Understanding the limitations of radiation-induced cell cycle checkpoints

The DNA damage response pathways involve processes of double-strand break (DSB) repair and cell cycle checkpoint control to prevent or limit entry into S phase or mitosis in the presence of unrepaired damage. Checkpoints can function to permanently remove damaged cells from the actively proliferating population but can also halt the cell cycle temporarily to provide time for the repair of DSBs. Although efficient in their ability to limit genomic instability, checkpoints are not foolproof but carry inherent limitations. Recent work has demonstrated that the G1/S checkpoint is slowly activated and allows cells to enter S phase in the presence of unrepaired DSBs for about 4–6 h post irradiation. During this time, only a slowing but not abolition of S-phase entry is observed. The G2/M checkpoint, in contrast, is quickly activated but only responds to a level of 10–20 DSBs such that cells with a low number of DSBs do not initiate the checkpoint or terminate arrest before repair is complete. Here, we discuss the limitations of these checkpoints in the context of the current knowledge of the factors involved. We suggest that the time needed to fully activate G1/S arrest reflects the existence of a restriction point in G1-phase progression. This point has previously been defined as the point when mitogen starvation fails to prevent cells from entering S phase. However, cells that passed the restriction point can respond to DSBs, albeit with reduced efficiency

The dynamics of a pre-mRNA splicing factor in living cells

Pre-mRNA splicing is a predominantly co-transcriptional event which involves a large number of essential splicing factors. Within the mammalian cell nucleus, most splicing factors are concentrated in 20-40 distinct domains called speckles. The function of speckles and the organization of cellular transcription and pre-mRNA splicing in vivo are not well understood. We have investigated the dynamic properties of splicing factors in nuclei of living cells. Here we show that speckles are highly dynamic structures that respond specifically to activation of nearby genes. These dynamic events are dependent on RNA polymerase II transcription, and are sensitive to inhibitors of protein kinases and Ser/Thr phosphatases. When single genes are transcriptionally activated in living cells, splicing factors leave speckles in peripheral extensions and accumulate at the new sites of transcription. We conclude that one function of speckles is to supply splicing factors to active genes. Our observations demonstrate that the interphase nucleus is far more dynamic in nature than previously assumed