impact of mutations on GLUT1 function. To test this, we measured glucose transport by GLUT1 variants identified in population controls and patients with mild to severe epilepsies. Controls were reference sequence from the NCBI and 4 population missense variants chosen from public reference control databases. Nine variants associated with epilepsies or movement disorders, with normal intellect in all individuals, formed the mild group. The severe group included 5 missense variants associated with classical GLUT1 encephalopathy. GLUT1 variants were expressed in Xenopus laevis oocytes, and glucose uptake was measured to determine kinetics (Vmax) and affinity (Km). RESULTS: Disease severity inversely correlated with rate of glucose transport between control (Vmax = 28 ± 5), mild (Vmax = 16 ± 3), and severe (Vmax = 3 ± 1) groups, respectively. Affinities of glucose binding in control (Km = 55 ± 18) and mild (Km = 43 ± 10) groups were not significantly different, whereas affinity was indeterminate in the severe group because of low transport rates. Simplified analysis of glucose transport at high concentration (100 mM) was equally effective at separating the groups. CONCLUSIONS: Disease severity can be partly explained by the extent of GLUT1 dysfunction. This simple Xenopus oocyte assay complements genetic and clinical assessments. In prenatal diagnosis, this simple oocyte glucose uptake assay could be useful because standard clinical assessments are not available.

Published
2018

23. Myoclonus Epilepsy and Ataxia due to KCNC1 Mutation: Analysis of 20 Cases and K plus Channel Properties

Author

Oliver, KL, Franceschetti, S, Milligan, CJ, Muona, M, Mandelstam, SA, Canafoglia, L, Boguszewska-Chachulska, AM, Korczyn, AD, Bisulli, F, Di Bonaventura, C, Ragona, F, Michelucci, R, Ben-Zeev, B, Straussberg, R, Panzica, F, Massano, J, Friedman, D, Crespel, A, Engelsen, BA, Andermann, F, Andermann, E, Spodar, K, Lasek-Bal, A, Riguzzi, P, Pasini, E, Tinuper, P, Licchetta, L, Gardella, E, Lindenau, M, Wulf, A, Moller, RS, Benninger, F, Afawi, Z, Rubboli, G, Reid, CA, Maljevic, S, Lerche, H, Lehesjoki, A-E, Petrou, S, Berkovic, SF, Oliver, KL, Franceschetti, S, Milligan, CJ, Muona, M, Mandelstam, SA, Canafoglia, L, Boguszewska-Chachulska, AM, Korczyn, AD, Bisulli, F, Di Bonaventura, C, Ragona, F, Michelucci, R, Ben-Zeev, B, Straussberg, R, Panzica, F, Massano, J, Friedman, D, Crespel, A, Engelsen, BA, Andermann, F, Andermann, E, Spodar, K, Lasek-Bal, A, Riguzzi, P, Pasini, E, Tinuper, P, Licchetta, L, Gardella, E, Lindenau, M, Wulf, A, Moller, RS, Benninger, F, Afawi, Z, Rubboli, G, Reid, CA, Maljevic, S, Lerche, H, Lehesjoki, A-E, Petrou, S, and Berkovic, SF

Abstract

OBJECTIVE: To comprehensively describe the new syndrome of myoclonus epilepsy and ataxia due to potassium channel mutation (MEAK), including cellular electrophysiological characterization of observed clinical improvement with fever. METHODS: We analyzed clinical, electroclinical, and neuroimaging data for 20 patients with MEAK due to recurrent KCNC1 p.R320H mutation. In vitro electrophysiological studies were conducted using whole cell patch-clamp to explore biophysical properties of wild-type and mutant KV 3.1 channels. RESULTS: Symptoms began at between 3 and 15 years of age (median = 9.5), with progressively severe myoclonus and rare tonic-clonic seizures. Ataxia was present early, but quickly became overshadowed by myoclonus; 10 patients were wheelchair-bound by their late teenage years. Mild cognitive decline occurred in half. Early death was not observed. Electroencephalogram (EEG) showed generalized spike and polyspike wave discharges, with documented photosensitivity in most. Polygraphic EEG-electromyographic studies demonstrated a cortical origin for myoclonus and striking coactivation of agonist and antagonist muscles. Magnetic resonance imaging revealed symmetrical cerebellar atrophy, which appeared progressive, and a prominent corpus callosum. Unexpectedly, transient clinical improvement with fever was noted in 6 patients. To explore this, we performed high-temperature in vitro recordings. At elevated temperatures, there was a robust leftward shift in activation of wild-type KV 3.1, increasing channel availability. INTERPRETATION: MEAK has a relatively homogeneous presentation, resembling Unverricht-Lundborg disease, despite the genetic and biological basis being quite different. A remarkable improvement with fever may be explained by the temperature-dependent leftward shift in activation of wild-type KV 3.1 subunit-containing channels, which would counter the loss of function observed for mutant channels, highlighting KCNC1 as a potential target for pre

