Decision-making by p53 and mTOR

type p53 is normally expressed at low levels and inactive due to the action of MDM2, an E3 ubiquitin ligase that binds p53 and promotes its degradation [1, 2]. However, p53 is stabilized in response to various stresses, such as DNA damage or inappropriate oncogene signaling, that might otherwise predispose a normal cell toward tumorigenesis [3]. The stress-induced stabilization of p53 results from disruption of p53-MDM2 binding. The majority of stabilized p53 accumulates in the nucleus where it functions as a transcription factor, activating expression of genes that induce either apoptosis or cell cycle arrests that can be either transient (quiescence) or permanent (senescence). Thus, p53 eliminates cells with potentially cancer-promoting lesions by inhibiting their growth or causing them to die. mTOR is a cytoplasmic kinase whose activity is often elevated in cancer [4]. mTOR converts signals from activated growth factor receptors into downstream events that promote cell proliferation and survival. Previous studies have demonstrated cross-talk between the p53 and mTOR signaling pathways. For example, p53 can activate expression of several genes, including TSC2, PTEN, IGF-BP3, and others, whose protein products can directly or indirectly inhibit mTOR activity [5]. These observations make sense given that p53 is a tumor suppressor and mTOR has more an oncogenic role in promoting cancer cell survival and proliferation. However, more recent studies indicate that the outcome of mTOR signaling can be context-dependent. Thus, while mTOR signaling promotes proliferation and survival under normal conditions, mTOR signaling can promote senescence under conditions in which the cell cycle is blocked [6, 7]. These observations support mTOR as a hub for receipt of multiple inputs that ultimately determine cell fate. When conditions are favorable mTOR activation promotes proliferation and survival, however, in the context of conflicting signals (e.g. growth factor signaling vs. cell cycle arrest), the effect of mTOR Commentary activation is permanent cell cycle exit (senescence). P21 is a cyclin-cdk inhibitor, transcriptional target of p53, and potent inducer of senescence [8, 9]. Blagosklonny and colleagues noted that in some cases p53 induction did not induce senescence while ectopic expression of p21 did [10]. This led to them to question the role of p53 in the senescence program, and whether p53 may actively suppress senescence. To address this, they used a cell line in which p21 was expressed from an inducible (IPTG-driven) promoter [11]. In this cell line, transient p21 expression induced by IPTG caused the cells to …