Florey Department of Neuroscience and Mental Health - Theses
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ItemA platform for analysis of in vitro neuronal networks for the development of precision therapeutics in SCN2A disease( 2019)Background and Purpose Developmental and epileptic encephalopathies are a group of devastating neurological disorders in which the patients have developmental impairment as well as refractory seizures. Comorbid states are common and include cognitive and movement disorders. SCN2A, which encodes the brain sodium channel Nav1.2, has emerged as one of the most prominent developmental and epileptic encephalopathy genes. Based on the onset of disease, patients with SCN2A epilepsy variants can be divided into two major groups. In the early onset group, seizures start within the first three months of life, whereas in the second group, the onset is after three months of age. Sodium channel blockers such as phenytoin are effective in some of the early onset patients. In contrast phenytoin is ineffective and may in fact worsen seizure outcomes in late onset disease. This suggests different molecular pathomechanisms. The lack of efficacious therapies underscores an urgent need for novel treatment strategies. Experimental Approach Two knock-in mouse lines were generated carrying Scn2a p.R1883Q and p.R854Q variants corresponding to human SCN2A p.R1882Q and p.R853Q variants. These are the most common recurrent variants found in the early and the late onset group of SCN2A developmental and epileptic encephalopathies, respectively. In vitro signatures of neuronal network behaviour were assessed using multi-electrode array analysis of the primary cortical cultures obtained from postnatal day 0-1 animals carrying the respective variants up to 28 days in vitro. Acute pharmacological effects were evaluated around 22 days in vitro. Key Results After 2-4 weeks network analysis in culture showed increased activity for neurons harbouring the heterozygous p.R1882Q variant associated with early onset disease. Conversely, a decreased firing rate was observed in cultures in which neurons carried the heterozygous p.R853Q variant associated with late-onset disease. The excitability in both cultures was reduced by phenytoin, which resulted in shifting the p.R1882Q in vitro phenotype towards the wild types and p.R853Q away from the wild types, consistent with clinical observations. Interestingly, one of the tested antiepileptic drugs changed the activity of both cultures was towards the wild type phenotype indicating potential benefits of this drug for both early and late onset SCN2A developmental and epileptic encephalopathies. Conclusion and Implications The assumption that early onset SCN2A variants are more likely to cause gain-of-function and the late onset SCN2A variants to a loss-of-function of the Nav1.2 channel was confirmed for the two studied variants using in vitro neuronal cultures. Moreover, the clinical observations regarding the effectiveness of the sodium channel blocker phenytoin in patients with early and late onset seizures was corroborated by our in vitro models. Lastly, an antiepileptic drug was identified as a potential treatment for both early and late onset SCN2A developmental and epileptic encephalopathies.