Published
2017

24. Functional variants in HCN4 and CACNA1H may contribute to genetic generalized epilepsy.

Author

Becker, F, Reid, CA, Hallmann, K, Tae, H-S, Phillips, AM, Teodorescu, G, Weber, YG, Kleefuss-Lie, A, Elger, C, Perez-Reyes, E, Petrou, S, Kunz, WS, Lerche, H, Maljevic, S, Becker, F, Reid, CA, Hallmann, K, Tae, H-S, Phillips, AM, Teodorescu, G, Weber, YG, Kleefuss-Lie, A, Elger, C, Perez-Reyes, E, Petrou, S, Kunz, WS, Lerche, H, and Maljevic, S

Abstract

OBJECTIVE: Genetic generalized epilepsy (GGE) encompasses seizure disorders characterized by spike-and-wave discharges (SWD) originating within thalamo-cortical circuits. Hyperpolarization-activated (HCN) and T-type Ca2+ channels are key modulators of rhythmic activity in these brain regions. Here, we screened HCN4 and CACNA1H genes for potentially contributory variants and provide their functional analysis. METHODS: Targeted gene sequencing was performed in 20 unrelated familial cases with different subtypes of GGE, and the results confirmed in 230 ethnically matching controls. Selected variants in CACNA1H and HCN4 were functionally assessed in tsA201 cells and Xenopus laevis oocytes, respectively. RESULTS: We discovered a novel CACNA1H (p.G1158S) variant in two affected members of a single family. One of them also carried an HCN4 (p.P1117L) variant inherited from the unaffected mother. In a separate family, an HCN4 variant (p.E153G) was identified in one of several affected members. Voltage-clamp analysis of CACNA1H (p.G1158S) revealed a small but significant gain-of-function, including increased current density and a depolarizing shift of steady-state inactivation. HCN4 p.P1117L and p.G153E both caused a hyperpolarizing shift in activation and reduced current amplitudes, resulting in a loss-of-function. SIGNIFICANCE: Our results are consistent with a model suggesting cumulative contributions of subtle functional variations in ion channels to seizure susceptibility and GGE.

Published
2017

25. Models for discovery of targeted therapy in genetic epileptic encephalopathies

Author

Maljevic, S, Reid, CA, Petrou, S, Maljevic, S, Reid, CA, and Petrou, S

Abstract

Epileptic encephalopathies are severe disorders emerging in the first days to years of life that commonly include refractory seizures, various types of movement disorders, and different levels of developmental delay. In recent years, many de novo occurring variants have been identified in individuals with these devastating disorders. To unravel disease mechanisms, the functional impact of detected variants associated with epileptic encephalopathies is investigated in a range of cellular and animal models. This review addresses efforts to advance and use such models to identify specific molecular and cellular targets for the development of novel therapies. We focus on ion channels as the best-studied group of epilepsy genes. Given the clinical and genetic heterogeneity of epileptic encephalopathy disorders, experimental models that can reflect this complexity are critical for the development of disease mechanisms-based targeted therapy. The convergence of technological advances in gene sequencing, stem cell biology, genome editing, and high throughput functional screening together with massive unmet clinical needs provides unprecedented opportunities and imperatives for precision medicine in epileptic encephalopathies.

Published
2017

26. Genetics and differenzial developmental expression of the Na+ channel gene SCN2A reveal molecular correlates for early-onset (neonatal-infantile) seizures and late-onset episodic ataxia, myoclonus and pain

Author

Liao, Y, Deprez, L, Anttonen, AK, Maljevic, S, Claes, L, Hristova, D, Jordanova, A, Ala-Mello, S, Liukkonen, E, Gaily, E, Bellan-Koch, A, Blazevic, D, Schubert, S, Thomas, EA, Petrou, S, Ahonen, VE, De Joghe, P, Lehesejoki, AE, and Lerche, H

Published
2024
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33. Mutations in the sodium channel gene SCN2A cause neonatal epilepsy with late-onset episodic ataxia

Author

University of Helsinki, Clinicum, University of Helsinki, Research Programs Unit, University of Helsinki, Neuroscience Center, Schwarz, N., Hahn, A., Bast, T., Mueller, S., Loeffler, H., Maljevic, S., Gaily, E., Prehl, I., Biskup, S., Joensuu, T., Lehesjoki, A. -E., Neubauer, B. A., Lerche, H., Hedrich, U. B. S., University of Helsinki, Clinicum, University of Helsinki, Research Programs Unit, University of Helsinki, Neuroscience Center, Schwarz, N., Hahn, A., Bast, T., Mueller, S., Loeffler, H., Maljevic, S., Gaily, E., Prehl, I., Biskup, S., Joensuu, T., Lehesjoki, A. -E., Neubauer, B. A., Lerche, H., and Hedrich, U. B. S.

