Glucose sensing in the pancreatic beta cell: a computational systems analysis

<p>Abstract</p> <p>Background</p> <p>Pancreatic beta-cells respond to rising blood glucose by increasing oxidative metabolism, leading to an increased ATP/ADP ratio in the cytoplasm. This leads to a closure of K<sub>ATP </sub>channels, depolarization of the...

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Main Authors: Philipson Louis H, Fridlyand Leonid E
Format: Article
Language:English
Published: BMC 2010-05-01
Series:Theoretical Biology and Medical Modelling
Online Access:http://www.tbiomed.com/content/7/1/15
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spelling doaj-94272b2631a84958b7540d0ea9dd879c2020-11-25T00:09:33ZengBMCTheoretical Biology and Medical Modelling1742-46822010-05-01711510.1186/1742-4682-7-15Glucose sensing in the pancreatic beta cell: a computational systems analysisPhilipson Louis HFridlyand Leonid E<p>Abstract</p> <p>Background</p> <p>Pancreatic beta-cells respond to rising blood glucose by increasing oxidative metabolism, leading to an increased ATP/ADP ratio in the cytoplasm. This leads to a closure of K<sub>ATP </sub>channels, depolarization of the plasma membrane, influx of calcium and the eventual secretion of insulin. Such mechanism suggests that beta-cell metabolism should have a functional regulation specific to secretion, as opposed to coupling to contraction. The goal of this work is to uncover contributions of the cytoplasmic and mitochondrial processes in this secretory coupling mechanism using mathematical modeling in a systems biology approach.</p> <p>Methods</p> <p>We describe a mathematical model of beta-cell sensitivity to glucose. The cytoplasmic part of the model includes equations describing glucokinase, glycolysis, pyruvate reduction, NADH and ATP production and consumption. The mitochondrial part begins with production of NADH, which is regulated by pyruvate dehydrogenase. NADH is used in the electron transport chain to establish a proton motive force, driving the F<sub>1</sub>F<sub>0 </sub>ATPase. Redox shuttles and mitochondrial Ca<sup>2+ </sup>handling were also modeled.</p> <p>Results</p> <p>The model correctly predicts changes in the ATP/ADP ratio, Ca<sup>2+ </sup>and other metabolic parameters in response to changes in substrate delivery at steady-state and during cytoplasmic Ca<sup>2+ </sup>oscillations. Our analysis of the model simulations suggests that the mitochondrial membrane potential should be relatively lower in beta cells compared with other cell types to permit precise mitochondrial regulation of the cytoplasmic ATP/ADP ratio. This key difference may follow from a relative reduction in respiratory activity. The model demonstrates how activity of lactate dehydrogenase, uncoupling proteins and the redox shuttles can regulate beta-cell function in concert; that independent oscillations of cytoplasmic Ca<sup>2+ </sup>can lead to slow coupled metabolic oscillations; and that the relatively low production rate of reactive oxygen species in beta-cells under physiological conditions is a consequence of the relatively decreased mitochondrial membrane potential.</p> <p>Conclusion</p> <p>This comprehensive model predicts a special role for mitochondrial control mechanisms in insulin secretion and ROS generation in the beta cell. The model can be used for testing and generating control hypotheses and will help to provide a more complete understanding of beta-cell glucose-sensing central to the physiology and pathology of pancreatic <it>β</it>-cells.</p> http://www.tbiomed.com/content/7/1/15
collection DOAJ
language English
format Article
sources DOAJ
author Philipson Louis H
Fridlyand Leonid E
spellingShingle Philipson Louis H
Fridlyand Leonid E
Glucose sensing in the pancreatic beta cell: a computational systems analysis
Theoretical Biology and Medical Modelling
author_facet Philipson Louis H
Fridlyand Leonid E
author_sort Philipson Louis H
title Glucose sensing in the pancreatic beta cell: a computational systems analysis
title_short Glucose sensing in the pancreatic beta cell: a computational systems analysis
title_full Glucose sensing in the pancreatic beta cell: a computational systems analysis
title_fullStr Glucose sensing in the pancreatic beta cell: a computational systems analysis
title_full_unstemmed Glucose sensing in the pancreatic beta cell: a computational systems analysis
title_sort glucose sensing in the pancreatic beta cell: a computational systems analysis
publisher BMC
series Theoretical Biology and Medical Modelling
issn 1742-4682
publishDate 2010-05-01
description <p>Abstract</p> <p>Background</p> <p>Pancreatic beta-cells respond to rising blood glucose by increasing oxidative metabolism, leading to an increased ATP/ADP ratio in the cytoplasm. This leads to a closure of K<sub>ATP </sub>channels, depolarization of the plasma membrane, influx of calcium and the eventual secretion of insulin. Such mechanism suggests that beta-cell metabolism should have a functional regulation specific to secretion, as opposed to coupling to contraction. The goal of this work is to uncover contributions of the cytoplasmic and mitochondrial processes in this secretory coupling mechanism using mathematical modeling in a systems biology approach.</p> <p>Methods</p> <p>We describe a mathematical model of beta-cell sensitivity to glucose. The cytoplasmic part of the model includes equations describing glucokinase, glycolysis, pyruvate reduction, NADH and ATP production and consumption. The mitochondrial part begins with production of NADH, which is regulated by pyruvate dehydrogenase. NADH is used in the electron transport chain to establish a proton motive force, driving the F<sub>1</sub>F<sub>0 </sub>ATPase. Redox shuttles and mitochondrial Ca<sup>2+ </sup>handling were also modeled.</p> <p>Results</p> <p>The model correctly predicts changes in the ATP/ADP ratio, Ca<sup>2+ </sup>and other metabolic parameters in response to changes in substrate delivery at steady-state and during cytoplasmic Ca<sup>2+ </sup>oscillations. Our analysis of the model simulations suggests that the mitochondrial membrane potential should be relatively lower in beta cells compared with other cell types to permit precise mitochondrial regulation of the cytoplasmic ATP/ADP ratio. This key difference may follow from a relative reduction in respiratory activity. The model demonstrates how activity of lactate dehydrogenase, uncoupling proteins and the redox shuttles can regulate beta-cell function in concert; that independent oscillations of cytoplasmic Ca<sup>2+ </sup>can lead to slow coupled metabolic oscillations; and that the relatively low production rate of reactive oxygen species in beta-cells under physiological conditions is a consequence of the relatively decreased mitochondrial membrane potential.</p> <p>Conclusion</p> <p>This comprehensive model predicts a special role for mitochondrial control mechanisms in insulin secretion and ROS generation in the beta cell. The model can be used for testing and generating control hypotheses and will help to provide a more complete understanding of beta-cell glucose-sensing central to the physiology and pathology of pancreatic <it>β</it>-cells.</p>
url http://www.tbiomed.com/content/7/1/15
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