Abstract
BackgroundMicrotubule-targeting drugs induce mitotic delay at pro-metaphase by preventing the spindle assembly checkpoint to be satisfied. However, especially after prolonged treatments, cells can escape this arrest in a process called mitotic slippage. The mechanisms underlying the spindle assembly checkpoint and slippage are not fully understood. It has been generally accepted that during mitosis there is a temporary shutdown of high-energy-consuming processes, such as transcription and translation. However, the synthesis of specific proteins is maintained or up-regulated since protein synthesis is necessary for entry into and progression through mitosis.Methodology/Principal FindingsIn this work we investigated whether the mitotic arrest caused by the mitotic checkpoint is independent of transcription and translation. By using immunofluorescent microscopy and western blotting, we demonstrate that inhibition of either of these processes induces a shortening of the mitotic arrest caused by the nocodazole treatment, and ultimately leads to mitotic slippage. Our western blotting and RTQ-PCR results show that inhibition of transcription during mitotic arrest does not affect the expression of the spindle checkpoint proteins, whereas it induces a significant decrease in the mRNA and protein levels of Cyclin B1. The exogenous expression of Cyclin B1 substantially rescued the mitotic phenotype in nocodazole cells treated with the inhibitors of transcription and translation.Conclusions/SignificanceThis work emphasizes the importance of transcription and translation for the maintenance of the spindle assembly checkpoint, suggesting the existence of a mechanism dependent on cyclin B1 gene regulation during mitosis. We propose that continuous transcription of mitotic regulators is required to sustain the activation of the spindle assembly checkpoint.
Highlights
The spindle assembly checkpoint (SAC), or mitotic checkpoint, monitors the microtubule attachment to kinetochores, ensuring the correct segregation of chromosomes [1,2]
We show that four and six hours of treatment with actinomycin D or cycloheximide is sufficient to override the mitotic delay caused by nocodazole in NIH3T3 and HEK293 cells, respectively, and induce slippage
Our results suggest that the mechanism underlying the activation of the APC/ CCdc20 upon mitotic inhibition of transcription or translation involves cyclin B1 gene expression
Summary
The spindle assembly checkpoint (SAC), or mitotic checkpoint, monitors the microtubule attachment to kinetochores, ensuring the correct segregation of chromosomes [1,2]. This mechanism prevents sister chromatids separation, delaying the onset of anaphase, until all kinetochores are correctly attached to the mitotic spindle and under appropriate tension. Unattached kinetochores trigger a diffusible signal [2,3], the mitotic checkpoint complex (MCC), that inhibits the Anaphase Promoting Complex/ Cyclosome (APC/C) by acting as a pseudo-substrate of APC/C The. Microtubule-targeting drugs induce mitotic delay at pro-metaphase by preventing the spindle assembly checkpoint to be satisfied. The mechanisms underlying the spindle assembly checkpoint and slippage are not fully understood. The synthesis of specific proteins is maintained or up-regulated since protein synthesis is necessary for entry into and progression through mitosis
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