Phosphorylation of Tip60 by GSK-3 determines the induction of PUMA and apoptosis by p53

Activation of p53 by DNA damage results in either cell-cycle arrest, allowing DNA repair and cell survival, or induction of apoptosis. As these opposite outcomes are both mediated by p53 stabilization, additional mechanisms to determine this decision must exist. Here, we show that glycogen synthase kinase-3 (GSK-3) is required for the p53-mediated induction of the proapoptotic BH3 only-protein PUMA, an essential mediator of p53-induced apoptosis. Inhibition of GSK-3 protected from cell death induced by DNA damage and promoted increased long-term cell survival. We demonstrate that GSK-3 phosphorylates serine 86 of the p53-acetyltransferase Tip60. A Tip60(S86A) mutant was less active to induce p53 K120 acetylation, histone 4 acetylation, and expression of PUMA. Our data suggest that GSK-3 mediated Tip60S86 phosphorylation provides a link between PI3K signaling and the choice for or against apoptosis induction by p53.     

Stabilization of p21 (Cip1/WAF1) following Tip60-dependent acetylation is required for p21-mediated DNA damage response

The molecular mechanisms controlling post-translational modifications of p21 have been pursued assiduously in recent years. Here, utilizing mass-spectrometry analysis and site-specific acetyl-p21 antibody, two lysine residues of p21, located at amino-acid sites 161 and 163, were identified as Tip60-mediated acetylation targets for the first time. Detection of adriamycin-induced p21 acetylation, which disappeared after Tip60 depletion with concomitant destabilization of p21 and disruption of G1 arrest, suggested that Tip60-mediated p21 acetylation is necessary for DNA damage-induced cell-cycle regulation. The ability of 2KQ, a mimetic of acetylated p21, to induce cell-cycle arrest and senescence was significantly enhanced in p21 null MEFs compared with those of cells expressing wild-type p21. Together, these observations demonstrate that Tip60-mediated p21 acetylation is a novel and essential regulatory process required for p21-dependent DNA damage-induced cell-cycle arrest.     

PIASy-mediated Tip60 sumoylation regulates p53-induced autophagy

Posttranslational modifications of p53 integrate diverse stress signals and regulate its activity, but their combinatorial contribution to overall p53 function is not clear. We investigated the roles of lysine (K) acetylation and sumoylation on p53 and their relation to apoptosis and autophagy. Here we describe the collaborative role of the SUMO E3 ligase PIASy and the lysine acetyltransferase Tip60 in p53-mediated autophagy. PIASy binding to p53 and PIASy-activated Tip60 lead to K386 sumoylation and K120 acetylation of p53, respectively. Even though these two modifications are not dependent on each other, together they act as a “binary death signal” to promote cytoplasmic accumulation of p53 and execution of PUMA-independent autophagy. PIASy-induced Tip60 sumoylation augments p53 K120 acetylation and apoptosis. In addition to p14^ARF inactivation, impairment in this intricate signaling may explain why p53 mutations are not found in nearly 50% of malignancies.     

PIASy-mediated Tip60 sumoylation regulates p53-induced autophagy

Posttranslational modifications of p53 integrate diverse stress signals and regulate its activity, but their combinatorial contribution to overall p53 function is not clear. We investigated the roles of lysine (K) acetylation and sumoylation on p53 and their relation to apoptosis and autophagy. Here we describe the collaborative role of the SUMO E3 ligase PIASy and the lysine acetyltransferase Tip60 in p53-mediated autophagy. PIASy binding to p53 and PIASy-activated Tip60 lead to K386 sumoylation and K120 acetylation of p53, respectively. Even though these two modifications are not dependent on each other, together they act as a “binary death signal” to promote cytoplasmic accumulation of p53 and execution of PUMA-independent autophagy. PIASy-induced Tip60 sumoylation augments p53 K120 acetylation and apoptosis. In addition to p14^ARF inactivation, impairment in this intricate signaling may explain why p53 mutations are not found in nearly 50% of malignancies.     

Deubiquitination of Tip60 by USP7 Determines the Activity of the p53-Dependent Apoptotic Pathway

Tip60 is an essential acetyltransferase required for acetylation of nucleosomal histones and other nonhistone proteins. Tip60 acetylates the p53 tumor suppressor at lysine 120 (K120), a modification essential for p53-dependent induction of PUMA and apoptosis. It is known that Tip60 is turned over in cells by the ubiquitin-proteasome system. However, the deubiquitinase activity for stabilizing Tip60 is unknown. Here we show that USP7 interacts with and deubiquitinates Tip60 both in vitro and in vivo. USP7 deubiquitinase activity is required for the stabilization of Tip60 in order to operate an effective p53-dependent apoptotic pathway in response to genotoxic stress. Inhibiting USP7 with the small-molecule inhibitor {"type":"entrez-protein","attrs":{"text":"P22077","term_id":"134707","term_text":"P22077"}}P22077 attenuates the p53-dependent apoptotic pathway by destabilizing Tip60. {"type":"entrez-protein","attrs":{"text":"P22077","term_id":"134707","term_text":"P22077"}}P22077, however, is still cytotoxic, and this is partly due to destabilization of Tip60.     

