Cav 1.3 channels play a crucial role in the formation of paroxysmal depolarization shifts in cultured hippocampal neurons

Victoria Stiglbauer; Matej Hotka; Manuel Ruiß; Karlheinz Hilber; Stefan Boehm; Helmut Kubista

doi:10.1111/epi.13719

Ca_v 1.3 channels play a crucial role in the formation of paroxysmal depolarization shifts in cultured hippocampal neurons

Epilepsia. 2017 May;58(5):858-871. doi: 10.1111/epi.13719. Epub 2017 Mar 11.

Authors

Victoria Stiglbauer¹, Matej Hotka¹, Manuel Ruiß¹, Karlheinz Hilber¹, Stefan Boehm¹, Helmut Kubista¹

Affiliation

¹ Department of Neurophysiology and Neuropharmacology, Center of Physiology and Pharmacology, Medical University of Vienna, Vienna, Austria.

Abstract

Objective: An increase of neuronal Ca_v 1.3 L-type calcium channels (LTCCs) has been observed in various animal models of epilepsy. However, LTCC inhibitors failed in clinical trials of epileptic treatment. There is compelling evidence that paroxysmal depolarization shifts (PDSs) involve Ca²⁺ influx through LTCCs. PDSs represent a hallmark of epileptiform activity. In recent years, a probable epileptogenic role for PDSs has been proposed. However, the implication of the two neuronal LTCC isoforms, Ca_v 1.2 and Ca_v 1.3, in PDSs remained unknown. Moreover, Ca²⁺ -dependent nonspecific cation (CAN) channels have also been suspected to contribute to PDSs. Nevertheless, direct experimental support of an important role of CAN channel activation in PDS formation is still lacking.

Methods: Primary neuronal networks derived from dissociated hippocampal neurons were generated from mice expressing a dihydropyridine-insensitive Ca_v 1.2 mutant (Ca_v 1.2DHP^-/- mice) or from Ca_v 1.3^-/- knockout mice. To investigate the role of Ca_v 1.2 and Ca_v 1.3, perforated patch-clamp recordings were made of epileptiform activity, which was elicited using either bicuculline or caffeine. LTCC activity was modulated using the dihydropyridines Bay K 8644 (agonist) and isradipine (antagonist).

Results: Distinct PDS could be elicited upon LTCC potentiation in Ca_v 1.2DHP^-/- neurons but not in Ca_v 1.3^-/- neurons. In contrast, when bicuculline led to long-lasting, seizure-like discharge events rather than PDS, these were prolonged in Ca_v 1.3^-/- neurons but not in Ca_v 1.2DHP^-/- neurons. Because only the Ca_v 1.2 isoform is functionally coupled to CAN channels in primary hippocampal networks, PDS formation does not require CAN channel activity.

Significance: Our data suggest that the LTCC requirement of PDS relates primarily to Ca_v 1.3 channels rather than to Ca_v 1.2 channels and CAN channels in hippocampal neurons. Hence, Ca_v 1.3 may represent a new therapeutic target for suppression of PDS development. The proposed epileptogenic role of PDSs may allow for a prophylactic rather than the unsuccessful seizure suppressing application of LTCC inhibitors.

Keywords: CAN channels; Epileptogenesis; L-type voltage-gated calcium channels; Primary cultured hippocampal neurons.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Animals
Calcium Channels, L-Type / physiology*
Evoked Potentials / physiology*
Hippocampus / physiopathology*
In Vitro Techniques
Mice
Mice, Inbred Strains
Nerve Net / physiopathology*
Neurons / physiology*
Patch-Clamp Techniques

Substances

Cacna1d protein, mouse
Calcium Channels, L-Type

Grants and funding

P 28179/FWF_/Austrian Science Fund FWF/Austria