ClC3 Is a Critical Regulator of the Cell Cycle in Normal and Malignant Glial Cells

ClC3 Is a Critical Regulator of the Cell Cycle in Normal and Malignant Glial Cells

Although most brain cells are postmitotic, small populations of progenitor or stem cells can divide throughout life. These cells are believed to be the most likely source for primary brain malignancies including gliomas. Such tumors share many common features with nonmalignant glial cells but, becau...

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Bibliographic Details
Published in:The Journal of neuroscience Vol. 28; no. 37; pp. 9205 - 9217
Main Authors: Habela, Christa W, Olsen, Michelle L, Sontheimer, Harald
Format: Journal Article
Language:English
Published: United States Soc Neuroscience 10-09-2008
Society for Neuroscience
Subjects:
Analysis of Variance
Angiogenesis Inhibitors - pharmacology
Animals
Animals, Newborn
Cell Cycle - physiology
Cell Division - physiology
Cell Membrane - metabolism
Cell Size
Cells, Cultured
Chloride Channels - physiology
Chlorides - metabolism
Computer Simulation
DNA - metabolism
Gene Expression Regulation - drug effects
Gene Expression Regulation - physiology
Glioma - pathology
Glioma - physiopathology
Humans
Membrane Potentials - drug effects
Membrane Potentials - physiology
Models, Biological
Neuroglia - cytology
Neuroglia - physiology
Nitrobenzoates - pharmacology
Patch-Clamp Techniques - methods
Rats
Time Factors
Tubulin - metabolism
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Summary:Although most brain cells are postmitotic, small populations of progenitor or stem cells can divide throughout life. These cells are believed to be the most likely source for primary brain malignancies including gliomas. Such tumors share many common features with nonmalignant glial cells but, because of their insidious growth, form cancers that are typically incurable. In studying the growth regulation of these tumors, we recently discovered that glioma cell division is preceded by a cytoplasmic condensation that we called premitotic condensation (PMC). PMC represents an obligatory step in cell replication and is linked to chromatin condensation. If perturbed, the time required to complete a division is significantly prolonged. We now show that PMC is a feature shared more commonly among normal and malignant cells and that the reduction of cell volume is accomplished by Cl(-) efflux through ClC3 Cl(-) channels. Patch-clamp electrophysiology demonstrated a significant upregulation of chloride currents at M phase of the cell cycle. Colocalization studies and coimmunoprecipitation experiments showed the channel on the plasma membrane and at the mitotic spindle. To demonstrate a mechanistic role for ClC3 in PMC, we knocked down ClC3 expression using short hairpin RNA constructs. This resulted in a significant reduction of chloride currents at M phase that was associated with a decrease in the rate of PMC and a similar impairment of DNA condensation. These data suggest that PMC is an integral part of cell division and is dependent on ClC3 channel function.
ISSN:0270-6474
1529-2401
DOI:10.1523/JNEUROSCI.1897-08.2008