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Optogenetic polymerization and assembly of electrically functional polymers for modulation of single-neuron excitability

Chanan D. Sessler, Yiming Zhou, Wenbo Wang, Nolan D. Hartley, Zhanyan Fu, David Graykowski, Morgan Sheng, Xiao Wang, Jia Liu

2022Science Advances29 citationsDOIOpen Access PDF

Abstract

Ionic conductivity and membrane capacitance are two foundational parameters that govern neuron excitability. Conventional optogenetics has emerged as a powerful tool to temporarily manipulate membrane ionic conductivity in intact biological systems. However, no analogous method exists for precisely manipulating cell membrane capacitance to enable long-lasting modulation of neuronal excitability. Genetically targetable chemical assembly of conductive and insulating polymers can modulate cell membrane capacitance, but further development of this technique has been hindered by poor spatiotemporal control of the polymer deposition and cytotoxicity from the widely diffused peroxide. We address these issues by harnessing genetically targetable photosensitizer proteins to assemble electrically functional polymers in neurons with precise spatiotemporal control. Using whole-cell patch-clamp recordings, we demonstrate that this optogenetic polymerization can achieve stepwise modulation of both neuron membrane capacitance and intrinsic excitability. Furthermore, cytotoxicity can be limited by controlling light exposure, demonstrating a promising new method for precisely modulating cell excitability.

Topics & Concepts

OptogeneticsCapacitancePolymerizationNanotechnologyMembraneBiophysicsNeuronMaterials scienceMembrane potentialCell membranePolymerChemistryNeuroscienceElectrodeBiologyBiochemistryComposite materialPhysical chemistryPhotoreceptor and optogenetics researchNeuroscience and Neural EngineeringNeural dynamics and brain function
Optogenetic polymerization and assembly of electrically functional polymers for modulation of single-neuron excitability | Litcius