Excess Glucose Impedes the Proliferation of Skeletal Muscle Satellite Cells Under Adherent Culture Conditions

Excess Glucose Impedes the Proliferation of Skeletal Muscle Satellite Cells Under Adherent Culture Conditions

Glucose is a major energy source consumed by proliferating mammalian cells. Therefore, in general, proliferating cells have the preference of high glucose contents in extracellular environment. Here, we showed that high glucose concentrations impede the proliferation of satellite cells, which are mu...

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Bibliographic Details
Published in:Frontiers in cell and developmental biology Vol. 9; p. 640399
Main Authors: Furuichi, Yasuro, Kawabata, Yuki, Aoki, Miho, Mita, Yoshitaka, Fujii, Nobuharu L, Manabe, Yasuko
Format: Journal Article
Language:English
Published: Switzerland Frontiers Media S.A 01-03-2021
Subjects:
Cell and Developmental Biology
glucose
primary culture
proliferation
satellite cell
self-renewal
glucose
satellite cell
proliferation
primary culture
self-renewal
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Summary:Glucose is a major energy source consumed by proliferating mammalian cells. Therefore, in general, proliferating cells have the preference of high glucose contents in extracellular environment. Here, we showed that high glucose concentrations impede the proliferation of satellite cells, which are muscle-specific stem cells, under adherent culture conditions. We found that the proliferation activity of satellite cells was higher in glucose-free DMEM growth medium (low-glucose medium with a glucose concentration of 2 mM) than in standard glucose DMEM (high-glucose medium with a glucose concentration of 19 mM). Satellite cells cultured in the high-glucose medium showed a decreased population of reserve cells, identified by staining for Pax7 expression, suggesting that glucose concentration affects cell fate determination. In conclusion, glucose is a factor that decides the cell fate of skeletal muscle-specific stem cells. Due to this unique feature of satellite cells, hyperglycemia may negatively affect the regenerative capability of skeletal muscle myofibers and thus facilitate sarcopenia.
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Edited by: Anthony Scimè, York University, Canada
Reviewed by: Joe Chakkalakal, University of Rochester, United States; Shihuan Kuang, Purdue University, United States
This article was submitted to Stem Cell Research, a section of the journal Frontiers in Cell and Developmental Biology
ISSN:2296-634X
2296-634X
DOI:10.3389/fcell.2021.640399