Coordination of cellular activity through Ca2+ enables β cells to secrete precise quantities of insulin. To explore how the Ca2+ response is orchestrated in space and time, we implement optogenetic systems to probe the role of individual β cells in the glucose response. By targeted β cell activation/inactivation in zebrafish, we reveal a hierarchy of cells, each with a different level of influence over islet-wide Ca2+ dynamics. First-responder β cells lie at the top of the hierarchy, essential for initiating the first-phase Ca2+ response. Silencing first responders impairs the Ca2+ response to glucose. Conversely, selective activation of first responders demonstrates their increased capability to raise pan-islet Ca2+ levels compared to followers. By photolabeling and transcriptionally profiling β cells that differ in their thresholds to a glucose-stimulated Ca2+ response, we highlight vitamin B6 production as a signature pathway of first responders. We further define an evolutionarily conserved requirement for vitamin B6 in enabling the Ca2+ response to glucose in mammalian systems.
Institut(e)Institute for Pancreatic Beta Cell Research (IPI)
FörderungenCanadian Institutes of Health Research (CIHR) postdoctoral fellowship Award DFG - International Research Training Group Wellcome Trust Investigator Award UK MRC Programme Diabetes UK Project CRCHUM start-up funds, an Innovation Canada John R. Evans Leader Award NIH-NIDDK multi-PI project CIHR-JDRF Team DFG