lations have so far been carried out using proliferating cells such as breast cancer epithelial and fibroblast cells. The fact that our Model predicts that the oscillations occur around the low-p53 steady states is consistent with these observed association between proliferating cells and p53 oscillations. We would like to offer ways to test the predictions of our model in the laboratory. Several single cell time-lapse microscopy experiments could be performed to validate key hypotheses generated from the models by taking advantage of the evidence that not every cell would manifest p53MDM2 oscillations when irradiated with the same IR intensity. For instance, only 40% of MCF-7 cells showed oscillations upon 10 Gy of gamma radiation. Strictly speaking, a cell could only be in one of the three states: low-p53, highp53 and oscillatory p53. The key prediction that p53 oscillations 22761436 induce higher level of target gene expression could be tested by 23300835 semi-quantifying the expression level of a luciferase reporter gene that possesses a p53 promoter sequence upon irradiation. Oscillatory cells are predicted to express higher intensity of fluorescence than non-oscillatory cells; comparisons should be made among cells that expressed similar mean level of p53. Also, an interesting experiment would be to test whether higher p53-dependent expression of cell cycle and DNA Torin-1 supplier repair genes in oscillatory cells could lead to faster cell cycle arrest and repair damage DNA than non-oscillatory cells upon irradiation. In contrast, the other key prediction that p53 oscillations lower the IR intensity level at which the system switches to high-p53 state is relatively trickier to perform experimentally. It involves the determination of cumulative IR dose that lead to a high-p53 state in each oscillatory and nonoscillatory cells by increasing the IR dose gradually. Oscillatory cells are predicted to switch to high-p53 state over a wider range of cumulative IR dose with lower median than non-oscillatory cells. Lastly, for the future development of our model, we would like to point out that besides PTEN, the insulin growth factor-binding protein 3 connects p53 to AKT. Upon DNA damage, IGFBP3 is upregulated by both p53-dependent and independent transcription. IGFBP3 binds and sequesters IGFs away from IGFRs, and thereby inhibits AKT activation; active IGF-bound IGFRs induce the downstream activation of the PI3K/AKT survival pathway. Surprisingly, through unknown mechanisms, IGFBP3 could also sensitize cells to the phosphorylation of AKT by IGFs, which leads to AKT activation. Thus, further experimental studies are needed to resolve the conflicting relationship between p53, IGFBP3 and AKT. Materials and Methods To determine the steady states of the Model, the left-hand sides of the ODEs in Supporting Information Found at: doi:10.1371/journal.pone.0004407.s001 Found at: doi:10.1371/journal.pone.0004407.s002 Found at: doi:10.1371/journal.pone.0004407.s003 Found at: doi:10.1371/journal.pone.0004407.s004 Found at: doi:10.1371/journal.pone.0004407.s005 Found at: doi:10.1371/journal.pone.0004407.s006 Found at: doi:10.1371/journal.pone.0004407.s007 Found at: doi:10.1371/journal.pone.0004407.s008 Gastrointestinal stromal tumors are a paradigm for the development of personalized treatment for cancer patients. The nearly simultaneous discovery of a biomarker that is reflective of their origin and the presence of gain-of-function kinase mutations in these tumors set the stage for mo