1772-P: Alpha-Cell Heterogeneity Contributes to Phasic Glucagon Release

Abstract

Glucagon, produced by α-cells of pancreatic islets, is one of the body’s primary tools for elevating blood glucose during hypoglycemia. The exact mechanism linking hypoglycemia to glucagon release by islet α-cells is, however, unclear; we therefore aimed to investigate it using optogenetics. We generated mice harboring the light-activated ion channel channelrhodopsin-2 (ChR2) specifically in α-cells and imaged the effect of optically induced depolarization of plasma membrane (10-ms 470-nm light pulses at 20Hz) at the level of membrane potential, cytosolic Ca2+ ([Ca2+]i) and ATP/ADP ratio. At 1 mmol/L glucose, optostimulation depolarized the electrically active α-cells from -76mV to -8mV, induced a transient surge in [Ca2+]i and elevated glucagon secretion by 200%. In contrast, the glucagonostatic effect of high glucose (>6 mmol/L) was mitigated by optostimulation of α-cells. At 1 mmol/L glucose, the stimulatory effects were abolished by the KATP channel activator diazoxide (100μmol/L) and L-type Ca2+ channel blocker isradipine (10μmol/L). Notably, KATP channel inhibitor tolbutamide (100μmol/L) induced electrical activity in the fraction of α-cells insensitive to low glucose (35%). As stimulation of electrical activity persisted significantly beyond optoactivation, we probed the interplay between electrical activity and energy metabolism. The depolarizing stimulus induced by a cocktail of amino acids ((AA) 2 mmol/L of alanine + arginine +glutamine) or a moderate increase of extracellular K+ (from 4 to 15 mmol/L) reduced ATP/ADP in α-cells exhibiting spontaneous Ca2+ oscillations at low glucose. Surprisingly, in the population of inactive α-cells, the stimulation increased ATP/ADP ratio. These data indicate that α-cells are functionally heterogeneous due to metabolic differences. The observed secretory responses reflect the combination of stimulatory and inhibitory effects in electrically active and silent cells, which may contribute to the phasic nature of AA-induced glucagon secretion. Disclosure C.A.Miranda: None. H.Dou: None. J.Tolö: None. A.I.Tarasov: None. P.Rorsman: None. Funding Svenska Sällskapet för Medicinsk Forskning (PD20-0056); Swedish Vetenskap Rådet