Kavli Affiliate: Yuh Nung Jan
| Authors: Jungwoo Wren Kim, Adeline J. H. Yong, Erin E. Aisenberg, Ted M. Dawson, Valina L. Dawson, Yuh-Nung Jan, Nicholas T. Ingolia, Wei Wang, Ruixuan Gao and Helen S. Bateup
| Summary:
Calcium ions serve as key intracellular signals. Local, transient increases in calcium concentrations can activate calcium sensor proteins that in turn trigger downstream effectors. In neurons, calcium transients play a central role in regulating neurotransmitter release and synaptic plasticity. However, it is challenging to capture the molecular events associated with these localized and ephemeral calcium signals. Here we present an engineered biotin ligase that combines the power of genetically encoded calcium indicators with protein proximity labeling. The enzyme, Cal-ID, biotinylates nearby proteins within minutes in response to elevated local calcium levels. The biotinylated proteins can be identified via mass spectrometry and visualized using microscopy. In neurons, Cal-ID labeling is triggered by neuronal activity, leading to prominent protein biotinylation that enables transcription-independent activity mapping in the brain. Cal-ID produces a biochemical record of calcium signaling and neuronal activity with high spatial resolution and molecular specificity.