One approach to studying the regulation of cell cycle progression (particularly in an era when genetic and molecular biology manipulations were less readily accomplished in mammalian cells) was to use treatments that induced cells to fuse and then monitor the behavior of the two nuclei in the resulting cell. The figure below depicts data from one such study.  The investigators did preliminary work to produce populations of cells that were synchronized in various stages of the cell cycle (G₁, S, or G₂ in the examples shown below). They then fused the cells in different combinations and monitored subsequent events in each of the nuclei. For purposes of this question, we will pay particular attention to what occurred in the nucleus that came from the cell in G₁. In one experiment (I), cells in the G₁ and S phases were fused.  That event caused the nucleus from the G₁ cell to very quickly enter the S phase (sooner than it would otherwise have done so).  In contrast, in a second experiment (II), in which cells in the G₁ and G₂ phases were fused, the nucleus from the G₁ cell remained on its original “timetable.”  That is, it did eventually enter S, but not any sooner than was the case for nuclei in the un-fused cells in G₁.  

How do you explain the ability of the S-phase cells in experiment I to induce premature entry of the G₁ nuclei into S?  (Hint: What protein(s) are present and active in S-phase cells but not G₁ cells?) Briefly explain your reasoning. Also, how do you explain the different outcome observed in experiment II?  In both cases the nuclei from the G₁ cells are being exposed to cellular contents of cells further along in the cell cycle, but the G₂ cells seem to have lost the “power” to drive premature entry into S. 

Transcribed Image Text:

(1I) (1) G1