The WTX tumor suppressor enhances p53 acetylation by CBP/p300

WTX encodes a tumor suppressor, frequently inactivated in Wilms tumor, with both plasma membrane and nuclear localization. WTX has been implicated in β-catenin turnover, but its effect on nuclear proteins is unknown. We report an interaction between WTX and p53, derived from the unexpected observation of WTX, p53, and E1B 55K colocalization within the characteristic cytoplasmic body of adenovirus-transformed kidney cells. In other cells without adenovirus expression, the C-terminal domain of WTX binds to the DNA-binding domain of p53, enhances its binding to CBP, and increases CBP/p300-mediated acetylation of p53 at Lys 373/382. WTX knockdown accelerates CBP/p300 protein turnover and attenuates this modification of p53. In p53-reconstitution experiments, cell-cycle arrest, apoptosis, and p53 target-gene expression are suppressed by depletion of WTX. Together, these results suggest that WTX modulates p53 function, in part through regulation of its activator CBP/p300.     

Negative Regulation of the Acetyltransferase TIP60-p53 Interplay by UHRF1 (Ubiquitin-like with PHD and RING Finger Domains 1)

Numerous studies indicate the importance of acetylation in p53-mediated stress responses upon DNA damage. We and others previously showed that TIP60 (Tat-interacting protein of 60 kDa)-mediated acetylation of p53 at K120 is crucial for p53-dependent apoptotic responses. Nevertheless, it remains unclear how TIP60-mediated effects on p53 are dynamically regulated in vivo. Here, we report that UHRF1 (ubiquitin-like with PHD and RING finger domains 1) interacts with TIP60 both in vitro and in vivo and induces degradation-independent ubiquitination of TIP60. Moreover, UHRF1 expression markedly suppresses the ability of TIP60 to acetylate p53. In contrast, RNAi-mediated knockdown of UHRF1 increases the endogenous levels of p53 acetylation at K120 and p53-mediated apoptosis is significantly enhanced in UHRF1-depleted cells. To elucidate the mechanisms of this regulation, we found that the interaction between TIP60 and p53 is severely inhibited in the presence of UHRF1, suggesting that UHRF1 modulates TIP60-mediated functions in both K120 acetylation-dependent and -independent manners. Consistent with this notion, UHRF1 knockdown promotes activation of p21 and PUMA but not MDM2. These findings demonstrate that UHRF1 is a critical negative regulator of TIP60 and suggest that UHRF1-mediated effects on p53 may contribute, at least in part, to its role in tumorigenesis.     

The p53-inducible E3 ubiquitin ligase p53RFP induces p53-dependent apoptosis

Recently, it has been shown that really interesting new gene (RING)-in between ring finger (IBR)-RING domain-containing proteins, such as Parkin and Parc, are E3 ubiquitin ligases and are involved in regulation of apoptosis. In this report, we show that p53-inducible RING-finger protein (p53RFP), a p53-inducible E3 ubiquitin ligase, induces p53-dependent but caspase-independent apoptosis. p53RFP contains an N-terminal RING-IBR-RING domain and an uncharacterized, evolutionally highly conserved C-terminal domain. p53RFP interacts with E2 ubiquitin-conjugating enzymes UbcH7 and UbcH8 but not with UbcH5, and this interaction is mediated through the RING-IBR-RING domain of p53RFP. Interestingly, the conserved C-terminal domain of p53RFP is required and sufficient for p53RFP-mediated apoptosis, suggesting p53RFP-mediated apoptosis does not require its E3 ubiquitin ligase activity. Together with a recent report showing that p53RFP is involved in ubiquitination and degradation of p21, a p53 downstream protein promoting growth arrest and antagonizing apoptosis, our findings suggest that p53RFP is involved in switching a cell from p53-mediated growth arrest to apoptosis.     

