Rapid, biochemical tagging of cellular activity history in vivo.
Run Zhang, Maribel Anguiano, Isak K Aarrestad, Sophia Lin, Joshua Chandra, Sruti S Vadde, David E Olson, Christina K Kim
bioRxiv : the preprint server for biology May 14, 2024 preprint DOI: 10.1101/2023.09.06.556431 via PubMed
Summary
An enzyme-catalyzed method called Ca2+-activated Split-TurboID (CaST) was developed to tag cells with elevated calcium levels in living organisms within 10 minutes. This approach allows for noninvasive monitoring of calcium activity, unlike traditional methods that require light delivery. The study demonstrated that CaST can effectively label activated neurons in the prefrontal cortex of untethered mice in response to psilocybin, correlating the labeling with head-twitch responses.
Study at a glance
| Population | untethered mice |
|---|---|
| Key finding | The CaST method can rapidly and noninvasively label neurons activated by psilocybin, correlating the signal with behavioral responses. |
Abstract
Intracellular calcium (Ca2+) is ubiquitous to cell signaling across all biology. While existing fluorescent sensors and reporters can detect activated cells with elevated Ca2+ levels, these approaches require implants to deliver light to deep tissue, precluding their noninvasive use in freely-behaving animals. Here we engineered an enzyme-catalyzed approach that rapidly and biochemically tags cells with elevated Ca2+ in vivo. Ca2+-activated Split-TurboID (CaST) labels activated cells within 10 minutes with an exogenously-delivered biotin molecule. The enzymatic signal increases with Ca2+ concentration and biotin labeling time, demonstrating that CaST is a time-gated integrator of total Ca2+ activity. Furthermore, the CaST read-out can be performed immediately after activity labeling, in contrast to transcriptional reporters that require hours to produce signal. These capabilities allowed us to apply CaST to tag prefrontal cortex neurons activated by psilocybin, and to correlate the CaST signal with psilocybin-induced head-twitch responses in untethered mice.