Abstract
The performance of available optogenetic inhibitors remains insufficient due to low light sensitivity, short-lasting photocurrents, and unintended changes in ion distributions. To overcome these limitations, a novel potassium channel-based optogenetic silencer was developed and successfully applied in various in vitro and acute in vivo settings (Bernal Sierra et al., 2018). This tool, a two-component construct called PACK, comprises a photoactivated adenylyl cyclase (bPAC) and a cAMP-dependent potassium channel (SthK). Here, we examined the long-term inhibitory action and side effects of the PACK construct in healthy and epileptic adult male mice. We targeted hippocampal CA1 pyramidal cells using a viral vector and enabled illumination of these neurons via an implanted optic fiber. Local field potential (LFP) recordings from the CA1 of freely moving mice revealed significantly reduced neuronal activity during 50-minute intermittent illumination, especially in the beta and gamma frequency ranges. Adversely, PACK expression in healthy mice induced chronic astrogliosis, dispersion of pyramidal cells, and generalized seizures. These side effects were independent of the light application and were also present in mice expressing bPAC without the potassium channel. Additionally, light-activation of bPAC alone increased neuronal activity, presumably via enhanced cAMP signaling. In chronically epileptic mice, the dark activity of bPAC/PACK in CA1 prevented the spread of spontaneous epileptiform activity from the seizure focus to the contralateral bPAC/PACK-expressing hippocampus. Taken together, the PACK tool is a potent optogenetic inhibitor but requires refinement of its light-sensitive domain to avoid unexpected physiological changes.
Significance statement Optogenetics allows precise manipulation of neuronal activity via genetically encoded light-sensitive proteins. Unfortunately, available optogenetic inhibitors are not suitable for prolonged use. The newly developed two-component potassium channel-based optogenetic inhibitor, PACK, has been identified as a potent silencer of neurons in various acute experiments. Here, we characterized the PACK construct in freely behaving healthy and epileptic mice. We targeted the PACK silencer specifically to CA1 pyramidal neurons, where illumination with short light pulses at low frequencies reliably reduced neuronal activity. In chronically epileptic mice, PACK prevented the spread of epileptiform activity from the seizure focus to the contralateral PACK-expressing hippocampus. The major disadvantage of the PACK silencer is its light-sensitive domain, the bPAC adenylyl cyclase, which may induce side effects.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
Conflict of interest statement: The authors declare no competing financial interests.
This study was supported by the German Research Foundation (HA 1443/11-1 to CAH, SPP1926 to YABS) and by the BrainLinks-BrainTools Center, which is funded by the Federal Ministry of Economics, Science and Arts of Baden-Württemberg within the sustainability program for projects of the Excellence Initiative II.