High fidelity optogenetic control of individual prefrontal cortical pyramidal neurons in vivo

TL;DR

This paper demonstrates high-fidelity optogenetic control of specific prefrontal cortical neurons in vivo using novel viral tools, enabling precise activation or silencing of neurons with high temporal accuracy for behavioral studies.

Contribution

The study introduces and validates new AAV-based optogenetic tools for precise control of prefrontal pyramidal neurons in vivo, with high fidelity and temporal resolution.

Findings

Blue light induces reliable spiking at 20 Hz

Green light silences neurons with 100% fidelity

Tools enable targeted neural manipulation in behavioral experiments

Abstract

Precise spatial and temporal manipulation of neural activity in specific genetically defined cell populations is now possible with the advent of optogenetics. The emerging field of optogenetics consists of a set of naturally-occurring and engineered light-sensitive membrane proteins that are able to activate (e.g., channelrhodopsin-2, ChR2) or silence (e.g., halorhodopsin, NpHR) neural activity. Here we demonstrate the technique and the feasibility of using novel adeno-associated viral (AAV) tools to activate (AAV-CaMKll{\alpha}-ChR2-eYFP) or silence (AAV-CaMKll{\alpha}-eNpHR3.0-eYFP) neural activity of rat prefrontal cortical prelimbic (PL) pyramidal neurons in vivo. In vivo single unit extracellular recording of ChR2-transduced pyramidal neurons showed that delivery of brief (10 ms) blue (473 nm) light-pulse trains up to 20 Hz via a custom fiber optic-coupled recording electrode (optrode) induced spiking with high fidelity at 20 Hz for the duration of recording (up to two hours in some cases). To silence spontaneously active neurons we transduced them with the NpHR construct and administered continuous green (532 nm) light to completely inhibit action potential activity for up to 10 seconds with 100% fidelity in most cases. These versatile photosensitive tools combined with optrode recording methods provide experimental control over activity of genetically defined neurons and can be used to investigate the functional relationship between neural activity and complex cognitive behavior.