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Targeting ischemia-induced KCC2 hypofunction rescues refractory neonatal seizures and mitigates epileptogenesis in a mouse model

Brennan J. Sullivan, Pavel A. Kipnis, Brandon M. Carter, Li‐Rong Shao, Shilpa D. Kadam

2021Science Signaling26 citationsDOIOpen Access PDF

Abstract

cotransporter 2 (KCC2), which maintains chloride homeostasis and promotes GABAergic inhibition upon its phosphorylation during postnatal development. Here, we investigated whether this mechanism is causal and whether it can be rescued by KCC2 functional enhancement. In a CD-1 mouse model of refractory ischemic neonatal seizures, treatment with the KCC2 functional enhancer CLP290 rescued phenobarbital efficacy, increased KCC2 abundance, and prevented the development of epileptogenesis, as quantified by video electroencephalogram monitoring. These effects were prevented by knock-in expression of nonphosphorylatable mutants of KCC2 (S940A or T906A and T1007A), indicating that KCC2 phosphorylation regulates both neonatal seizure susceptibility and CLP290-mediated KCC2 functional enhancement. Our findings therefore validate KCC2 as a clinically relevant target for refractory neonatal seizures and provide insights for future drug development.

Topics & Concepts

EpileptogenesisPhenobarbitalEpilepsyMedicineNeuroscienceGABAergicHypoxic Ischemic EncephalopathyPharmacologyEncephalopathyBioinformaticsInternal medicineBiologyReceptorNeuroscience and Neuropharmacology ResearchIon channel regulation and functionEpilepsy research and treatment