Bright calcium-modulated bioluminescent indicators for activity imaging and red photon-assisted synaptic transmission

ABSTRACT

Bioluminescent calcium sensors have unique uses in neuroscience and neuroengineering, enabling noninvasive imaging of neuronal activity and contactless activation of opsin-expressing neurons. However, the speed, range, and robustness of non-invasive imaging and rewiring or neuronal activity are limited by the radiance and dynamic range of existing bioluminescent calcium sensors. Here, we report the stepwise engineering of improved cyan-excitable red fluorescent proteins (mCyRFP4 and dCyRFP4), an improved red bioluminescent protein based on NanoLuc and CyRFP4 (Antares3), and an improved bioluminescent calcium sensor based on Antares3 (CaMBI3). Antares3 is 3-fold brighter than its predecessor, while CaMBI3 responds with an overall dynamic range of 24-fold, enabling high-sensitivity detection of calcium dynamics in muscle and neuronal tissues in vivo . Finally, a CaMBI3 variant and a red-shifted opsin ChRmine enabled red photon-assisted synaptic transmission in C. elegans . CaMBI3 thus facilitates genetically targeted non-invasive imaging and rewiring of neural activity in living animals.