A role for E2F1 in the induction of apoptosis during thymic negative selection.

Thymic negative selection is the process in which maturing thymocytes that express T-cell receptors recognizing self are eliminated by apoptotic cell death. The molecular mechanism by which this occurs is poorly understood. Notably, genes involved in cell death, even thymocyte death, such as Fas, Fas-ligand, p53, caspase-1, caspase-3, and caspase-9, and Bcl-2 have been found to not be required for normal thymic negative selection. We have demonstrated previously that E2F1-deficient mice have a defect in thymocyte apoptosis. Here we show that E2F1 is required for normal thymic negative selection. Furthermore, we observed an E2F1-dependent increase of p53 protein levels during the process of thymic clonal deletion, which suggests that E2F1 regulates activation-induced apoptosis of self-reactive thymocytes by a p53-dependent mechanism. In contrast, other apoptotic pathways operating on developing thymocytes, such as glucocorticoid-induced cell death, are not mediated by E2F1. The T lymphocytes that escape thymic negative selection migrate to the peripheral immune system but do not appear to be autoreactive, indicating that there may exist E2F1-independent mechanisms of peripheral tolerance, which protect mice from developing an autoimmune response. We expect that E2F1-deficient mice will provide a useful tool for understanding the molecular mechanism of and the immunological importance of thymic negative selection.     

E2F1 and E2F3 activate ATM through distinct mechanisms to promote E1A-induced apoptosis

Deregulation of the Rb-E2F pathway occurs in many cancers and results in aberrant cell proliferation as well as an increased propensity to undergo apoptosis. In most cases, apoptosis in response to Rb inactivation involves the activation of p53 but the molecular details of the signaling pathway connecting Rb loss to p53 are poorly understood. Here we demonstrate that the E1A oncoprotein, which binds and inhibits Rb family members, induces the accumulation and phosphorylation of p53 through the DNA damage-responsive ATM kinase. As a result, E1A-induced apoptosis is significantly impaired in cells lacking ATM. In contrast, inactivation of ARF, which is widely believed to activate p53 in response to oncogenic stress, has no effect on p53 induction and only a modest effect on apoptosis in response to E1A. Both E2F1 and E2F3 contribute to ATM-dependent phosphorylation of p53 and apoptosis in cells expressing E1A. However, deregulated E2F3 activity is implicated in the DNA damage caused by E1A while E2F1 stimulates ATM- and NBS1-dependent p53 phosphorylation and apoptosis through a mechanism that does not involve DNA damage.     

E2F and p53 induce apoptosis independently during Drosophila development but intersect in the context of DNA damage

In mammalian cells, RB/E2F and p53 are intimately connected, and crosstalk between these pathways is critical for the induction of cell cycle arrest or cell death in response to cellular stresses. Here we have investigated the genetic interactions between RBF/E2F and p53 pathways during Drosophila development. Unexpectedly, we find that the pro-apoptotic activities of E2F and p53 are independent of one another when examined in the context of Drosophila development: apoptosis induced by the deregulation of dE2F1, or by the overexpression of dE2F1, is unaffected by the elimination of dp53; conversely, dp53-induced phenotypes are unaffected by the elimination of dE2F activity. However, dE2F and dp53 converge in the context of a DNA damage response. Both dE2F1/dDP and dp53 are required for DNA damage-induced cell death, and the analysis of rbf1 mutant eye discs indicates that dE2F1/dDP and dp53 cooperatively promote cell death in irradiated discs. In this context, the further deregulation in the expression of pro-apoptotic genes generates an additional sensitivity to apoptosis that requires both dE2F/dDP and dp53 activity. This sensitivity differs from DNA damage-induced apoptosis in wild-type discs (and from dE2F/dDP-induced apoptosis in un-irradiated rbf1 mutant eye discs) by being dependent on both hid and reaper. These results show that pro-apoptotic activities of dE2F1 and dp53 are surprisingly separable: dp53 is required for dE2F-dependent apoptosis in the response to DNA damage, but it is not required for dE2F-dependent apoptosis caused simply by the inactivation of rbf1.     

p300 binding by E1A cosegregates with p53 induction but is dispensable for apoptosis.

