Suppression of apoptosis and clonogenic survival in irradiated human lymphoblasts with different TP53 status

The influence of radiation-induced apoptosis on radiosensitivity was studied in a set of closely related human lymphoblastoid cell lines differing in TP53 status. The clonogenic survival of irradiated TK6 cells (expressing wild-type TP53), WTK1 cells (overexpressing mutant TP53), and TK6E6 cells (negative for TP53 owing to transfection with HPV16 E6) was assessed in relation to the induction of apoptosis and its suppression by caspase inhibition or treatment with PMA as well as after treatment with caffeine. Measurements using the alkaline comet assay and pulsed-field electrophoresis of the induction and repair of DNA strand breaks showed similar kinetics of the processing of early DNA damage in these cell lines. The cytochalasin B micronucleus assay revealed identical levels of residual damage in the first postirradiation mitosis of these cells. Abrogation of TP53-dependent apoptosis in TK6E6 cells resulted in a distinct increase in radioresistance. Further suppression of apoptosis as observed in WTK1 cells overexpressing mutant TP53 apparently was not responsible for the high radioresistance of WTK1 cells, since other means of highly efficient suppression of apoptosis (caspase inhibition or PMA treatment) increased the clonogenic survival of irradiated TK6 cells only to levels similar to those of TK6E6 cells with abrogated TP53-dependent apoptosis. Considering the similar levels of residual chromosomal damage in TK6E6 cells and WTK1 cells, a hitherto unknown mechanism of tolerance needs to be inferred for these TP53 mutant cells. This residual damage tolerance, however, appears to require an intact G2/M-phase checkpoint function since the relative radioresistance of the WTK1 cells was completely lost upon caffeine treatment, which also resulted in a failure of the TK6 and TK6E6 cells to execute apoptosis. In this situation, the cellular response seems to be dominated entirely by TP53-independent mitotic failure.     

Parthenolide sensitizes cells to X-ray-induced cell killing through inhibition of NF-kappaB and split-dose repair

Human cancers have multiple alterations in cell signaling pathways that promote resistance to cytotoxic therapy such as X rays. Parthenolide is a sesquiterpene lactone that has been shown to inhibit several pro-survival cell signaling pathways, induce apoptosis, and enhance chemotherapy-induced cell killing. We investigated whether parthenolide would enhance X-ray-induced cell killing in radiation resistant, NF-kappaB-activated CGL1 cells. Treatment with 5 microM parthenolide for 48 to 72 h inhibited constitutive NF-kappaB binding and cell growth, reduced plating efficiency, and induced apoptosis through stabilization of p53 (TP53), induction of the pro-apoptosis protein BAX, and phosphorylation of BID. Parthenolide also enhanced radiation-induced cell killing, increasing the X-ray sensitivity of CGL1 cells by a dose modification factor of 1.6. Flow cytometry revealed that parthenolide reduced the percentage of X-ray-resistant S-phase cells due to induction of p21 waf1/cip1 (CDKN1A) and the onset of G1/S and G2/M blocks, but depletion of radioresistant S-phase cells does not explain the observed X-ray sensitization. Further studies demonstrated that the enhancement of X-ray-induced cell killing by parthenolide is due to inhibition of split-dose repair.     

Caspase 2 is both required for p53-mediated apoptosis and downregulated by p53 in a p21-dependent manner

