ATM and Chk2-dependent phosphorylation of MDMX contribute to p53 activation after DNA damage

The p53 tumor suppressor is activated after DNA damage to maintain genomic stability and prevent transformation. Rapid activation of p53 by ionizing radiation is dependent on signaling by the ATM kinase. MDM2 and MDMX are important p53 regulators and logical targets for stress signals. We found that DNA damage induces ATM-dependent phosphorylation and degradation of MDMX. Phosphorylated MDMX is selectively bound and degraded by MDM2 preceding p53 accumulation and activation. Reduction of MDMX level by RNAi enhances p53 response to DNA damage. Loss of ATM prevents MDMX degradation and p53 stabilization after DNA damage. Phosphorylation of MDMX on S342, S367, and S403 were detected by mass spectrometric analysis, with the first two sites confirmed by phosphopeptide-specific antibodies. Mutation of MDMX on S342, S367, and S403 each confers partial resistance to MDM2-mediated ubiquitination and degradation. Phosphorylation of S342 and S367 in vivo require the Chk2 kinase. Chk2 also stimulates MDMX ubiquitination and degradation by MDM2. Therefore, the E3 ligase activity of MDM2 is redirected to MDMX after DNA damage and contributes to p53 activation.     

14-3-3τ Regulates Ubiquitin-Independent Proteasomal Degradation of p21, a Novel Mechanism of p21 Downregulation in Breast Cancer

14-3-3 proteins regulate many cellular functions, including proliferation. However, the detailed mechanisms by which they control the cell cycle remain to be fully elucidated. We report that one of the 14-3-3 isoforms, 14-3-3τ, is required for the G₁/S transition through its role in ubiquitin-independent proteasomal degradation of p21. 14-3-3τ binds to p21, MDM2, and the C8 subunit of the 20S proteasome in G₁ phase and facilitates proteasomal targeting of p21. This function of 14-3-3τ may be deregulated in cancer. The overexpression of 14-3-3τ is frequently found in primary human breast cancer and correlates with lower levels of p21 and shorter patient survival. Tenascin-C, an extracellular matrix protein involved in tumor initiation and progression and a known 14-3-3τ inducer, decreases p21 and abrogates adriamycin-induced G₁/S arrest. It has been known that p21 is required for a proper tamoxifen response in breast cancer. We show that the overexpression of 14-3-3τ inhibits tamoxifen-induced p21 induction and growth arrest in MCF7 cells. Together, the findings of our studies strongly suggest a novel oncogenic role of 14-3-3τ by downregulating p21 in breast cancer. Therefore, 14-3-3τ may be a potential therapeutic target in breast cancer.14-3-3 proteins are a family of about 30-kDa dimeric well-conserved α-helical phosphoserine/threonine binding proteins. They contain seven mammalian isoforms (β, ɛ, γ, η, σ, τ, ζ) and are able to bind to multiple protein ligands. The 14-3-3 binding proteins are very diverse; therefore, 14-3-3 is involved in many different cellular processes, including mitogenesis, DNA damage checkpoint, cell cycle control, and apoptosis (12). Most 14-3-3 ligands require phosphorylation to bind to 14-3-3; and their consensus motifs are R(S/Ar)XpSXP (mode 1), RX(Ar/S)XpSXP (mode 2) (12, 46), and (pS/pT)X_1-2-COOH (mode 3) (13). However, this consensus is not absolutely required, since a few 14-3-3 binding ligands have sequences significantly different from the sequences of these motifs or do not even require phosphorylation for binding (12, 46).In general, 14-3-3 proteins play a role in promoting survival and repressing apoptosis (33). However, each isoform may have unique functions in certain physiological contexts. For example, 14-3-3τ binds to ATM-phosphorylated E2F1 during DNA damage and promotes E2F1 stability, leading to the induction of E2F1 proapoptotic target genes such as p73, Apaf1, and caspases (44). Like other 14-3-3 isoforms, however, there appears to be a role for 14-3-3τ in cell survival as well. The deletion of 14-3-3τ in mice leads to embryonic lethality, probably due to developmental arrest (25). Examination of 14-3-3τ^+/− mice reveals a role for 14-3-3τ in cardiomyocyte survival (25). This is probably due to its activity that antagonizes ASK1 and sequesters BAD and FOXO family members. However, whether and how 14-3-3τ is involved in cell cycle progression remain poorly understood.In the study described here, we investigated the role of 14-3-3τ in cell cycle control and uncovered its involvement in the regulation of the cyclin-dependent kinase inhibitor p21(Waf1/Cip1). p21 is a p53 target gene and a major regulator that mediates p53-dependent G₁ arrest and senescence. The turnover of the p21 protein is under very tight control. p21 can be degraded through both ubiquitin-dependent and ubiquitin-independent mechanisms. In the ubiquitin-dependent pathway, Skp2 and CRL4(Cdt2) are responsible for p21 degradation in S phase (1, 5, 23, 30, 48), whereas APC/C^Cdc20 controls the degradation of p21 in prometaphase (3). There are also data demonstrating that Skp2 is not required for basal p21 ubiquitylation and degradation (8). p21 can also be directly targeted to the proteasome for degradation without ubiquitylation (38). This process is mediated by an interaction between p21 and the C8 α subunit of the 20S proteasome (40) and can be promoted by MDM2 and MDMX (20, 21, 49). The MDM2/MDMX-regulated degradation of p21 occurs at the G₁ and early S phases (21). The stability of the p21 protein is also regulated by heat shock proteins. An Hsp90 binding protein, WISp39, recruits Hsp90 to p21 and protects p21 from degradation during DNA damage (19). Therefore, it appears that several different regulators control the stability of the p21 protein, probably depending on the phases of the cell cycle and cellular contexts.Given the evidence of both ubiquitin-dependent and -independent degradation of p21, Pagano and colleagues proposed that both mechanisms of degradation of p21 in different protein complexes may occur in cells (3). It has been shown that free p21, but not cyclin E/cdk2-bound p21, can be degraded by the proteasome in vitro without ubiquitylation (4, 26, 27). Thus, when p21 is complexed with cdk2, it may be degraded by the ubiquitin-dependent pathway, while the ubiquitin-independent mechanism may target free p21 for degradation. It has been shown that this process involves the REGγ proteasome complex (7, 26), which forms the 11S lid and activates the 20S catalytic core proteasome. However, the regulatory mechanisms for the ubiquitin-independent degradation of p21 remain unclear.In the present study, we identify 14-3-3τ as the protein that regulates the ubiquitin-independent proteasomal degradation of p21 in G₁ phase. We demonstrate a direct role for 14-3-3τ in the 20S-mediated p21 degradation via facilitation of an interaction between p21, MDM2, and C8 in vitro. This new role of 14-3-3τ might have an important clinical implication. The extracellular matrix tenascin-C induces 14-3-3τ and degrades p21 through the induction of 14-3-3τ and ameliorates adriamycin-induced cell cycle arrest. 14-3-3τ is often overexpressed in breast cancer, and its overexpression is associated with the downregulation of p21 and shorter patient survival. Through the downregulation of p21, 14-3-3τ overexpression also leads to tamoxifen resistance in MCF7 breast cancer cells.     

