Slow potentials encode intercellular coupling and insulin demand in pancreatic beta cells

Aims/hypothesis Ion fluxes constitute a major integrative signal in beta cells that leads to insulin secretion and regulation of gene expression. Understanding these electrical signals is important for deciphering the endogenous algorithms used by islets to attain homeostasis and for the design of n...

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Bibliographic Details
Published in:Diabetologia 2015-06, Vol.58 (6), p.1291-1299
Main Authors: Lebreton, Fanny, Pirog, Antoine, Belouah, Isma, Bosco, Domenico, Berney, Thierry, Meda, Paolo, Bornat, Yannick, Catargi, Bogdan, Renaud, Sylvie, Raoux, Matthieu, Lang, Jochen
Format: Article
Language:English
Subjects:
Algorithms
Animals
Cells, Cultured
Cellular Biology
Electrodes
Electrophysiological Phenomena
Engineering Sciences
Gene Deletion
Gene expression
Gene Expression Regulation
Glucagon
Glucose
Glucose - metabolism
Homeostasis
Hormones
Human Physiology
Humans
Insulin
Insulin - metabolism
Insulin-Secreting Cells - cytology
Internal Medicine
Ions
Life Sciences
Medicine
Medicine & Public Health
Metabolic Diseases
Metabolism
Metabolites
Mice
Mice, Inbred C57BL
Mice, Knockout
Micro and nanotechnologies
Microelectronics
Peptides
Potassium
Sensors
Signal Processing, Computer-Assisted
Signal Transduction
Subcellular Processes
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Summary:Aims/hypothesis Ion fluxes constitute a major integrative signal in beta cells that leads to insulin secretion and regulation of gene expression. Understanding these electrical signals is important for deciphering the endogenous algorithms used by islets to attain homeostasis and for the design of new sensors for monitoring beta cell function. Methods Mouse and human islets were cultured on multielectrode arrays (MEAs) for 3–13 days. Extracellular electrical activities received on each electrode were continuously amplified and recorded for offline characterisation. Results Differential band-pass filtering of MEA recordings of mouse islets showed two extracellular voltage waveforms: action potentials (lasting 40–60 ms) and very robust slow potentials (SPs, lasting 800–1,500 ms), the latter of which have not been described previously. The frequency of SPs directly correlated with glucose concentration, peaked at 10 mmol/l glucose and was further augmented by picomolar concentrations of glucagon-like peptide-1. SPs required the closure of ATP-dependent potassium channels as they were induced by glucose or glibenclamide but were not elicited by KCl-induced depolarisation. Pharmacological tools and the use of beta cell specific knockout mice showed that SPs reflected cell coupling via connexin 36. Moreover, increasing and decreasing glucose ramps showed hysteresis with reduced glucose sensitivity during the decreasing phase. SPs were also observed in human islets and could be continuously recorded over 24 h. Conclusions/interpretation This novel electrical signature reflects the syncytial function of the islets and is specific to beta cells. Moreover, the observed hysteresis provides evidence for an endogenous algorithm naturally present in islets to protect against hypoglycaemia.
ISSN:0012-186X
1432-0428
DOI:10.1007/s00125-015-3558-z