A Hierarchical Whole-body Modeling Approach Elucidates the Link between in Vitro Insulin Signaling and in Vivo Glucose Homeostasis
Open Access
- 1 July 2011
- journal article
- research article
- Published by Elsevier BV in Journal of Biological Chemistry
- Vol. 286 (29), 26028-26041
- https://doi.org/10.1074/jbc.m110.188987
Abstract
Type 2 diabetes is a metabolic disease that profoundly affects energy homeostasis. The disease involves failure at several levels and subsystems and is characterized by insulin resistance in target cells and tissues (i.e. by impaired intracellular insulin signaling). We have previously used an iterative experimental-theoretical approach to unravel the early insulin signaling events in primary human adipocytes. That study, like most insulin signaling studies, is based on in vitro experimental examination of cells, and the in vivo relevance of such studies for human beings has not been systematically examined. Herein, we develop a hierarchical model of the adipose tissue, which links intracellular insulin control of glucose transport in human primary adipocytes with whole-body glucose homeostasis. An iterative approach between experiments and minimal modeling allowed us to conclude that it is not possible to scale up the experimentally determined glucose uptake by the isolated adipocytes to match the glucose uptake profile of the adipose tissue in vivo. However, a model that additionally includes insulin effects on blood flow in the adipose tissue and GLUT4 translocation due to cell handling can explain all data, but neither of these additions is sufficient independently. We also extend the minimal model to include hierarchical dynamic links to more detailed models (both to our own models and to those by others), which act as submodules that can be turned on or off. The resulting multilevel hierarchical model can merge detailed results on different subsystems into a coherent understanding of whole-body glucose homeostasis. This hierarchical modeling can potentially create bridges between other experimental model systems and the in vivo human situation and offers a framework for systematic evaluation of the physiological relevance of in vitro obtained molecular/cellular experimental data.Keywords
This publication has 43 references indexed in Scilit:
- Mass and Information Feedbacks through Receptor Endocytosis Govern Insulin Signaling as Revealed Using a Parameter-free Modeling FrameworkJournal of Biological Chemistry, 2010
- Grand challenges in systems physiologyFrontiers in Physiology, 2010
- Glucose Levels at the Site of Subcutaneous Insulin Administration and Their Relationship to Plasma LevelsDiabetes Care, 2010
- A Dynamic Analysis of IRS-PKR Signaling in Liver Cells: A Discrete Modeling ApproachPLOS ONE, 2009
- The crosstalk between EGF, IGF, and Insulin cell signaling pathways - computational and experimental analysisBMC Systems Biology, 2009
- Systems‐level interactions between insulin–EGF networks amplify mitogenic signalingMolecular Systems Biology, 2009
- Harmonic oscillator model of the insulin and IGF1 receptors’ allosteric binding and activationMolecular Systems Biology, 2009
- Model-Based Hypothesis Testing of Key Mechanisms in Initial Phase of Insulin SignalingPLoS Computational Biology, 2008
- Glucose transport and sensing in the maintenance of glucose homeostasis and metabolic harmonyJCI Insight, 2006
- Insulin Receptor Binding Kinetics: Modeling and Simulation StudiesJournal of Theoretical Biology, 2000