Nature Communications (Aug 2023)

Reversal of cell, circuit and seizure phenotypes in a mouse model of DNM1 epileptic encephalopathy

  • Katherine Bonnycastle,
  • Katharine L. Dobson,
  • Eva-Maria Blumrich,
  • Akshada Gajbhiye,
  • Elizabeth C. Davenport,
  • Marie Pronot,
  • Moritz Steinruecke,
  • Matthias Trost,
  • Alfredo Gonzalez-Sulser,
  • Michael A. Cousin

DOI
https://doi.org/10.1038/s41467-023-41035-w
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 19

Abstract

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Abstract Dynamin-1 is a large GTPase with an obligatory role in synaptic vesicle endocytosis at mammalian nerve terminals. Heterozygous missense mutations in the dynamin-1 gene (DNM1) cause a novel form of epileptic encephalopathy, with pathogenic mutations clustering within regions required for its essential GTPase activity. We reveal the most prevalent pathogenic DNM1 mutation, R237W, disrupts dynamin-1 enzyme activity and endocytosis when overexpressed in central neurons. To determine how this mutation impacted cell, circuit and behavioural function, we generated a mouse carrying the R237W mutation. Neurons from heterozygous mice display dysfunctional endocytosis, in addition to altered excitatory neurotransmission and seizure-like phenotypes. Importantly, these phenotypes are corrected at the cell, circuit and in vivo level by the drug, BMS-204352, which accelerates endocytosis. Here, we demonstrate a credible link between dysfunctional endocytosis and epileptic encephalopathy, and importantly reveal that synaptic vesicle recycling may be a viable therapeutic target for monogenic intractable epilepsies.