MDMX regulation of p53 response to ribosomal stress

Ribosomal stress such as disruption of rRNA biogenesis activates p53 by release of ribosomal proteins from the nucleoli, which bind to MDM2 and inhibit p53 degradation. We found that p53 activation by ribosomal stress requires degradation of MDMX in an MDM2-dependent fashion. Tumor cells overexpressing MDMX are less sensitive to actinomycin D-induced growth arrest due to formation of inactive p53-MDMX complexes. Knockdown of MDMX increases sensitivity to actinomycin D, whereas MDMX overexpression abrogates p53 activation and prevents growth arrest. Furthermore, MDMX expression promotes resistance to the chemotherapeutic agent 5-fluorouracil (5-FU), which at low concentrations activates p53 by inducing ribosomal stress without significant DNA damage signaling. Knockdown of MDMX abrogates HCT116 tumor xenograft formation in nude mice. MDMX overexpression does not accelerate tumor growth but increases resistance to 5-FU treatment in vivo. Therefore, MDMX is an important regulator of p53 response to ribosomal stress and RNA-targeting chemotherapy agents.     

Regulation of MDMX nuclear import and degradation by Chk2 and 14-3-3

The MDM2 homolog MDMX is an important regulator of p53 during mouse embryonic development. DNA damage promotes MDMX phosphorylation, nuclear translocation, and degradation by MDM2. Here we show that MDMX copurifies with 14-3-3, and DNA damage stimulates MDMX binding to 14-3-3. Chk2-mediated phosphorylation of MDMX on S367 is important for stimulating 14-3-3 binding, MDMX nuclear import by a cryptic nuclear import signal, and degradation by MDM2. Mutation of MDMX S367 inhibits ubiquitination and degradation by MDM2, and prevents MDMX nuclear import. Expression of 14-3-3 stimulates the degradation of phosphorylated MDMX. Chk2 and 14-3-3 cooperatively stimulate MDMX ubiquitination and overcome the inhibition of p53 by MDMX. These results suggest that MDMX-14-3-3 interaction plays a role in p53 response to DNA damage by regulating MDMX localization and stability.     

