Mitochondrial turnover at central GABAergic synapses governs vulnerability to epileptic seizures

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Abstract

Mitochondrial dysfunction has long been known to underlie neurodegeneration, yet the contribution of mitochondrial turnover dynamics to functional aspects of defined synaptic circuits remains poorly understood. Here, we show that the mitochondrial proteome and turnover rates of hippocampal glutamatergic and GABAergic neurons is differentially remodelled by experience, with distal axon terminals of somatostatin-positive neurons exhibiting most dramatic changes, suggesting a form of metabolic plasticity at GABAergic synapses coupled to circuit activity. Conditional ablation of the mitochondrial transport proteins MIRO1 or TRAK1 (whose human mutations cause congenital epilepsy) stalled turnover at axon terminals driving loss of cristae, without affecting synapse or neuron integrity. The resulting reduction in synaptic GABA levels destabilized network oscillations and led to hyperexcitability, culminating in recurrent seizures and premature death. Post-weaning gene therapy efficiently reversed mitochondrial alterations and ameliorated the epileptic phenotype, underscoring the crucial role of mitochondrial turnover at central GABAergic synapses for balancing network excitability.

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