Steel Factor Regulates Cell Cycle Asymmetry

Asymmetric segregation of cell‐fate determinants during mitosis (spatial asymmetry) is an essential mechanism by which stem cells are maintained while simultaneously giving rise to differentiated progenitors that ultimately produce all the specialized cells in the hematopoietic system. Temporal cell...

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Bibliographic Details
Published in:Stem cells (Dayton, Ohio) Ohio), 2001-01, Vol.19 (6), p.483-491
Main Authors: Mantel, Charlie, Hendrie, Paul, Broxmeyer, Hal E.
Format: Article
Language:English
Subjects:
Cell Cycle - drug effects
Cell Cycle - physiology
Cell cycle heterogeneity
Cell Cycle Proteins - drug effects
Cell Cycle Proteins - metabolism
Cell Division - drug effects
Cyclin-Dependent Kinase Inhibitor p27
Drug Synergism
Granulocyte-Macrophage Colony-Stimulating Factor - pharmacology
Humans
P27kip‐1
Stem cell asymmetry
Stem cell factor
Stem Cell Factor - pharmacology
Time Factors
Tumor Cells, Cultured
Tumor Suppressor Proteins - drug effects
Tumor Suppressor Proteins - metabolism
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Summary:Asymmetric segregation of cell‐fate determinants during mitosis (spatial asymmetry) is an essential mechanism by which stem cells are maintained while simultaneously giving rise to differentiated progenitors that ultimately produce all the specialized cells in the hematopoietic system. Temporal cell cycle asymmetry and heterogeneity are attributes of cell proliferation that are also essential for maintaining tissue organization. Hematopoietic stem cells (HSCs) are regulated by a complex network of cytokines, some of which have very specific effects, while others have very broad ranging effects on HSCs. Some cytokines, like steel factor (SLF), are known to synergize with other cytokines to produce rapid expansion of progenitor cells. Using the human growth factor‐dependent MO7e cell line as a model for synergistic proliferation, we present evidence that links proliferation asymmetry to SLF synergy with GM‐CSF, and suggests that temporal asymmetry and cell cycle heterogeneity can be regulated by SLF in vitro. We also show that CDK‐inhibitor and cell cycle regulator, p27kip‐1, may be involved in this temporal asymmetry regulation. We propose that SLF/GM‐CSF synergy is, in part, due to a shift in proliferation pattern from a heterogeneous and asymmetric one to a more synchronous and symmetric pattern, thus contributing dramatically to the rapid expansion that accompanies SLF synergy observed in MO7e cells. This kinetic model of asymmetry is consistent with recent evidence showing that even though SLF synergy results in a strong proliferative signal, it does not increase primary HSC self‐renewal, which is believed to be highly dependent on asymmetric divisions. The factor‐dependent MO7e/SCF‐ synergy/asymmetry model described here may therefore be useful for studies of the effects of various cytokines on cell cycle asymmetry.
ISSN:1066-5099
1549-4918
DOI:10.1634/stemcells.19-6-483