Cell Cycle Blockers Mimosine, Ciclopirox, and Deferoxamine Prevent the Death of PC12 Cells and Postmitotic Sympathetic Neurons After Removal of Trophic Support

Overview

Journal J Neurosci

Specialty Neurology

Date 1996 Feb 1

PMID 8558244

Citations 69

Authors

S E Farinelli

L A Greene

Affiliations

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Abstract

In the present study, we tested whether apoptotic neuronal death caused by withdrawal of trophic support might be prevented by agents that block cell cycle progression. We used three complementary model systems that exhibit apoptotic death: dividing PC12 cells deprived of nerve growth factor (NGF); and primary cultures of postmitotic sympathetic neurons deprived of NGF. We show that cell death in each case can be suppressed by treatment with the G1/S blockers mimosine, ciclopirox, and deferoxamine at concentrations that correlate with their abilities to block PC12 cell proliferation. In contrast, agents that block cell cycle progression in the S-, G2-, or M-phase do not prevent cell death. These observations support the hypothesis that removal of trophic support from dividing or postmitotic neuronal cells provokes their apoptotic death by causing them either to proceed through or to attempt to re-enter an uncoordinated and consequently fatal cell cycle. Moreover, the data suggest that simply blocking the cycle at any point is not protective but, rather, that it is necessary to block at specific "safe" points. This study defines a safe point in the cell cycle before the G1/S transition that is demarcated by the action of these three agents.

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