Curated Optogenetic Publication Database

Abstract: This study explores how the small GTPase RhoA modulates plasma membrane lipid nanodomains, particularly cholesterol-rich ordered membrane domains (OMDs). These nanodomains play a critical role in regulating ion channel activity and neuronal excitability. However, due to their nanoscale dimensions, OMDs remain challenging to visualize using conventional light microscopy. Here, we used fluorescently labeled cholera toxin B (CTxB) and the palmitoylated peptide Lck-10 (L10) as probes to visualize OMDs and quantified their size via confocal fluorescence lifetime imaging microscopy (FLIM)-based Förster resonance energy transfer (FRET). Pharmacological inhibition of RhoA significantly reduced OMD sizes in both human cell lines and dorsal root ganglion (DRG) neurons. To achieve better spatiotemporal control of specific RhoA activation, we employed an improved light-inducible dimerization (iLID) system. Optogenetic activation of RhoA rapidly increased FRET efficiency between CTxB probes, indicating OMD coalescence. Functionally, RhoA inhibition potentiated hyperpolarization-activated cyclic nucleotide-gated (HCN) channel activity in nociceptive DRG neurons, increasing spontaneous action potential firing. Conversely, in a spared nerve injury rat model, RhoA activation expanded OMDs in nociceptive DRG neurons. Constitutive RhoA activation suppressed HCN channel activity and decreased membrane excitability. These findings support a neuroprotective role for RhoA activation, where it restores OMD size and suppresses pathological hyperexcitability in neuropathic pain.

Abstract: Currently available inhibitory optogenetic tools provide short and transient silencing of neurons, but they cannot provide long-lasting inhibition because of the requirement for high light intensities. Here we present an optimized blue-light-sensitive synthetic potassium channel, BLINK2, which showed good expression in neurons in three species. The channel is activated by illumination with low doses of blue light, and in our experiments it remained active over (tens of) minutes in the dark after the illumination was stopped. This activation caused long periods of inhibition of neuronal firing in ex vivo recordings of mouse neurons and impaired motor neuron response in zebrafish in vivo. As a proof-of-concept application, we demonstrated that in a freely moving rat model of neuropathic pain, the activation of a small number of BLINK2 channels caused a long-lasting (>30 min) reduction in pain sensation.