Structure of the MDM2/MDMX RING domain heterodimer reveals dimerization is required for their ubiquitylation in trans

MDM2, a ubiquitin E3-ligase of the RING family, has a key role in regulating p53 abundance. During normal non-stress conditions p53 is targeted for degradation by MDM2. MDM2 can also target itself and MDMX for degradation. MDMX is closely related to MDM2 but the RING domain of MDMX does not possess intrinsic E3-ligase activity. Instead, MDMX regulates p53 abundance by modulating the levels and activity of MDM2. Dimerization, mediated by the conserved C-terminal RING domains of both MDM2 and MDMX, is critical to this activity. Here we report the crystal structure of the MDM2/MDMX RING domain heterodimer and map residues required for functional interaction with the E2 (UbcH5b). In both MDM2 and MDMX residues C-terminal to the RING domain have a key role in dimer formation. In addition we show that these residues are part of an extended surface that is essential for ubiquitylation in trans. This study provides a molecular basis for understanding how heterodimer formation leads to stabilization of MDM2, yet degradation of p53, and suggests novel targets for therapeutic intervention.     

Induction of G1 arrest and apoptosis in human jurkat T cells by pentagalloylglucose through inhibiting proteasome activity and elevating p27Kip1, p21Cip1/WAF1, and Bax proteins

Pentagalloylglucose, which is found in many medicinal plants, can arrest the cell cycle at G(1) phase through down-regulation of cyclin-dependent kinases 2 and 4 and up-regulation of the cyclin-dependent kinase inhibitors p27(Kip1) and p21(Cip1/WAF1) in human breast cancer cells. Pentagalloylglucose also induces apoptosis in human leukemic cells. However, the mechanisms by which pentagalloylglucose induces these effects is unclear. We now show that pentagalloylglucose inhibits the activities of purified 20 and 26 S proteasomes in vitro, the 26 S proteasome in Jurkat T cell lysates, and chymotrypsin-like activity of the 26 S proteasome in intact Jurkat T cells. The turnover of p27(Kip1) and p21(Cip1/WAF1), which is necessary for cell cycle progression mediated by proteasome degradation, was disrupted by treatment of human Jurkat T cells with pentagalloylglucose. This was shown by cycloheximide treatment and in vivo pulse-chase labeling experiments, and this effect correlated with the arrest of proliferation of Jurkat T cells at G(1). Inhibition of the proteasome by pentagalloylglucose and by the proteasome inhibitor MG132 caused accumulation of ubiquitin-tagged proteins in Jurkat T cells. The addition of pentagalloylglucose to Jurkat T cells enhanced the stability of the proteasome substrate Bax and increased cytochrome c release and apoptosis. Our findings suggest a mechanism for the effect of pentagalloylglucose on the cell cycle in human leukemic cells: that pentagalloylglucose down-regulates proteasome-mediated pathways because it is a proteasome inhibitor.     

MDM2 promotes p21waf1/cip1 proteasomal turnover independently of ubiquitylation

The CDK inhibitor p21waf1/cip1 is degraded by a ubiquitin-independent proteolytic pathway. Here, we show that MDM2 mediates this degradation process. Overexpression of wild-type or ring finger-deleted, but not nuclear localization signal (NLS)-deleted, MDM2 decreased p21waf1/cip1 levels without ubiquitylating this protein and affecting its mRNA level in p53(-/-) cells. This decrease was reversed by the proteasome inhibitors MG132 and lactacystin, by p19(arf), and by small interfering RNA (siRNA) against MDM2. p21waf1/cip1 bound to MDM2 in vitro and in cells. The p21waf1/cip1-binding-defective mutant of MDM2 was unable to degrade p21waf1/cip1. MDM2 shortened the half-life of both exogenous and endogenous p21waf1/cip1 by 50% and led to the degradation of its lysine-free mutant. Consequently, MDM2 suppressed p21waf1/cip1-induced cell growth arrest of human p53(-/-) and p53(-/-)/Rb(-/-)cells. These results demonstrate that MDM2 directly inhibits p21waf1/cip1 function by reducing p21waf1/cip1 stability in a ubiquitin-independent fashion.     

