De Novo Loss-of-Function Mutations in CHD2 Cause a Fever-Sensitive Myoclonic Epileptic Encephalopathy Sharing Features with Dravet Syndrome

Suls, Arvid; Jaehn, Johanna A.; Kecskés, Angela; Weber, Yvonne G.; Weckhuysen, Sarah; Craiu, Dana; Siekierska, Aleksandra; Djémié, Tania; Afrikanova, Tatiana; Gormley, Padhraig; Spiczak, Sarah von; Kluger, Gerhard; Iliescu, Catrinel; Talvik, Tiina; Talvik, Inga; Meral, Cihan; Çağlayan, Hande; Giráldez, Beatriz G.; Serratosa, Joan; Lemke, Johannes R.; Hoffman-Zacharska, Dorota; Szczepanik, Elżbieta; Barišić, Nina; Komárek, Vladimı́r; Hjalgrim, Helle; Møller, Rikke S.; Linnankivi, Tarja; Dimova, Petia; Striano, Pasquale; Zara, Federico; Marini, Carla; Guerrini, Renzo; Depienne, Christel; Baulac, Stéphanie; Kuhlenbäumer, Gregor; Crawford, Alexander D.; Lehesjoki, Anna‐Elina; Witte, Peter de; Palotie, Aarno; Lerche, Holger; Esguerra, Camila V.; Jonghe, Peter De; Helbig, Ingo; Hendrickx, Rik; Holmgren, Philip; Stephani, Ulrich; Muhle, Hiltrud; Pendiziwiat, Manuela; Appenzeller, Silke; Selmer, Kaja Kristine; Brilstra, Eva H.; Koeleman, Bobby P. C.; Rosenow, Felix; LeGuern, Eric; Štěrbová, Katalin; Budişteanu, Magdalena; Rodica, Gherghiceanu; Arsene, Oana Tarta; Barca, Diana; Guerrero, Rosa; Ortega, Laura; Тодорова, Албена; Kirov, Andrey; Robbiano, Angela; Arslan, Mutluay; Yış, Uluç; Ivanović, Vanja

doi:10.1016/j.ajhg.2013.09.017

Cited by 190 publications

(181 citation statements)

References 34 publications

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“…Reports of genetically and chemically induced zebrafish models of epilepsy (reviewed in 19, 24, 37, 38), have established a number of behavioral paradigms that are used as metrics in this field. These measures are generally obtained at larval stages 3–7 dpf upon evoked or spontaneous swimming episodes 20, 21, 28, 39.…”

Section: Discussionmentioning

confidence: 99%

“…This phenotype could be measured automatically by movement quantification and therefore could represent an early screening parameter for hyperactivity in zebrafish. At later stages of larval development, extensive research on both drug‐induced and genetic models of epilepsy have revealed a stereotyped swimming characteristic of epileptogenic‐like activity, where individual larvae swim in a circular, corkscrew‐like trajectory 20, 22, 24. To describe this particular phenotype, we have quantified the rotational angle of the swimming trajectory and obtained a reliable metric for comparing the epilepsy‐like phenotypic features in zebrafish.…”

Section: Discussionmentioning

confidence: 99%

“…The first report of chemically induced seizures using the convulsant drug pentylenetetrazole (PTZ) documented stereotypical swimming abnormalities in 1‐week‐old larvae, consisting of circular trajectories, which correlated with increased synchronized neuronal activity in the zebrafish optic tectum as evidenced by field recordings 20. Subsequent studies have successfully reproduced these effects in genetic models of epilepsy in zebrafish 21, 22, 23, 24. Recently, a zebrafish homozygous null model for the mTOR regulator protein, TSC2, was reported to display epileptiform activity and defective locomotion responses,25 validating the use of this vertebrate model organism for epilepsies related to the mTOR pathway.…”

Section: Introductionmentioning

confidence: 99%

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Depdc5 knockdown causes mTOR‐dependent motor hyperactivity in zebrafish

Calbiac

Dabacan²,

Marsan

et al. 2018

Ann Clin Transl Neurol

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Objective DEPDC5 was identified as a major genetic cause of focal epilepsy with deleterious mutations found in a wide range of inherited forms of focal epilepsy, associated with malformation of cortical development in certain cases. Identification of frameshift, truncation, and deletion mutations implicates haploinsufficiency of DEPDC5 in the etiology of focal epilepsy. DEPDC5 is a component of the GATOR1 complex, acting as a negative regulator of mTOR signaling.MethodsZebrafish represents a vertebrate model suitable for genetic analysis and drug screening in epilepsy‐related disorders. In this study, we defined the expression of depdc5 during development and established an epilepsy model with reduced Depdc5 expression.ResultsHere we report a zebrafish model of Depdc5 loss‐of‐function that displays a measurable behavioral phenotype, including hyperkinesia, circular swimming, and increased neuronal activity. These phenotypic features persisted throughout embryonic development and were significantly reduced upon treatment with the mTORC1 inhibitor, rapamycin, as well as overexpression of human WT DEPDC5 transcript. No phenotypic rescue was obtained upon expression of epilepsy‐associated DEPDC5 mutations (p.Arg487* and p.Arg485Gln), indicating that these mutations cause a loss of function of the protein.InterpretationThis study demonstrates that Depdc5 knockdown leads to early‐onset phenotypic features related to motor and neuronal hyperactivity. Restoration of phenotypic features by WT but not epilepsy‐associated Depdc5 mutants, as well as by mTORC1 inhibition confirm the role of Depdc5 in the mTORC1‐dependent molecular cascades, defining this pathway as a potential therapeutic target for DEPDC5‐inherited forms of focal epilepsy.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Depdc5 knockdown causes mTOR‐dependent motor hyperactivity in zebrafish