Abstract

Mutations in SCN2A cause epilepsy syndromes of variable severity including neonatal-infantile seizures. In one case, we previously described additional childhood-onset episodic ataxia. Here, we corroborate and detail the latter phenotype in three further cases. We describe the clinical characteristics, identify the causative SCN2A mutations and determine their functional consequences using whole-cell patch-clamping in mammalian cells. In total, four probands presented with neonatal-onset seizures remitting after five to 13 months. In early childhood, they started to experience repeated episodes of ataxia, accompanied in part by headache or back pain lasting minutes to several hours. In two of the new cases, we detected the novel mutation p.Arg1882Gly. While this mutation occurred de novo in both patients, one of them carries an additional known variant on the same SCN2A allele, inherited from the unaffected father (p.Gly1522Ala). Whereas p.Arg1882Gly alone shifted the activation curve by -4 mV, the combination of both variants did not affect activation, but caused a depolarizing shift of voltage-dependent inactivation, and a significant increase in Na+ current density and protein production. p.Gly1522Ala alone did not change channel gating. The third new proband carries the same de novo SCN2A gain-of-function mutation as our first published case (p.Ala263Val). Our findings broaden the clinical spectrum observed with SCN2A gain-of-function mutations, showing that fairly different biophysical mechanisms can cause a convergent clinical phenotype of neonatal seizures and later onset episodic ataxia.

Published
2016

34. Dominant KCNA2 mutation causes episodic ataxia and pharmacoresponsive epilepsy

Author

Corbett, MA, Bellows, ST, Li, M, Carroll, R, Micallef, S, Carvill, GL, Myers, CT, Howell, KB, Maljevic, S, Lerche, H, Gazina, EV, Mefford, HC, Bahlo, M, Berkovic, SF, Petrou, S, Scheffer, IE, Gecz, J, Corbett, MA, Bellows, ST, Li, M, Carroll, R, Micallef, S, Carvill, GL, Myers, CT, Howell, KB, Maljevic, S, Lerche, H, Gazina, EV, Mefford, HC, Bahlo, M, Berkovic, SF, Petrou, S, Scheffer, IE, and Gecz, J

Abstract

OBJECTIVE: To identify the genetic basis of a family segregating episodic ataxia, infantile seizures, and heterogeneous epilepsies and to study the phenotypic spectrum of KCNA2 mutations. METHODS: A family with 7 affected individuals over 3 generations underwent detailed phenotyping. Whole genome sequencing was performed on a mildly affected grandmother and her grandson with epileptic encephalopathy (EE). Segregating variants were filtered and prioritized based on functional annotations. The effects of the mutation on channel function were analyzed in vitro by voltage clamp assay and in silico by molecular modeling. KCNA2 was sequenced in 35 probands with heterogeneous phenotypes. RESULTS: The 7 family members had episodic ataxia (5), self-limited infantile seizures (5), evolving to genetic generalized epilepsy (4), focal seizures (2), and EE (1). They had a segregating novel mutation in the shaker type voltage-gated potassium channel KCNA2 (CCDS_827.1: c.765_773del; p.255_257del). A rare missense SCN2A (rs200884216) variant was also found in 2 affected siblings and their unaffected mother. The p.255_257del mutation caused dominant negative loss of channel function. Molecular modeling predicted repositioning of critical arginine residues in the voltage-sensing domain. KCNA2 sequencing revealed 1 de novo mutation (CCDS_827.1: c.890G>A; p.Arg297Gln) in a girl with EE, ataxia, and tremor. CONCLUSIONS: A KCNA2 mutation caused dominantly inherited episodic ataxia, mild infantile-onset seizures, and later generalized and focal epilepsies in the setting of normal intellect. This observation expands the KCNA2 phenotypic spectrum from EE often associated with chronic ataxia, reflecting the marked variation in severity observed in many ion channel disorders.

