Abstract
Even brief epileptic seizures can lead to activity-dependent structural remodeling of neural circuitry. Animal models show that the functional plasticity of synapses and changes in the intrinsic excitability of neurons can be crucial for epileptogenesis. However, the exact mechanisms underlying epileptogenesis remain unclear. We induced epileptiform activity in rat hippocampal slices for 15 min using a 4-aminopyridine (4-AP) in vitro model and observed hippocampal hyperexcitability for at least 1 h. We tested several possible mechanisms of this hyperexcitability, including changes in intrinsic membrane properties of neurons and presynaptic and postsynaptic alterations. Neither input resistance nor other essential biophysical properties of hippocampal CA1 pyramidal neurons were affected by epileptiform activity. The glutamate release probability also remained unchanged, as the frequency of miniature EPSCs and the paired amplitude ratio of evoked responses did not change after epileptiform activity. However, we found an increase in the AMPA/NMDA ratio, suggesting alterations in the properties of postsynaptic glutamatergic receptors. Thus, the increase in excitability of hippocampal neural networks is realized through postsynaptic mechanisms. In contrast, the intrinsic membrane properties of neurons and the probability of glutamate release from presynaptic terminals are not affected in a 4-AP model.
Highlights
A significant number of cases of temporal lobe epilepsy in humans develop in healthy people as a result of injury or disease
This study investigated the short-term effects of epileptiform activity on synaptic and nonsynaptic plasticity in the hippocampus
Epileptiform activity in rat entorhinal-hippocampal slices was induced by 20-min exposure to the 4-AP-containing bath solution with altered extracellular ion concentrations (8.5 mM K+ ; 0.25 mM Mg2+ )
Summary
A significant number of cases of temporal lobe epilepsy in humans develop in healthy people as a result of injury or disease. It is crucial to know the initial molecular and cellular abnormalities specific to epileptogenesis. Based on this knowledge, more promising therapeutic strategies for the prevention of acquired temporal lobe epilepsy can be developed [2,3]. In vitro brain tissue preparations allow the simple and accessible study of brain networks and provide an opportunity to understand the brain’s molecular and cellular mechanisms of functioning in health and disease with detail that is unattainable in vivo. In vitro brain slices are generally recognized as an optimal model for studying epileptiform activity in the brain tissue [4]. GABA-mediated transmission paradoxically facilitates neuronal hyperexcitation in 4-AP-based epilepsy
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