E1A expression during adenovirus infection induces apoptosis. E1A expression causes accumulation of the p53 tumor suppressor protein, and E1A-induced apoptosis is p53 mediated in primary rodent cells, implying that p53 induction may be linked to apoptosis induction by E1A. Adenoviruses containing mutations in the E1A gene were tested for the ability to trigger both p53 accumulation and the appearance of enhanced cytopathy (cyt phenotype) and degradation of DNA (deg phenotype), indicative of apoptosis in infected HeLa cells. The adenoviruses had mutations which disrupted the pRb- and/or p300-binding activities of E1A so that the relationship between p53 induction and apoptosis and binding to these cellular proteins by E1A could be determined. An E1A mutation that specifically disrupted the p300-binding activity failed to induce p53 accumulation, whereas mutations in E1A which affected pRb binding induced p53 accumulation. Thus, p300 binding was required and pRb binding was dispensable for E1A-mediated accumulation of p53 in HeLa cells. All the E1A mutant viruses, regardless of the ability to induce p53 accumulation, induced the cyt and deg phenotypes, suggesting that p53 induction in infected HeLa cells was not essential for apoptosis, nor was binding of E1A to the pRb and/or p300 protein. The possibility that E1A induced a p53-independent apoptosis pathway was tested by analyzing the appearance of the cyt and deg phenotypes in Saos-2 cells, which were null for both alleles of p53, upon adenovirus infection. An adenovirus expressing wild-type 12S E1A induced both the cyt and deg phenotypes in Saos-2 cells, as did all the E1A mutant viruses. Thus, E1A expression during infection of human cells may trigger redundant p53-independent and -dependent apoptotic pathways.     

A role for 14-3-3 tau in E2F1 stabilization and DNA damage-induced apoptosis

Genotoxic stress triggers apoptosis through multiple signaling pathways. Recent studies have demonstrated a specific induction of E2F1 accumulation and a role for E2F1 in apoptosis upon DNA damage. Induction of E2F1 is mediated by phosphorylation events that are dependent on DNA damage-responsive protein kinases, such as ATM. How ATM phosphorylation leads to E2F1 stabilization is unknown. We now show that 14-3-3 tau, a phosphoserine-binding protein, mediates E2F1 stabilization. 14-3-3 tau interacts with ATM-phosphorylated E2F1 during DNA damage and inhibits E2F1 ubiquitination. Depletion of 14-3-3 tau or E2F1, but not E2F2 or E2F3, blocks adriamycin-induced apoptosis. 14-3-3 tau is also required for expression and induction of E2F1 apoptotic targets, such as p73, Apaf-1, and caspases, during DNA damage. Together, these data demonstrate a novel function for 14-3-3 tau in the regulation of E2F1 protein stability and apoptosis during DNA damage.     

E2F1-dependent pathways are involved in amonafide analogue 7-d-induced DNA damage, G2/M arrest, and apoptosis in p53-deficient K562 cells

The E2F1 gene well known is its pivotal role in regulating the entry from G1 to S phase, while the salvage antitumoral pathway which implicates it, especially in the absence of p53, is not fully characterized. We therefore attempted to identify the up‐ and down‐stream events involved in the activation of the E2F1‐dependent pro‐apoptotic pathway. For this purpose, a amonafide analogue, 7‐d (2‐(3‐(2‐(Dimethylamino)ethylamino)propyl)‐6‐(dodecylamino)‐1H‐benzo[de]isoquinoline‐1,3(2H)‐dione) was screened, which exhibited high antitumor activity against p53‐deficient human Chronic Myelogenous Leukemia (CML) K562 cells. Analysis of flow cytometry and western blots of K562 cells treated with 7‐d revealed an appreciable G2/M cycle arrest and apoptosis in a dose and time‐dependent manner via p53‐independent pathway. A striking increase in “Comet tail” formation and γ‐H2AX expression showed that DNA double strand breaks (DSB) were caused by 7‐d treatment. ATM/ATR signaling was reported to connect E2F1 induction with apoptosis in response to DNA damage. Indeed, 7‐d‐induced G2/M arrest and apoptosis were antagonized by ATM/ATR signaling inhibitor, Caffeine, which suggested that ATM/ATR signaling was activated by 7‐d treatment. Furthermore, the increased expression of E2F1, p73, and Apaf‐1 and p73 dissociation from HDM2 was induced by 7‐d treatment, however, knockout of E2F1 expression reversed p73, Apaf‐1, and p21^Cip1/WAF1 expression, reactivated cell cycle progression, and inhibited 7‐d‐induced apoptosis. Altogether our results for the first time indicate that 7‐d mediates its growth inhibitory effects on CML p53‐deficient cells via the activation of an E2F1‐dependent mitochondrial and cell cycle checkpoint signaling pathway which subsequently targets p73, Apaf‐1, and p21^Cip1/WAF1. J. Cell. Biochem. 113: 3165–3177, 2012. © 2012 Wiley Periodicals, Inc.