Published
2016

35. Employing state-of-the-art technology to explore mechanisms of epilepsy and novel therapeutic options

Author

Wuttke, TV and Maljevic, S

Subjects
therapeutic options, ddc: 610, epilepsy, 610 Medical sciences, Medicine, pathophysiology
Abstract

Objective: Over the course of the last years several idiopathic epilepsy syndromes and more recently also epileptic encephalopathies have been linked to ion channel mutations. Numerous mutations (e.g. KV7 potassium channel mutations) have been analyzed in heterologous expression systems (for example[for full text, please go to the a.m. URL], 65. Jahrestagung der Deutschen Gesellschaft für Neurochirurgie (DGNC)

Published
2014
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36. DE NOVO LOSS- OR GAIN-OF-FUNCTION MUTATIONS IN KCNA2 CAUSE EPILEPTIC ENCEPHALOPATHY

Author

Syrbe, S., Hedrich, U., Riesch, E., Djemie, T., Mueller, S., Moller, R. S., Maher, B., Hernandez-Hernandez, L., Synofzik, M., Caglayan, H., Arslan, M., Serratosa, J., Nothnagel, M., May, P., Krause, R., Loeffler, H., Detert, K., Dorn, T., Vogt, H., Kraemer, G., Schoels, L., Mullis, P., Linnankivi, T., Lehesjoki, A. -E., Sterbova, K., Craiu, D., Hoffman-Zacharska, D., Korff, C., Weber, Y., Steinlin, M., Gallati, S., Bertsche, A., Bernhard, M., Merkenschlager, A., Kiess, W., Gonzalez, M., Zuechner, S., Palotie, A., Suls, A., De Jonghe, P., Helbig, I., Biskup, S., Wolff, M., Maljevic, S., Schuele, R., Sisodiya, S., Weckhuysen, S., Lerche, H., Lemke, J., Syrbe, S., Hedrich, U., Riesch, E., Djemie, T., Mueller, S., Moller, R. S., Maher, B., Hernandez-Hernandez, L., Synofzik, M., Caglayan, H., Arslan, M., Serratosa, J., Nothnagel, M., May, P., Krause, R., Loeffler, H., Detert, K., Dorn, T., Vogt, H., Kraemer, G., Schoels, L., Mullis, P., Linnankivi, T., Lehesjoki, A. -E., Sterbova, K., Craiu, D., Hoffman-Zacharska, D., Korff, C., Weber, Y., Steinlin, M., Gallati, S., Bertsche, A., Bernhard, M., Merkenschlager, A., Kiess, W., Gonzalez, M., Zuechner, S., Palotie, A., Suls, A., De Jonghe, P., Helbig, I., Biskup, S., Wolff, M., Maljevic, S., Schuele, R., Sisodiya, S., Weckhuysen, S., Lerche, H., and Lemke, J.

Published
2015

37. Mutations in the sodium channel gene SCN2A cause neonatal epilepsy with late-onset episodic ataxia

Author

Schwarz, N., primary, Hahn, A., additional, Bast, T., additional, Müller, S., additional, Löffler, H., additional, Maljevic, S., additional, Gaily, E., additional, Prehl, I., additional, Biskup, S., additional, Joensuu, T., additional, Lehesjoki, A.-E., additional, Neubauer, B. A., additional, Lerche, H., additional, and Hedrich, U. B. S., additional

Published
2015
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38. V28. KCNA2 mutations cause epileptic encephalopathy by gain- or loss-of channel function

Author

Hedrich, U.B.S., primary, Syrbe, S., additional, Riesch, E., additional, Djémié, T., additional, Müller, S., additional, Møller, R.S., additional, Maher, B., additional, Hernandez-Hernandez, L., additional, Synofzik, M., additional, Caglayan, H.S., additional, Arslan, M., additional, Serratosa, J., additional, Gonzalez, M., additional, Züchner, S., additional, Palotie, A., additional, Suls, A., additional, De Jonghe, P., additional, Helbig, I., additional, Biskup, S., additional, Wolff, M., additional, Maljevic, S., additional, Schuele-Freyer, R., additional, Sisodiya, S.M., additional, Weckhuysen, S., additional, Lerche, H., additional, and Lemke, J.R., additional

Published
2015
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40. Paroxysmal exercise-induced dyskinesia and epilepsy is due to mutations in SLC2A1, encoding the glucose transporter GLUT1

