Chemogenetics with PSAM4-GlyR decreases excitability and epileptiform activity in epileptic hippocampus
Gonzalez-Ramos, Ana LU ; Berglind, Fredrik LU ; Kudláček, Jan LU ; Rocha, Elza R. ; Melin, Esbjörn LU
; Sebastião, Ana M.
; Valente, Cláudia A.
; Ledri, Marco
LU
; Andersson, My
LU
and Kokaia, Merab
LU
(2024)
In Gene Therapy
- Abstract
Despite the availability of new drugs on the clinics in recent years, drug-resistant epilepsy remains an unresolved challenge for healthcare, and one-third of epilepsy patients remain refractory to anti-seizure medications. Gene therapy in experimental models has emerged as effective treatment targeting specific neuronal populations in the epileptogenic focus. When combined with an external chemical activator using chemogenetics, it also becomes an “on-demand” treatment. Here, we evaluate a targeted and specific chemogenetic therapy, the PSAM/PSEM system, which holds promise as a potential candidate for clinical application in treating drug-resistant epilepsy. We show that the inert ligand uPSEM817, which selectively... (More)
Despite the availability of new drugs on the clinics in recent years, drug-resistant epilepsy remains an unresolved challenge for healthcare, and one-third of epilepsy patients remain refractory to anti-seizure medications. Gene therapy in experimental models has emerged as effective treatment targeting specific neuronal populations in the epileptogenic focus. When combined with an external chemical activator using chemogenetics, it also becomes an “on-demand” treatment. Here, we evaluate a targeted and specific chemogenetic therapy, the PSAM/PSEM system, which holds promise as a potential candidate for clinical application in treating drug-resistant epilepsy. We show that the inert ligand uPSEM817, which selectively activates the chloride-permeable channel PSAM4-GlyR, effectively reduces the number of depolarization-induced action potentials in vitro. This effect is likely due to the shunting of depolarizing currents, as evidenced by decreased membrane resistance in these cells. In organotypic slices, uPSEM817 decreased the number of bursts and peak amplitude of events of spontaneous epileptiform activity. Although administration of uPSEM817 in vivo did not significantly alter electrographic seizures in a male mouse model of temporal lobe epilepsy, it did demonstrate a strong trend toward reducing the frequency of interictal epileptiform discharges. These findings indicate that PSAM4-GlyR-based chemogenetics holds potential as an anti-seizure strategy, although further refinement is necessary to enhance its efficacy.
(Less)
- author
- Gonzalez-Ramos, Ana
LU
; Berglind, Fredrik
LU
; Kudláček, Jan
LU
; Rocha, Elza R.
; Melin, Esbjörn
LU
; Sebastião, Ana M.
; Valente, Cláudia A.
; Ledri, Marco
LU
; Andersson, My
LU
and Kokaia, Merab
LU
- organization
-
- Neurology, Lund
- Epilepsy Center
- Experimental Epilepsy Group (research group)
- Molecular Neurophysiology and Epilepsy group (research group)
- Brain Repair and Imaging in Neural Systems (BRAINS) (research group)
- LU Profile Area: Light and Materials
- LTH Profile Area: Nanoscience and Semiconductor Technology
- NanoLund: Centre for Nanoscience
- publishing date
- 2024
- type
- Contribution to journal
- publication status
- in press
- subject
- in
- Gene Therapy
- publisher
- Springer Nature
- external identifiers
-
- pmid:39455855
- scopus:85207366883
- ISSN
- 0969-7128
- DOI
- 10.1038/s41434-024-00493-7
- language
- English
- LU publication?
- yes
- id
- e5b20a68-fad6-4160-a15f-2d21b39d8d54
- date added to LUP
- 2025-01-13 15:31:05
- date last changed
- 2025-07-15 06:10:29
@article{e5b20a68-fad6-4160-a15f-2d21b39d8d54,
abstract = {{<p>Despite the availability of new drugs on the clinics in recent years, drug-resistant epilepsy remains an unresolved challenge for healthcare, and one-third of epilepsy patients remain refractory to anti-seizure medications. Gene therapy in experimental models has emerged as effective treatment targeting specific neuronal populations in the epileptogenic focus. When combined with an external chemical activator using chemogenetics, it also becomes an “on-demand” treatment. Here, we evaluate a targeted and specific chemogenetic therapy, the PSAM/PSEM system, which holds promise as a potential candidate for clinical application in treating drug-resistant epilepsy. We show that the inert ligand uPSEM<sup>817</sup>, which selectively activates the chloride-permeable channel PSAM<sup>4</sup>-GlyR, effectively reduces the number of depolarization-induced action potentials in vitro. This effect is likely due to the shunting of depolarizing currents, as evidenced by decreased membrane resistance in these cells. In organotypic slices, uPSEM<sup>817</sup> decreased the number of bursts and peak amplitude of events of spontaneous epileptiform activity. Although administration of uPSEM<sup>817</sup> in vivo did not significantly alter electrographic seizures in a male mouse model of temporal lobe epilepsy, it did demonstrate a strong trend toward reducing the frequency of interictal epileptiform discharges. These findings indicate that PSAM<sup>4</sup>-GlyR-based chemogenetics holds potential as an anti-seizure strategy, although further refinement is necessary to enhance its efficacy.</p>}},
author = {{Gonzalez-Ramos, Ana and Berglind, Fredrik and Kudláček, Jan and Rocha, Elza R. and Melin, Esbjörn and Sebastião, Ana M. and Valente, Cláudia A. and Ledri, Marco and Andersson, My and Kokaia, Merab}},
issn = {{0969-7128}},
language = {{eng}},
publisher = {{Springer Nature}},
series = {{Gene Therapy}},
title = {{Chemogenetics with PSAM<sup>4</sup>-GlyR decreases excitability and epileptiform activity in epileptic hippocampus}},
url = {{http://dx.doi.org/10.1038/s41434-024-00493-7}},
doi = {{10.1038/s41434-024-00493-7}},
year = {{2024}},
}