Curated Optogenetic Publication Database

Abstract: Photon upconversion (UC) from near-infrared (NIR) light to visible light has enabled optogenetic manipulations in deep tissues. However, materials for NIR optogenetics have been limited to inorganic UC nanoparticles. Extension to organic triplet-triplet annihilation (TTA)-based UC systems would innovate NIR optogenetics toward the use of biocompatible materials placed at a desired position. Here, we report the first example of NIR light-triggered optogenetics by using TTA-UC hydrogels. To achieve triplet sensitization even in the highly viscous hydrogel matrices, a NIR-absorbing complex is covalently linked with energy-pooling acceptor chromophores, which significantly elongates the donor triplet lifetime. The donor and acceptor are solubilized in hydrogels formed from biocompatible Pluronic F127 micelles, and we find that the additional heat treatment endows remarkable oxygen-tolerant property to the excited triplets in the hydrogel. Combined with photoactivatable Cre recombinase (PA-Cre) technology, NIR light stimulation successfully performs genome engineering such as hippocampal dendritic spine formation involved in learning and long-term memory.

Abstract: Dendritic spines are the major loci of synaptic plasticity and are considered as possible structural correlates of memory. Nonetheless, systematic manipulation of specific subsets of spines in the cortex has been unattainable, and thus, the link between spines and memory has been correlational. We developed a novel synaptic optoprobe, AS-PaRac1 (activated synapse targeting photoactivatable Rac1), that can label recently potentiated spines specifically, and induce the selective shrinkage of AS-PaRac1-containing spines. In vivo imaging of AS-PaRac1 revealed that a motor learning task induced substantial synaptic remodelling in a small subset of neurons. The acquired motor learning was disrupted by the optical shrinkage of the potentiated spines, whereas it was not affected by the identical manipulation of spines evoked by a distinct motor task in the same cortical region. Taken together, our results demonstrate that a newly acquired motor skill depends on the formation of a task-specific dense synaptic ensemble.