The RASSF6 Tumor Suppressor Protein Regulates Apoptosis and the Cell Cycle via MDM2 Protein and p53 Protein

Ras association domain family (RASSF) 6 is a member of the C-terminal RASSF proteins such as RASSF1A and RASSF3. RASSF6 is involved in apoptosis in various cells under miscellaneous conditions, but it remains to be clarified how RASSF6 exerts tumor-suppressive roles. We reported previously that RASSF3 facilitates the degradation of MDM2, a major E3 ligase of p53, and stabilizes p53 to function as a tumor suppressor. In this study, we demonstrate that RASSF6 overexpression induces G₁/S arrest in p53-positive cells. Its depletion prevents UV- and VP-16-induced apoptosis and G₁/S arrest in HCT116 and U2OS cells. RASSF6-induced apoptosis partially depends on p53. RASSF6 binds MDM2 and facilitates its ubiquitination. RASSF6 depletion blocks the increase of p53 in response to UV exposure and up-regulation of p53 target genes. RASSF6 depletion delays DNA repair in UV- and VP-16-treated cells and increases polyploid cells after VP-16 treatment. These findings indicate that RASSF6 stabilizes p53, regulates apoptosis and the cell cycle, and functions as a tumor suppressor. Together with the previous reports regarding RASSF1A and RASSF3, the stabilization of p53 may be the common function of the C-terminal RASSF proteins.     

MDM2--master regulator of the p53 tumor suppressor protein

MDM2 is an oncogene that mainly functions to modulate p53 tumor suppressor activity. In normal cells the MDM2 protein binds to the p53 protein and maintains p53 at low levels by increasing its susceptibility to proteolysis by the 26S proteosome. Immediately after the application of cellular stress, the ability of MDM2 to bind to p53 is blocked or altered in a fashion that prevents MDM2-mediated degradation. As a result, p53 levels rise, causing cell cycle arrest or apoptosis. In this review, we present evidence for the existence of three highly conserved regions (CRs) shared by MDM2 proteins and MDMX proteins of different species. These highly conserved regions encompass residues 42-94 (CR1), 301-329 (CR2), and 444-483 (CR3) on human MDM2. These three domains are respectively important for binding p53, for binding the retinoblastoma protein, and for transferring ubiquitin to p53. This review discusses the major milestones uncovered in MDM2 research during the past 12 years and potential uses of this knowledge in the fight against cancer.     

DNA damage-induced MDMX degradation is mediated by MDM2

Although genetic studies have demonstrated that MDMX is essential to maintain p53 activity at low levels in non-stressed cells, it is unknown whether MDMX regulates p53 activation by DNA damage. We show here that DNA damage-induced p53 induction is associated with rapid down-regulation of the MDMX protein. Significantly, interference with MDMX down-regulation results in the suppression of p53 activation by genotoxic stress. We also demonstrate that DNA damage-induced MDMX reduction is mediated by MDM2, which targets MDMX for proteasomal degradation by a distinct mechanism that permits preferential MDMX degradation and therefore ensures optimal p53 activation.     

Role of p53 in cell cycle regulation and apoptosis following exposure to proteasome inhibitors.

In this study, we explored what effect inhibitors of the 26S proteasome have on cell cycle distribution and induction of apoptosis in human skin fibroblasts and colon cancer cells differing in their p53 status. We found that proteasome inhibition resulted in nuclear accumulation of p53. This was surprising because it is thought that the degradation of p53 is mediated by cytoplasmic 26S proteasomes. Nuclear accumulation of p53 was accompanied by the induction of both p21WAF1 mRNA and protein as well as a decrease in cells entering S phase. Interestingly, cells with compromised p53 function showed a marked increase in the proportion of cells in the G2-M phase of the cell cycle and an attenuated induction of apoptosis after proteasome inhibition. Taken together, our results suggest that proteasome inhibition results in nuclear accumulation of p53 and a p53-stimulated induction of both G1 arrest and apoptosis.     

