Design Principles of Pancreatic Islets: Glucose-Dependent Coordination of Hormone Pulses

Overview

Journal PLoS One

Specialties General Medicine
Science

Date 2016 Apr 2

PMID 27035570

Citations 14

Authors

Danh-Tai Hoang

Manami Hara

Junghyo Jo

Affiliations

Soon will be listed here.

Abstract

Pancreatic islets are functional units involved in glucose homeostasis. The multicellular system comprises three main cell types; β and α cells reciprocally decrease and increase blood glucose by producing insulin and glucagon pulses, while the role of δ cells is less clear. Although their spatial organization and the paracrine/autocrine interactions between them have been extensively studied, the functional implications of the design principles are still lacking. In this study, we formulated a mathematical model that integrates the pulsatility of hormone secretion and the interactions and organization of islet cells and examined the effects of different cellular compositions and organizations in mouse and human islets. A common feature of both species was that islet cells produced synchronous hormone pulses under low- and high-glucose conditions, while they produced asynchronous hormone pulses under normal glucose conditions. However, the synchronous coordination of insulin and glucagon pulses at low glucose was more pronounced in human islets that had more α cells. When β cells were selectively removed to mimic diabetic conditions, the anti-synchronicity of insulin and glucagon pulses was deteriorated at high glucose, but it could be partially recovered when the re-aggregation of remaining cells was considered. Finally, the third cell type, δ cells, which introduced additional complexity in the multicellular system, prevented the excessive synchronization of hormone pulses. Our computational study suggests that controllable synchronization is a design principle of pancreatic islets.

Citing Articles

Mathematical modeling clarifies the paracrine roles of insulin and glucagon on the glucose-stimulated hormonal secretion of pancreatic alpha- and beta-cells.

Brown A, Tzanakakis E Front Endocrinol (Lausanne). 2023; 14:1212749.

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A primer on modelling pancreatic islets: from models of coupled β-cells to multicellular islet models.

Felix-Martinez G, Godinez-Fernandez J Islets. 2023; 15(1):2231609.

PMID: 37415423 PMC: 10332213. DOI: 10.1080/19382014.2023.2231609.

Pancreatic α and β cells are globally phase-locked.

Ren H, Li Y, Han C, Yu Y, Shi B, Peng X Nat Commun. 2022; 13(1):3721.

PMID: 35764654 PMC: 9240067. DOI: 10.1038/s41467-022-31373-6.

Determinants and dynamics of pancreatic islet architecture.

Adams M, Blum B Islets. 2022; 14(1):82-100.

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IsletLab: an application to reconstruct and analyze islet architectures.

Felix-Martinez G Islets. 2021; 14(1):36-39.

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