Quantitative characterization of the path of glucose diffusion facilitated by human glucose transporter 1

Glucose transporter GLUT1 is ubiquitously expressed in the human body from the red cells to the blood-brain barrier to the skeletal muscles. It is physiologically relevant to understand how GLUT1 facilitates diffusion of glucose across the cell membrane. It is also pathologically relevant because GL...

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Published in:Biochimica et biophysica acta. Biomembranes 2022-09, Vol.1864 (9), p.183975-183975, Article 183975
Main Author: Chen, Liao Y.
Format: Article
Language:English
Subjects:
Cell membrane
Erythrocyte
Free energy
Glucose transport
Molecular dynamics simulation
Transport
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Summary:Glucose transporter GLUT1 is ubiquitously expressed in the human body from the red cells to the blood-brain barrier to the skeletal muscles. It is physiologically relevant to understand how GLUT1 facilitates diffusion of glucose across the cell membrane. It is also pathologically relevant because GLUT1 deficiency causes neurological disorders and anemia and because GLUT1 overexpression fuels the abnormal growth of cancer cells. This article presents a quantitative investigation of GLUT1 based on all-atom molecular-dynamics (MD) simulations of the transporter embedded in lipid bilayers of asymmetric inner-and-outer-leaflet lipid compositions, subject to asymmetric intra-and-extra-cellular environments. This is in contrast with the current literature of MD studies that have not considered both of the aforementioned asymmetries of the cell membrane. The equilibrium (unbiased) dynamics of GLUT1 shows that it can facilitate glucose diffusion across the cell membrane without undergoing large-scale conformational motions. The Gibbs free-energy profile, which is still lacking in the current literature of GLUT1, quantitatively characterizes the diffusion path of glucose from the periplasm, through an extracellular gate of GLUT1, on to the binding site, and off to the cytoplasm. This transport mechanism is validated by the experimental data that GLUT1 has low water-permeability, uptake-efflux symmetry, and 10 kcal/mol Arrhenius activation barrier around 37 °C. [Display omitted] •Model system of two membrane patches asymmetric in EC and IC salines•Model RBC membrane asymmetric in inner and outer leaflet lipid compositions•EC-gating mechanism of GLUT1 in quantitative agreement with in vitro data on glucose transport and water permeation
ISSN:0005-2736
1879-2642
DOI:10.1016/j.bbamem.2022.183975