During continuous proliferation, cyclin D1 protein is induced to high levels in a Ras-dependent manner as cells progress from S phase to G2 phase. To understand the mechanism of the Ras-dependent cyclin D1 induction, cyclin D1 mRNA levels were determined by quantitative image analysis following fluorescent in situ hybridization. Although a slight increase in mRNA expression levels was detected during the S/G2 transition, this increase could not explain the more robust induction of cyclin D1 protein levels. This suggested the involvement of posttranscriptional regulation as a mechanism of cyclin D1 protein induction. To directly test this hypothesis, the cyclin D1 transcription rate was determined by run-on assays. The transcription rate of cyclin D1 stayed steady during the synchronous transition from S the G2 phase. We further demonstrated that cyclin D1 protein levels could increase during G2 phase in the absence of new mRNA synthesis. a-Amanitin, a transcription inhibitor, did not suppress cyclin D1 protein elevation as the cells progressed from S to G2 phase, even though the inhibitor was able to completely block cyclin D1 protein induction during reentry into the cell cycle from quiescence. The half life of cyclin D1 protein was shortest during S phase indicating that a change in protein stability might play a role in post-translational induction of cyclin D1 in G2 phase. These data indicate a fundamental difference in the regulation of cyclin D1 production during continuous cell cycle progression and re-initiation of the cell cycle. Oncogene (2002Oncogene ( ) 21, 7545 -7556. doi:10.1038 Keywords: cell cycle; Ras; cyclin D1; in situ hybridization; single cell-based analysis; post-transcriptional regulation
IntroductionCell cycle progression consists of multiple coordinated processes, including DNA duplication and chromosome segregation, to ensure accurate transfer of genetic information to daughter cells. To achieve this, cells are equipped with a variety of systems to sense unfavorable conditions for completing the cell cycle, such as lack of mitogens, low nutrient levels, DNA damage, disruption of the mitotic spindles, etc. Under such conditions, check points are activated and cell cycle progression is halted at specific points in the cell cycle (Pardee, 1989;Vogelstein et al., 2000). Some of these reversible checkpoints have been utilized to synchronize cells to study cell cycle regulation. To study the control of G1/S phase transition, for instance, mitogen deprivation-readdition is often employed. When mitogens are removed, mammalian fibroblast cells are arrested in a quiescent state, referred to as G0, with a G1 content of DNA. This withdrawal from the cell cycle may have physiological importance, because forced cell cycle progression in the absence of growth factors often results in apoptosis (Evan and Vousden, 2001). When mitogens are available again, the cells reenter into cell cycle. The reversible nature of this G0 arrest has allowed studies of the molecular events controlling the cell cycle tran...
