Abstract
Channelrhodopsin-2 (ChR2) has quickly gained popularity as a powerful tool for eliciting genetically targeted neuronal activation. However, little has been reported on the response kinetics of optogenetic stimulation across different neuronal subtypes. With excess stimulation, neurons can be driven into depolarization block, a state where they cease to fire action potentials. Herein, we demonstrate that light-induced depolarization block in neurons expressing ChR2 poses experimental challenges for stable activation of specific cell types and may confound interpretation of experiments when 'activated' neurons are in fact being functionally silenced. We show both ex vivo and in vivo that certain neuronal subtypes targeted for ChR2 expression become increasingly susceptible to depolarization block as the duration of light pulses are increased. We find that interneuron populations have a greater susceptibility to this effect than principal excitatory neurons, which are more resistant to light-induced depolarization block. Our results highlight the need to empirically determine the photo-response properties of targeted neurons when using ChR2, particularly in studies designed to elicit complex circuit responses in vivo where neuronal activity will not be recorded simultaneous to light stimulation. DOI: http://dx.doi.org/10.7554/eLife.01481.001.
Highlights
Optogenetics is a powerful emergent technology for investigating complex patterns of synaptic connectivity and circuit properties that underlie physiology and behavior
The first type of interneuron we investigated has been characterized by its expression of corticotropin-releasing hormone (CRH) (Taniguchi et al, 2011)
For olfactory bulb CRH interneurons, we observed that short duration (5–25 ms) light pulses (‘time on’) were optimal for sustaining consistent neuronal firing, with a highest average firing rate elicited at 10 ms pulse widths (Figure 1C)
Summary
Optogenetics is a powerful emergent technology for investigating complex patterns of synaptic connectivity and circuit properties that underlie physiology and behavior. Many variants of light-sensitive proteins are available for use towards the activation or inhibition of excitable cells (Lin, 2011; Rein and Deussing, 2012). Absorption of photons by the chromophore induces conformational changes in the channel that allow for the passage of cations across the cell membrane in which it is expressed (Boyden et al, 2005). This direct photo-gating makes ChR2 useful for manipulating neuronal activity in vitro
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