Abstract
Cells recovering from the G2/M DNA damage checkpoint rely more on Aurora A-PLK1 signaling than cells progressing through an unperturbed G2 phase, but the reason for this discrepancy is not known. Here, we devised a method based on a FRET reporter for PLK1 activity to sort cells in distinct populations within G2 phase. We employed mass spectroscopy to characterize changes in protein levels through an unperturbed G2 phase and validated that ATAD2 levels decrease in a proteasome-dependent manner. Comparing unperturbed cells with cells recovering from DNA damage, we note that at similar PLK1 activities, recovering cells contain higher levels of Cyclin B1 and increased phosphorylation of CDK1 targets. The increased Cyclin B1 levels are due to continuous Cyclin B1 production during a DNA damage response and are sustained until mitosis. Whereas partial inhibition of PLK1 suppresses mitotic entry more efficiently when cells recover from a checkpoint, partial inhibition of CDK1 suppresses mitotic entry more efficiently in unperturbed cells. Our findings provide a resource for proteome changes during G2 phase, show that the mitotic entry network is rewired during a DNA damage response, and suggest that the bottleneck for mitotic entry shifts from CDK1 to PLK1 after DNA damage.
Highlights
The levels and activities of many proteins change through the cell cycle
In addition to a change in protein levels, we found that the balance between PLK1 target phosphorylation and Cyclin-Cyclin Dependent Kinases (CDK) target phosphorylation is altered after recovery from the DNA damage checkpoint in G2 phase
We developed a setup to use Fluorescence Activated Cell Sorting (FACS) of live cells based on Förster Resonance Energy Transfer (FRET)
Summary
The levels and activities of many proteins change through the cell cycle. These variations are needed to direct events such as DNA replication and cell division in a timely fashion. Changes in protein levels and activities are under strict control. After an initial external regulation by growth factors, the changes are intrinsically enforced [1]. In this sense, the cell cycle constitutes a continuous oscillation of protein levels and activities. A complex mix of feedback and feedforward systems ensures that protein levels and activities change until being reset after cell division [2,3]
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