Upon treatment with some DNA damaging agents, human H1299 tumor-derived cells expressing inducible versions of wild-type or mutant p53 with inactive transactivation domain I (p53Q22/S23) undergo apoptosis. In cells expressing either version of p53, caspase 2 activation is required for release of cytochrome c and cell death. Furthermore, silencing of PIDD (a factor previously shown to be required for caspase 2 activation) by siRNA suppresses apoptosis by both wild-type p53 and p53Q22/S23. Despite the finding that caspase 2 is essential for DNA damage-facilitated, p53-mediated apoptosis, induction of wild-type p53 (with or without DNA damage) resulted in a reduction of caspase 2 mRNA and protein levels. In this study we sought to provide a mechanism for the negative regulation of caspase 2 by p53 as well as provide insight as to why p53 may repress a key mediator of p53-dependent apoptosis. Mechanistically, we show that DNA binding and/or transactivation domains of p53 are crucial for mediating transrepression. Further, expression of p21 (in p53-null cells inducibly expressing p21) is sufficient to mediate repression of caspase 2. Deletion of p21 or E2F-1 not only abrogated repression of caspase 2, but also stimulated the expression of caspase 2 above basal levels, implicating the requirement for an intact p21/Rb/E2F pathway in the down-regulation of caspase 2. As this p53/p21-dependent repression of caspase 2 can occur in the absence of DNA damage, caspase 2 repression does not simply seem to be a consequence of the apoptotic process. Down-regulation of caspase 2 levels by p53 may help to determine cell fate by preventing cell death when unnecessary.     

Activation of an MDM2-specific caspase by p53 in the absence of apoptosis.

Cells undergoing p53-mediated apoptosis activate caspase 3-like activities, resulting in the cleavage of the MDM2 oncoprotein and other apoptotic substrates such as poly(ADP-ribose) polymerase. To investigate the mechanism of p53-mediated apoptosis and to determine whether cleavage of MDM2 has a potential role in regulating p53, we examined caspase activation and cleavage of MDM2 in a cell line undergoing p53-mediated growth arrest and delayed apoptosis. We found that in H1299 cells expressing a temperature-sensitive human p53, a distinct caspase activity specific for the MDM2 cleavage site DVPD is induced by p53 prior to the onset of apoptosis and loss of viability. This is accompanied by the cleavage of MDM2 but not the apoptotic substrate poly(ADP-ribose) polymerase. The cleaved MDM2 loses the ability to promote p53 degradation and may potentially function in a dominant-negative fashion to stabilize p53. These results suggest that p53 activation may induce a positive feedback effect by cleavage of MDM2 through a unique caspase.     

Triad 1 induces apoptosis by p53 activation

Triad 1 (2 RING [really interesting new gene] fingers and DRIL [double RING finger linked] 1) is an E3 ligase that induces apoptosis and clonogenic inhibition in myeloid cells through Gfi-1 stabilization. Here we demonstrate that Triad 1 induces apoptosis in several cancer cell lines including MCF7, A549, U2OS, and HCT 116 p53^+/+ cells via its RING ligase activity. Interestingly, in these cancer cells, Triad 1-induced apoptosis is not mediated by Gfi-1 stabilization but is instead p53-dependent. Moreover, Triad 1 promotes transactivation of p53. These results suggest that Triad 1 can induce apoptosis through its ligase activity via p53 activation.     

Spatiotemporal activation of caspase‐dependent and ‐independent pathways in staurosporine‐induced apoptosis of p53wt and p53mt human cervical carcinoma cells