Deacetylation of the DNA-binding domain regulates p53-mediated apoptosis

In unstressed cells, the p53 tumor suppressor is highly unstable. DNA damage and other forms of cellular stress rapidly stabilize and activate p53. This process is regulated by a complex array of post-translational modifications that are dynamically deposited onto p53. Recent studies show that these modifications orchestrate p53-mediated processes such as cell cycle arrest and apoptosis. Cancer cells carry inherent genetic damage, but avoid arrest and apoptosis by inactivating p53. Defining the enzymatic machinery that regulates the stress-induced modification of p53 at single-residue resolution is critical to our understanding of the biochemical mechanisms that control this critical tumor suppressor. Specifically, acetylation of p53 at lysine 120, a DNA-binding domain residue mutated in human cancer, is essential for triggering apoptosis. Given the oncogenic properties of deacetylases and the success of deacetylase inhibitors as anticancer agents, we investigated the regulation of Lys(120) deacetylation using pharmacologic and genetic approaches. This analysis revealed that histone deacetylase 1 is predominantly responsible for the deacetylation of Lys(120). Furthermore, treatment with the clinical-grade histone deacetylase inhibitor entinostat enhances Lys(120) acetylation, an event that is mechanistically linked to its apoptotic effect. These data expand our understanding of the mechanisms controlling p53 function and suggest that regulation of p53 modification status at single-residue resolution by targeted therapeutics can selectively alter p53 pathway function. This knowledge may impact the rational application of deacetylase inhibitors in the treatment of human cancer.     

Expression of RB C pocket fragments in HSF induces delayed cell cycle progression and sensitizes to apoptosis upon cellular stresses

The retinoblastoma protein (RB) plays an important role in growth suppression through the formation of multiple protein complexes with its target proteins using A/B and C pockets. Even though the A/B and C pockets co-operate for growth suppression, the function of RB in growth arrest is inhibited by the coexpression of RB C fragments with full length RB in the absence of p53, which implies that C pocket fragments are likely to act as a dominant-negative inhibitor of RB function. In contrast, the loss of the RB functions in the presence of p53 triggers a cell cycle arrest or apoptosis by p53-dependent pathways. Thus, it still remains to be elucidated whether the expression of RB C pocket fragments in the presence of p53 induces delayed cell cycle progression and sensitizes cells to apoptosis through p53-dependent pathways. Our results show that the expression of RB C pocket fragments not only induces delayed cell cycle progression, which is mediated by the down-regulation of cyclin A, cyclin E, and E2F-1, but also sensitizes cells to apoptosis through p53-dependent pathways.     

Hzf Determines cell survival upon genotoxic stress by modulating p53 transactivation

A critical unresolved issue about the genotoxic stress response is how the resulting activation of the p53 tumor suppressor can lead either to cell-cycle arrest and DNA repair or to apoptosis. We show here that hematopoietic zinc finger (Hzf), a zinc-finger-containing p53 target gene, modulates p53 transactivation functions in an autoregulatory feedback loop. Hzf is induced by p53 and binds to its DNA-binding domain, resulting in preferential transactivation of proarrest p53 target genes over its proapoptotic target genes. Thus, p53 activation results in cell-cycle arrest in Hzf wild-type MEFs, while in Hzf(-/-) MEFs, apoptosis is induced. Exposure of Hzf null mice to ionizing radiation resulted in enhanced apoptosis in several organs, as compared to in wild-type mice. These findings provide novel insights into the regulation of p53 transactivation function and suggest that Hzf functions as a key player in regulating cell fate decisions in response to genotoxic stress.     

p53蛋白泛素化修饰的研究进展

p53具有抑制肿瘤细胞增殖的作用,但是细胞内p53蛋白的堆积反而加速细胞衰老或凋亡,因此对p53进行严格的调控显得格外重要.泛素化、磷酸化和乙酰化是p53蛋白最主要的几种修饰形式,但近来研究表明泛素化对p53调控发挥着中心作用.MDM2是主要的负调节因子,其具有泛素连接酶的活性,早先的研究认为MDM2的作用主要是特异性结合p53并介导其在蛋白酶作用下降解,但近来的研究发现MDM2还可以介导p53的核-浆交换,这种现象在DNA损伤时尤为明显.推测MDM2介导p53的泛素化在体内可能发挥着多种调控功能.     

Role of the histone acetyl transferase Tip60 in the p53 pathway

The histone acetyl transferase Tip60 (HTATIP) shares many properties with the tumor suppressor p53 (TP53). Both proteins are involved in the cellular response to DNA damage, are subjected to proteasomal digestion following Mdm2-mediated ubiquitination, and accumulate after UV irradiation. We found here that knock-down of Tip60 affects the p53-dependent response following actinomycin D treatment, most likely because it inhibits p21 (CDKN1A) accumulation. Moreover, Tip60 is required for p53 to activate the endogenous p21 promoter, suggesting that it functions as a p53 co-activator. However, we also found that knock-down of Tip60 increases the turnover rate of p53 under normal growth conditions. Tip60 interferes with Mdm2-mediated degradation of p53, probably because it affects its subcellular localization. Taken together, our results suggest that Tip60 plays a double role in the p53 pathway: under normal growth conditions, Tip60 contributes to maintain a basal pool of p53 by interfering with its degradation; following DNA damage, Tip60 functions as p53 co-activator. That these two distinct roles are linked during the p53-dependent response is an attractive hypothesis.