Author

Suls, A, Dedeken, P, Goffin, K, Van Esch, H, Dupont, P, Cassiman, D, Kempfle, J, Wuttke, TV, Weber, Y, Lerche, H, Afawi, Z, Vandenberghe, W, Korczyn, AD, Berkovic, SF, Ekstein, D, Kivity, S, Ryvlin, P, Claes, LRF, Deprez, L, Maljevic, S, Vargas, A, Van Dyck, T, Goossens, D, Del-Favero, J, Van Laere, K, De Jonghe, P, Paesschen, W, Suls, A, Dedeken, P, Goffin, K, Van Esch, H, Dupont, P, Cassiman, D, Kempfle, J, Wuttke, TV, Weber, Y, Lerche, H, Afawi, Z, Vandenberghe, W, Korczyn, AD, Berkovic, SF, Ekstein, D, Kivity, S, Ryvlin, P, Claes, LRF, Deprez, L, Maljevic, S, Vargas, A, Van Dyck, T, Goossens, D, Del-Favero, J, Van Laere, K, De Jonghe, P, and Paesschen, W

Abstract

Paroxysmal exercise-induced dyskinesia (PED) can occur in isolation or in association with epilepsy, but the genetic causes and pathophysiological mechanisms are still poorly understood. We performed a clinical evaluation and genetic analysis in a five-generation family with co-occurrence of PED and epilepsy (n = 39), suggesting that this combination represents a clinical entity. Based on a whole genome linkage analysis we screened SLC2A1, encoding the glucose transporter of the blood-brain-barrier, GLUT1 and identified heterozygous missense and frameshift mutations segregating in this and three other nuclear families with a similar phenotype. PED was characterized by choreoathetosis, dystonia or both, affecting mainly the legs. Predominant epileptic seizure types were primary generalized. A median CSF/blood glucose ratio of 0.52 (normal >0.60) in the patients and a reduced glucose uptake by mutated transporters compared with the wild-type as determined in Xenopus oocytes confirmed a pathogenic role of these mutations. Functional imaging studies implicated alterations in glucose metabolism in the corticostriate pathways in the pathophysiology of PED and in the frontal lobe cortex in the pathophysiology of epileptic seizures. Three patients were successfully treated with a ketogenic diet. In conclusion, co-occurring PED and epilepsy can be due to autosomal dominant heterozygous SLC2A1 mutations, expanding the phenotypic spectrum associated with GLUT1 deficiency and providing a potential new treatment option for this clinical syndrome.

Published
2008

42. Paroxysmal choreoathetosis/spasticity (DYT9) is caused by a GLUT1 defect

Author

Weber, Y. G., primary, Kamm, C., additional, Suls, A., additional, Kempfle, J., additional, Kotschet, K., additional, Schule, R., additional, Wuttke, T. V., additional, Maljevic, S., additional, Liebrich, J., additional, Gasser, T., additional, Ludolph, A. C., additional, Van Paesschen, W., additional, Schols, L., additional, De Jonghe, P., additional, Auburger, G., additional, and Lerche, H., additional

Published
2011
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43. Genetics and differenzial developmental expression of the Na+ channel gene SCN2A reveal molecular correlates for early-onset (neonatal-infantile) seizures and late-onset episodic ataxia, myoclonus and pain

Author

Liao, Y, primary, Deprez, L, additional, Anttonen, AK, additional, Maljevic, S, additional, Claes, L, additional, Hristova, D, additional, Jordanova, A, additional, Ala-Mello, S, additional, Liukkonen, E, additional, Gaily, E, additional, Bellan-Koch, A, additional, Blazevic, D, additional, Schubert, S, additional, Thomas, EA, additional, Petrou, S, additional, Ahonen, VE, additional, De Joghe, P, additional, Lehesejoki, AE, additional, and Lerche, H, additional

Published
2009
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46. Paroxysmal exercise-induced dyskinesia and epilepsy is due to mutations in SLC2A1, encoding the glucose transporter GLUT1

Author

Suls, A., primary, Dedeken, P., additional, Goffin, K., additional, Van Esch, H., additional, Dupont, P., additional, Cassiman, D., additional, Kempfle, J., additional, Wuttke, T. V., additional, Weber, Y., additional, Lerche, H., additional, Afawi, Z., additional, Vandenberghe, W., additional, Korczyn, A. D., additional, Berkovic, S. F., additional, Ekstein, D., additional, Kivity, S., additional, Ryvlin, P., additional, Claes, L. R. F., additional, Deprez, L., additional, Maljevic, S., additional, Vargas, A., additional, Van Dyck, T., additional, Goossens, D., additional, Del-Favero, J., additional, Van Laere, K., additional, De Jonghe, P., additional, and Van Paesschen, W., additional

Published
2008
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