Single-cell metabolic imaging reveals a SLC2A3-dependent glycolytic burst in motile endothelial cells

Single-cell metabolic imaging reveals a SLC2A3-dependent glycolytic burst in motile endothelial cells

Single-cell motility is spatially heterogeneous and driven by metabolic energy. Directly linking cell motility to cell metabolism is technically challenging but biologically important. Here, we use single-cell metabolic imaging to measure glycolysis in individual endothelial cells with genetically e...

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Bibliographic Details
Published in:Nature metabolism Vol. 3; no. 5; pp. 714 - 727
Main Authors: Wu, David, Harrison, Devin L., Szasz, Teodora, Yeh, Chih-Fan, Shentu, Tzu-Pin, Meliton, Angelo, Huang, Ru-Ting, Zhou, Zhengjie, Mutlu, Gökhan M., Huang, Jun, Fang, Yun
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 01-05-2021
Subjects:
13/89
14/33
14/63
38/1
38/109
38/35
38/77
631/1647/245
631/443/319
631/80/128/2031
631/80/84/2341
64/60
692/4019/592
82/58
Biomarkers
Biomedical and Life Sciences
Cell Movement
Cells, Cultured
Computational Biology - methods
Cytoskeleton - metabolism
Endothelial Cells - metabolism
Endothelium, Vascular
Energy Metabolism
Glucose - metabolism
Glucose Transporter Type 3 - genetics
Glucose Transporter Type 3 - metabolism
Glycolysis
Humans
Life Sciences
Mechanical Phenomena
Models, Biological
Molecular Imaging - methods
rhoA GTP-Binding Protein - metabolism
Single-Cell Analysis - methods
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Summary:Single-cell motility is spatially heterogeneous and driven by metabolic energy. Directly linking cell motility to cell metabolism is technically challenging but biologically important. Here, we use single-cell metabolic imaging to measure glycolysis in individual endothelial cells with genetically encoded biosensors capable of deciphering metabolic heterogeneity at subcellular resolution. We show that cellular glycolysis fuels endothelial activation, migration and contraction and that sites of high lactate production colocalize with active cytoskeletal remodelling within an endothelial cell. Mechanistically, RhoA induces endothelial glycolysis for the phosphorylation of cofilin and myosin light chain in order to reorganize the cytoskeleton and thus control cell motility; RhoA activation triggers a glycolytic burst through the translocation of the glucose transporter SLC2A3/GLUT3 to fuel the cellular contractile machinery, as demonstrated across multiple endothelial cell types. Our data indicate that Rho-GTPase signalling coordinates energy metabolism with cytoskeleton remodelling to regulate endothelial cell motility. Wu, Harrison and colleagues visualize lactate production at subcellular resolution in migrating endothelial cells and identify hotspots of glycolytic activity, mediated by RhoA and the glucose transporter SLC2A3, that couple cellular energy metabolism with cytoskeleton remodelling and cell motility.
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D.W. and D.L.H. planned and executed experiments, analyzed data and interpreted results. T.S. analyzed data. C.Y., A.M., T-P.S., R.H., and Z.Z. performed experiments. J.H. and Y.F. planned experiments and interpreted results. G.M.M. helped design experiments. D.W., D.L.H., J.H., and Y.H. wrote and edited the manuscript.
Author contributions
ISSN:2522-5812
2522-5812
DOI:10.1038/s42255-021-00390-y