Photopharmacological activation of adenosine A1receptor signaling suppresses seizures in a mouse model for temporal lobe epilepsy

Abstract

AbstractUp to 30% of epilepsy patients suffer from drug-resistant epilepsy (DRE). The search for innovative therapies is therefore important to close the existing treatment gap in these patients. The adenosinergic system possesses potent anticonvulsive effects, mainly through the adenosine A1receptor (A1R). However, clinical application of A1R agonists is hindered by severe systemic side effects. To achieve local modulation of A1Rs, we employed a photopharmacological approach using a caged version of the A1R agonist N6-cyclopentyladenosine, termed cCPA. We performed the firstin vivostudy with intracerebroventricularly (ICV) administered cCPA to investigate the potential to uncage sufficient amounts of cCPA in the hippocampus by local illumination in order to suppress hippocampal excitability and seizures in mice. Using hippocampal evoked potential recordings, we showed a reduction in hippocampal neurotransmission after photo-uncaging of cCPA, similar to that obtained with ICV injection of CPA. Furthermore, in the intrahippocampal kainic acid mouse model for DRE, photo-uncaging of CPA in the epileptic hippocampus resulted in a strong suppression of seizures. Finally, we demonstrated that intrahippocampal photo-uncaging of CPA resulted in less impairment of motor performance in the rotarod test compared to ICV administration of CPA. These results provide a proof of concept for photopharmacological A1R modulation as an effective precision treatment for DRE.