Background information. Caspase‐dependent and ‐independent death mechanisms are involved in apoptosis in a variety of human carcinoma cells treated with antineoplastic compounds. Our laboratory has reported that p53 is a key contributor of mitochondrial apoptosis in cervical carcinoma cells after staurosporine exposure. However, higher mitochondrial membrane potential dissipation and greater DNA fragmentation were observed in p53^wt (wild‐type p53) HeLa cells compared with p53^mt (mutated p53) C‐33A cells. Here, we have studied events linked to the mitochondrial apoptotic pathway. Results. Staurosporine can induce death of HeLa cells via a cytochrome c/caspase‐9/caspase‐3 mitochondrial‐dependent apoptotic pathway and via a delayed caspase‐independent pathway. In contrast with p53^wt cells, p53^mt C‐33A cells exhibit firstly caspase‐8 activation leading to caspase‐3 activation and Bid cleavage followed by cytochrome c release. Attenuation of PARP‐1 [poly(ADP‐ribose) polymerase‐1] cleavage as well as oligonucleosomal DNA fragmentation in the presence of z‐VAD‐fmk points toward a major involvement of a caspase‐dependent pathway in staurosporine‐induced apoptosis in p53^wt HeLa cells, which is not the case in p53^mt C‐33A cells. Meanwhile, the use of 3‐aminobenzamide, a PARP‐1 inhibitor known to prevent AIF (apoptosis‐inducing factor) release, significantly decreases staurosporine‐induced death in these p53^mt carcinoma cells, suggesting a preferential implication of caspase‐independent apoptosis. On the other hand, we show that p53, whose activity is modulated by pifithrin‐α, isolated as a suppressor of p53‐mediated transactivation, or by PRIMA‐1 (p53 reactivation and induction of massive apoptosis), that reactivates mutant p53, causes cytochrome c release as well as mitochondrio—nuclear AIF translocation in staurosporine‐induced apoptosis of cervical carcinoma cells. Conclusions. The present paper highlights that staurosporine engages the intrinsic mitochondrial apoptotic pathway via caspase‐8 or caspase‐9 signalling cascades and via caspase‐independent cell death, as well as through p53 activity.     

Skp2 suppresses p53-dependent apoptosis by inhibiting p300

The F box protein Skp2 is oncogenic, and its frequent amplification and overexpression correlate with the grade of malignancy of certain tumors. Conversely, depletion of Skp2 decreases cell growth and increases apoptosis. Here, we show that Skp2 counteracts the transactivation function of p53 and suppresses apoptosis mediated by DNA damage or p53 stabilization. We demonstrate that Skp2 forms a complex with p300 through the CH1 and the CH3 domains of p300 to which p53 is thought to bind and antagonizes the interaction between p300 and p53 in cells and in vitro. As Skp2 antagonizes the interaction between p300 and p53, Skp2 suppresses p300-mediated acetylation of p53 and the transactivation ability of p53. Conversely, ectopic expression of p300 rescues the transactivation function of p53 in cells overexpressing Skp2. Taken together, our results indicate that Skp2 controls p300-p53 signaling pathways in cancer cells, making Skp2 a potential molecular target for cancer therapy.     

BOK and NOXA are essential mediators of p53-dependent apoptosis

Cellular stress leads to DNA damage and activation of the intrinsic apoptotic pathway in which translocation of mitochondrial cytochrome c to the cytosol plays a critical role. Previous studies have suggested alternative mechanisms responsible for this process. We examined initiation mechanisms of the intrinsic apoptotic pathway using human neuroblastoma and breast cancer cells. Results indicated that translocation of cytochrome c does not require prior activation of caspases but rather depends on activation of specific BCL-2 family members, depending upon the type of death signal. Thus, DNA damage-induced apoptosis requires new protein synthesis, accumulation of p53 tumor suppressor protein, and p53-dependent induction of BOK and NOXA genes, while a role for BAX in this pathway is not essential. In contrast, apoptosis induced by staurosporine does not require protein synthesis but is characterized by translocation of BAX. Based on these findings, we propose a model of the intrinsic apoptotic cascade induced by DNA damage where proapoptotic BOK substitutes for a function of BAX.     

Arsenic trioxide selectively induces early and extensive apoptosis via the APO2/caspase-8 pathway engaging the mitochondrial pathway in myeloma cells with mutant p53

