Publication
Epileptic pilocarpine-treated rats exhibit aberrant hippocampal EPSP-spike potentiation but retain long-term potentiation
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- Last modified
- 05/14/2025
- Type of Material
- Authors
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Ezekiel Carpenter-Hyland, Morehouse School of MedicineEdyta K. Bichler, Morehouse School of MedicineMatthew Smith, Emory UniversityRobert S. Sloviter, Morehouse School of MedicineMorris Benveniste, Morehouse School of Medicine
- Language
- English
- Date
- 2017-11
- Publisher
- The Physiological Society
- Publication Version
- Copyright Statement
- © 2017 The Authors. Physiological Reports published by Wiley Periodicals, Inc. on behalf of The Physiological Society and the American Physiological Society
- License
- Final Published Version (URL)
- Title of Journal or Parent Work
- Volume
- 5
- Issue
- 21
- Start Page
- e13490
- End Page
- e13490
- Grant/Funding Information
- This study has been funded by NINDS S11NS055883 and NIA SC1AG046907, (MB).
- Abstract
- Hippocampal neuron plasticity is strongly associated with learning, memory, and cognition. In addition to modification of synaptic function and connectivity, the capacity of hippocampal neurons to undergo plasticity involves the ability to change nonsynaptic excitability. This includes altering the probability that EPSPs will generate action potentials (E‐S plasticity). Epilepsy is a prevalent neurological disorder commonly associated with neuronal hyperexcitability and cognitive dysfunction. We examined E‐S plasticity in chronically epileptic Sprague–Dawley rats 3–10 weeks after pilocarpine‐induced status epilepticus. CA1 neurons in hippocampal slices were assayed by whole‐cell current clamp to measure EPSPs evoked by Schaffer collateral stimulation. Using a weak spike‐timing‐dependent protocol to induce plasticity, we found robust E‐S potentiation in conjunction with weak long‐term potentiation (LTP) in saline‐treated rats. In pilocarpine‐treated rats, a similar degree of LTP was found, but E‐S potentiation was reduced. Additionally, the degree of E‐S potentiation was not correlated with the degree of LTP for either group, suggesting that they independently contribute to neuronal plasticity. E‐S potentiation also differed from LTP in that E‐S plasticity could be induced solely from action potentials generated by postsynaptic current injection. The calcium chelating agent BAPTA in the intracellular solution blocked LTP and E‐S potentiation, revealing the calcium dependence of both processes. These findings suggest that LTP and E‐S potentiation have overlapping but nonidentical mechanisms of inducing neuronal plasticity that may independently contribute to cognitive disruptions observed in the chronic epileptic state.
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- Research Categories
- Biology, Neuroscience
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