Mutual dependence of MDM2 and MDMX in their functional inactivation of p53

MDMX, an MDM2-related protein, has emerged as yet another essential negative regulator of p53 tumor suppressor, since loss of MDMX expression results in p53-dependent embryonic lethality in mice. However, it remains unknown why neither homologue can compensate for the loss of the other. In addition, results of biochemical studies have suggested that MDMX inhibits MDM2-mediated p53 degradation, thus contradicting its role as defined in gene knockout experiments. Using cells deficient in either MDM2 or MDMX, we demonstrated that these two p53 inhibitors are in fact functionally dependent on each other. In the absence of MDMX, MDM2 is largely ineffective in down-regulating p53 because of its extremely short half-life. MDMX renders MDM2 protein sufficiently stable to function at its full potential for p53 degradation. On the other hand, MDMX, which is a cytoplasmic protein, depends on MDM2 to redistribute into the nucleus and be able to inactivate p53. We also showed that MDMX, when exceedingly overexpressed, inhibits MDM2-mediated p53 degradation by competing with MDM2 for p53 binding. Our findings therefore provide a molecular basis for the nonoverlapping activities of these two p53 inhibitors previously revealed in genetic studies.     

MDMX overexpression prevents p53 activation by the MDM2 inhibitor Nutlin

The p53 tumor suppressor plays a key role in maintaining genomic stability and protection against malignant transformation. MDM2 and MDMX are both p53-binding proteins that regulate p53 stability and activity. Recent development of the MDM2 inhibitor Nutlin 3 has greatly facilitated functional analysis of MDM2-p53 binding. We found that although MDMX is homologous to MDM2 and binds to the same region on p53 N terminus, Nutlin does not disrupt p53-MDMX interaction. The ability of Nutlin to activate p53 is compromised in tumor cells overexpressing MDMX. Combination of Nutlin with MDMX siRNA resulted in synergistic activation of p53 and growth arrest. These results suggest that MDMX is also a valid target for p53 activation in tumor cells. Development of novel compounds that are MDMX-specific or optimized for dual-inhibition of MDM2 and MDMX are necessary to achieve full activation of p53 in tumor cells.     

Induction of p53-, MDM2-, and WAF1/CIP1-like Molecules in Insect Cells by DNA-Damaging Agents

Cellular responses following DNA damage are ubiquitous in the biological world. In response to DNA damage, cell cycle checkpoints are activated, which delay cell cycle progression and most likely serve to allow time for repair. One important checkpoint in mammalian cells, activated in the G₁ phase of the cell cycle, is dependent on the p53 tumor suppressor gene product. While p53 is responsible for inducing G₁ arrest, the product of the MDM2 gene is believed to alleviate the arrest, allowing continuation of the cell cycle after a transient delay. Inasmuch as MDM2 and WAF1/CIP1 are transactivated by p53, while MDM2 binds to and modulates the activity of p53, a "feedback loop" is thus created. This pathway has been highly conserved in mammalian cells, but its presence outside of vertebrates is unknown. By using human MDM2 and WAF1/CIP1 cDNA probes, and monoclonal antibodies to p53 and Mdm2, we demonstrate in insect cell lines evidence for the existence of p53-, MDM2-, and WAF1/CIP1 -like molecules and a p53-regulated pathway following treatment by DNA-damaging agents.     

Effects of p21Cip1/Waf1 at Both the G1/S and the G2/M Cell Cycle Transitions: pRb Is a Critical Determinant in Blocking DNA Replication and in Preventing Endoreduplication

It has been proposed that the functions of the cyclin-dependent kinase inhibitors p21^Cip1/Waf1 and p27^Kip1 are limited to cell cycle control at the G₁/S-phase transition and in the maintenance of cellular quiescence. To test the validity of this hypothesis, p21 was expressed in a diverse panel of cell lines, thus isolating the effects of p21 activity from the pleiotropic effects of upstream signaling pathways that normally induce p21 expression. The data show that at physiological levels of accumulation, p21, in addition to its role in negatively regulating the G₁/S transition, contributes to regulation of the G₂/M transition. Both G₁- and G₂-arrested cells were observed in all cell types, with different preponderances. Preponderant G₁ arrest in response to p21 expression correlated with the presence of functional pRb. G₂ arrest was more prominent in pRb-negative cells. The arrest distribution did not correlate with the p53 status, and proliferating-cell nuclear antigen (PCNA) binding activity of p21 did not appear to be involved, since p27, which lacks a PCNA binding domain, produced similar arrest Bs. In addition, DNA endoreduplication occurred in pRb-negative but not in pRb-positive cells, suggesting that functional pRb is necessary to prevent DNA replication in p21 G₂-arrested cells. These results suggest that the primary target of the Cip/Kip family of inhibitors leading to efficient G₁ arrest as well as to blockade of DNA replication from either G₁ or G₂ phase is the pRb regulatory system. Finally, the tendency of Rb-negative cells to undergo endoreduplication cycles when p21 is expressed may have negative implications in the therapy of Rb-negative cancers with genotoxic agents that activate the p53/p21 pathway.