Arsenic trioxide (ATO) is effective in the treatment of acute promyelocytic leukemia (APL) and induces apoptosis in APL cells and in a great variety of other cancer cells. We have previously shown that ATO induces apoptosis in myeloma cells in two different modes depending on p53 status in the cells. In cells expressing mutated p53, ATO induced, G2/M arrest and activation caspase 8 and 3 and rapid and extensive apoptosis. Myeloma cells expressing w.t. p53, ATO induced G1 arrest and delayed apoptosis with activation of caspase 9 and 3. APO2/TRAIL receptor expression was induced in both cell types and APO2/TRAIL synergized with ATO in the induction of apoptosis. Here we tested the effect of ATO on mitochondrial membrane potential (MMP) in myeloma cells expressing mutated or w.t. p53. In myeloma cells expressing mutated p53, depolarization of MMP occurred early, concomitant with induction of APO2/TRAIL, activation of BID and release of AIF, preceding apoptosis. However, in cells expressing w.t. p53, APO2/TRAIL is not induced, BID is not cleaved and depolarization of MMP occurs concurrently with cytochrome c release and apoptosis. These results explain the greater sensitivity to ATO of cells with mutated p53 and suggest perhaps a general mechanism for ATO-induced apoptosis.     

SIRT1 regulates apoptosis and Nanog expression in mouse embryonic stem cells by controlling p53 subcellular localization

Nuclear tumor suppressor p53 transactivates proapoptotic genes or antioxidant genes depending on stress severity, while cytoplasmic p53 induces mitochondrial-dependent apoptosis without gene transactivation. Although SIRT1, a p53 deacetylase, inhibits p53-mediated transactivation, how SIRT1 regulates these p53 multifunctions is unclear. Here we show that SIRT1 blocks nuclear translocation of cytoplasmic p53 in response to endogenous reactive oxygen species (ROS) and triggers mitochondrial-dependent apoptosis in mouse embryonic stem (mES) cells. ROS generated by antioxidant-free culture caused p53 translocation into mitochondria in wild-type mES cells but induced p53 translocation into the nucleus in SIRT1(-/-) mES cells. Endogenous ROS triggered apoptosis of wild-type mES through mitochondrial translocation of p53 and BAX but inhibited Nanog expression of SIRT1(-/-) mES, indicating that SIRT1 makes mES cells sensitive to ROS and inhibits p53-mediated suppression of Nanog expression. Our results suggest that endogenous ROS control is important for mES cell maintenance in culture.     

ATR Activation Necessary But Not Sufficient for p53 Induction and Apoptosis in Hydroxyurea-Hypersensitive Myeloid Leukemia Cells

Hydroxyurea (HU) is a competitive inhibitor of ribonucleotide reductase that is used for the treatment of myeloproliferative disorders. HU inhibits DNA replication and induces apoptosis in a cell type-dependent manner, yet the relevant pathways that mediate apoptosis in response to this agent are not well characterized. In this study, we employed the human myeloid leukemia 1 (ML-1) cell line as a model to investigate the mechanisms of HU-induced apoptosis. Exposure of ML-1 cells to HU caused rapid cell death that was accompanied by hallmark features of apoptosis, including membrane blebbing, phosphatidylserine translocation, and caspase activation. HU-induced apoptosis required new protein synthesis, was induced by HU exposures as short as 15 min, and correlated with the accumulation of p53 and induction of the p53 target gene PUMA. p53 induction in ML-1 cells was ATR dependent and downregulation of p53 through RNAi delayed HU-induced apoptosis. HU did not induce p53 or induce apoptosis in Molt-3 leukemia cells, even though exposure to HU induced a comparable level of DNA damage and robustly activated the ATR pathway. The microtubule inhibitor nocodazole suppressed HU-induced p53 accumulation in ML-1 cells suggesting that a microtubule-dependent event contributes to p53 induction and apoptosis in this cell line. Our findings outline an HU-induced cell death pathway and suggest that activation of the ATR is necessary, but not sufficient, for stabilization of p53 in response to DNA replication stress.     

