Quiescent fibroblasts exhibit high metabolic activity

Many cells in mammals exist in the state of quiescence, which is characterized by reversible exit from the cell cycle. Quiescent cells are widely reported to exhibit reduced size, nucleotide synthesis, and metabolic activity. Much lower glycolytic rates have been reported in quiescent compared with...

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Published in:PLoS biology 2010-10, Vol.8 (10), p.e1000514-e1000514
Main Authors: Lemons, Johanna M S, Feng, Xiao-Jiang, Bennett, Bryson D, Legesse-Miller, Aster, Johnson, Elizabeth L, Raitman, Irene, Pollina, Elizabeth A, Rabitz, Herschel A, Rabinowitz, Joshua D, Coller, Hilary A
Format: Article
Language:English
Subjects:
Animals
Apoptosis
Carbon - metabolism
Cell Biology/Cell Growth and Division
Cell Cycle
Cell Proliferation
Cells, Cultured
Citric Acid Cycle - physiology
Fatty acids
Fatty Acids - metabolism
Fibroblasts
Fibroblasts - cytology
Fibroblasts - metabolism
Genetic aspects
Glucose - metabolism
Glycolysis - physiology
Humans
Isotopes - metabolism
Medical research
Metabolism
Metabolites
Microbiology
Pentose Phosphate Pathway - physiology
Physiological aspects
Proteins
Synthesis
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Summary:Many cells in mammals exist in the state of quiescence, which is characterized by reversible exit from the cell cycle. Quiescent cells are widely reported to exhibit reduced size, nucleotide synthesis, and metabolic activity. Much lower glycolytic rates have been reported in quiescent compared with proliferating lymphocytes. In contrast, we show here that primary human fibroblasts continue to exhibit high metabolic rates when induced into quiescence via contact inhibition. By monitoring isotope labeling through metabolic pathways and quantitatively identifying fluxes from the data, we show that contact-inhibited fibroblasts utilize glucose in all branches of central carbon metabolism at rates similar to those of proliferating cells, with greater overflow flux from the pentose phosphate pathway back to glycolysis. Inhibition of the pentose phosphate pathway resulted in apoptosis preferentially in quiescent fibroblasts. By feeding the cells labeled glutamine, we also detected a "backwards" flux in the tricarboxylic acid cycle from α-ketoglutarate to citrate that was enhanced in contact-inhibited fibroblasts; this flux likely contributes to shuttling of NADPH from the mitochondrion to cytosol for redox defense or fatty acid synthesis. The high metabolic activity of the fibroblasts was directed in part toward breakdown and resynthesis of protein and lipid, and in part toward excretion of extracellular matrix proteins. Thus, reduced metabolic activity is not a hallmark of the quiescent state. Quiescent fibroblasts, relieved of the biosynthetic requirements associated with generating progeny, direct their metabolic activity to preservation of self integrity and alternative functions beneficial to the organism as a whole.
ISSN:1545-7885
1544-9173
1545-7885
DOI:10.1371/journal.pbio.1000514