Calbiac

Dabacan²,

Marsan

et al. 2018

Ann Clin Transl Neurol

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“…It combines easy handling and relatively high-throughput screening with the complexity of a whole vertebrate organism. Within the past decade, the usefulness of zebrafish in epilepsy research has been validated through studies involving pharmacologically induced acute seizure models [13][14][15] as well as zebrafish models of genetic epileptic syndromes (Angelman's [16], Lowe's [17], BNFC [18], EAST [19], and Dravet [20,21]). More recently, some of these zebrafish models have been applied in high-throughput epilepsy drug discovery (PTZ [22] and Dravet [20]).…”

Section: Introductionmentioning

confidence: 99%

Cross-species pharmacological characterization of the allylglycine seizure model in mice and larval zebrafish

Leclercq

Afrikanova

Langlois

et al. 2015

Epilepsy & Behavior

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Treatment-resistant seizures affect about a third of patients suffering from epilepsy. To fulfill the need for new medications targeting treatment-resistant seizures, a number of rodent models offer the opportunity to assess a variety of potential treatment approaches. The use of such models, however, has proven to be timeconsuming and labor-intensive. In this study, we performed pharmacological characterization of the allylglycine (AG) seizure model, a simple in vivo model for which we demonstrated a high level of treatment resistance. (D,L)-Allylglycine inhibits glutamic acid decarboxylase (GAD) -the key enzyme in γ-aminobutyric acid (GABA) biosynthesis -leading to GABA depletion, seizures, and neuronal damage. We performed a side-by-side comparison of mouse and zebrafish acute AG treatments including biochemical, electrographic, and behavioral assessments. Interestingly, seizure progression rate and GABA depletion kinetics were comparable in both species. Five mechanistically diverse antiepileptic drugs (AEDs) were used. Three out of the five AEDs (levetiracetam, phenytoin, and topiramate) showed only a limited protective effect (mainly mortality delay) at doses close to the TD 50 (dose inducing motor impairment in 50% of animals) in mice. The two remaining AEDs (diazepam and sodium valproate) displayed protective activity against AG-induced seizures. Experiments performed in zebrafish larvae revealed behavioral AED activity profiles highly analogous to those obtained in mice. Having demonstrated crossspecies similarities and limited efficacy of tested AEDs, we propose the use of AG in zebrafish as a convenient and high-throughput model of treatment-resistant seizures.

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“…Selecting phenotypically matched cases can thus enlarge the chance of finding independent variants in the same gene (eg, ref. 15).…”

Section: Ngs Findings In Mendelian Epilepsy Disordersmentioning

confidence: 99%

Lessons learned from gene identification studies in Mendelian epilepsy disorders

et al. 2015

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Next-generation sequencing (NGS) technologies are now routinely used for gene identification in Mendelian disorders. Setting up cost-efficient NGS projects and managing the large amount of variants remains, however, a challenging job. Here we provide insights in the decision-making processes before and after the use of NGS in gene identification studies. Genetic factors are thought to have a role in~70% of all epilepsies, and a variety of inheritance patterns have been described for seizure-associated gene defects. We therefore chose epilepsy as disease model and selected 35 NGS studies that focused on patients with a Mendelian epilepsy disorder. The strategies used for gene identification and their respective outcomes were reviewed. High-throughput NGS strategies have led to the identification of several new epilepsy-causing genes, enlarging our knowledge on both known and novel pathomechanisms. NGS findings have furthermore extended the awareness of phenotypical and genetic heterogeneity. By discussing recent studies we illustrate: (I) the power of NGS for gene identification in Mendelian disorders, (II) the accelerating pace in which this field evolves, and (III) the considerations that have to be made when performing NGS studies. Nonetheless, the enormous rise in gene discovery over the last decade, many patients and families included in gene identification studies still remain without a molecular diagnosis; hence, further genetic research is warranted. On the basis of successful NGS studies in epilepsy, we discuss general approaches to guide human geneticists and clinicians in setting up cost-efficient gene identification NGS studies.

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De Novo Loss-of-Function Mutations in CHD2 Cause a Fever-Sensitive Myoclonic Epileptic Encephalopathy Sharing Features with Dravet Syndrome

Cited by 190 publications

References 34 publications

Depdc5 knockdown causes mTOR‐dependent motor hyperactivity in zebrafish

Depdc5 knockdown causes mTOR‐dependent motor hyperactivity in zebrafish

Cross-species pharmacological characterization of the allylglycine seizure model in mice and larval zebrafish

Lessons learned from gene identification studies in Mendelian epilepsy disorders

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