Involvement of caspase 1 and its activator Ipaf upstream of mitochondrial events in apoptosis

PTP-S2/TC45 is a nuclear protein tyrosine phosphatase that activates p53 and induces caspase 1-dependent apoptosis. We analyzed the role of ICE protease-activating factor (Ipaf), an activator of caspase 1 in p53-dependent apoptosis. We also determined the sequence of events that lead to apoptosis upon caspase 1 activation by Ipaf. PTP-S2 expression induced Ipaf mRNA in MCF-7 cells which was dependent on p53. PTP-S2-induced apoptosis was inhibited by a dominant-negative mutant of Ipaf and also by an Ipaf-directed short-hairpin RNA. Doxorubicin-induced apoptosis was potentiated by the expression of caspase 1 (but not by a catalytic mutant of caspase 1) and required endogenous Ipaf. Doxorubicin treatment of MCF-7 cells resulted in activation of exogenous caspase 1, which was partly dependent on endogenous Ipaf. An activated form of Ipaf induced caspase 1-dependent apoptosis that was inhibited by Bcl2 and also by a dominant inhibitor of caspase 9 (caspase 9s). Caspase 1-dependent apoptosis induced by doxorubicin was also inhibited by Bcl2 and caspase 9s, but caspase 1 activation by activated Ipaf was not inhibited by Bcl2. Mitochondrial membrane permeabilization was induced by caspase 1 and activated Ipaf, which was inhibited by Bcl2, but not by caspase 9s. Expression of caspase 1 with activated Ipaf resulted in the activation of Bax at mitochondria. Our results suggest that Ipaf is involved in PTP-S2-induced apoptosis and that caspase 1, when activated by Ipaf, causes release of mitochondrial proteins (cytochrome c and Omi) through Bax activation, thereby functioning as an initiator caspase.     

Mitochondrial inner membrane permeabilisation enables mtDNA release during apoptosis

During apoptosis, pro‐apoptotic BAX and BAK are activated, causing mitochondrial outer membrane permeabilisation (MOMP), caspase activation and cell death. However, even in the absence of caspase activity, cells usually die following MOMP. Such caspase‐independent cell death is accompanied by inflammation that requires mitochondrial DNA (mtDNA) activation of cGAS‐STING signalling. Because the mitochondrial inner membrane is thought to remain intact during apoptosis, we sought to address how matrix mtDNA could activate the cytosolic cGAS‐STING signalling pathway. Using super‐resolution imaging, we show that mtDNA is efficiently released from mitochondria following MOMP. In a temporal manner, we find that following MOMP, BAX/BAK‐mediated mitochondrial outer membrane pores gradually widen. This allows extrusion of the mitochondrial inner membrane into the cytosol whereupon it permeablises allowing mtDNA release. Our data demonstrate that mitochondrial inner membrane permeabilisation (MIMP) can occur during cell death following BAX/BAK‐dependent MOMP. Importantly, by enabling the cytosolic release of mtDNA, inner membrane permeabilisation underpins the immunogenic effects of caspase‐independent cell death.     

Sodium orthovanadate suppresses DNA damage-induced caspase activation and apoptosis by inactivating p53

We previously reported that p42/SETbeta is a substrate for caspase-7 in irradiated MOLT-4 cells, and that treating the cells with sodium orthovanadate (vanadate) inhibits p42/SETbeta's caspase-mediated cleavage. Here, we initially found that the inhibitory effect of vanadate was due to the suppression of caspase activation but not of caspase activity. Further investigations revealed that vanadate suppressed upstream of apoptotic events, such as the loss of mitochondrial membrane potential, the conformational change of Bax, and p53 transactivation, although the accumulation, total phosphorylation, and phosphorylation of six individual sites of p53 were not affected. Importantly, vanadate suppressed p53-dependent apoptosis, but not p53-independent apoptosis. Finally, gel-shift and chromatin immunoprecipitation assays conclusively demonstrated that vanadate inhibits the DNA-binding activity of p53. Vanadate is conventionally used as an inhibitor of protein tyrosine phosphatases (PTPs); however, we recommend that the influence of vanadate not only on PTPs but also on p53 be considered before using it.