RACK1 and Stratifin Target ΔNp63α for a Proteasome Degradation in Head and Neck Squamous Cell Carcinoma Cells upon DNA Damage

P53 family members with a transactivation domain induce cell cycle arrest and promoteapoptosis. However, ΔNp63 isotypes lacking the transactivation (TA)- domain promote cellproliferation and tumorigenesis in vitro and in vivo. Although p53, TAp63 or TAp73 are stabilizedupon DNA damage, we found that the genotoxic stress agents induced a dramatic decrease andphosphorylation of ΔNp63α in squamous cell carcinoma cells. Further work revealed that RACK1physically associated with the p63α C-terminal domain through its WD40 domain. However,stratifin binds with phosphorylated ΔNp63α in response to cisplatin. Upon DNA damage inducedby cisplatin, stratifin mediated a nuclear export of ΔNp63α into cytoplasm and then RACK1targeted latter into a proteasome degradation pathway possibly serving as an E3 ubiquitin ligase.Moreover, siRNA knockdown of both stratifin and RACK1 inhibited a nuclear export and proteindegradation of ΔNp63α, respectively. Our data suggest that modification and down regulation ofΔNp63α is one of the major determinants of the cellular response to DNA damage in human headand neck cancers.     

ΔNp63α Levels Correlate with Clinical Tumor Response to Cisplatin

After exposure to damaging agents, the p53 tumor suppressor is stabilized mediating cell cycle arrest and apoptosis. p53 family member, ΔNp63α promotes cell proliferation and accelerates tumor growth. We previously found that the genotoxic stress agents induced a decrease of ΔNp63α . We further observed that genotoxic stress mediated phosphorylation of ΔNp63α targeting it into proteasome degradation. Here, we found that high ΔNp63 protein levels in primary tumors accurately predicted response to platinum based chemotherapy and a favorable outcome in head and neck cancer patients. Our data suggest that degradation of ΔNp63α is part of the cellular response to DNA damage in head and neck cancers. The findings may have implications for the rational use of DNA damaging agents in human cancer.     

Evaluation of p63 and p73 antibodies for cross-reactivity

The tumor suppressor p53 is commonly mutated in human cancers. However, two homologs of p53, p63 and p73, are frequently over-expressed in tumors and are associated with tumor subtypes, clinical outcomes, and responses to therapy. There are many isoforms of p53, p63, and p73 (the p53 family). Proper detection of and discrimination between the members of this tumor suppressor family in human tissues is of critical importance to cancer research and clinical care. In this study, we assessed the specificity of several commercially available and newly generated p73 antibodies, focusing on antibodies that distinguish between the TAp73 and ?Np73 isoforms by Western analysis, immunohistochemistry, and immunofluorescence. In addition, we found that the pan-p63 and pan-p73 antibodies tested cross-react with p73 and p63 respectively. The results of this study have important implications for analysis of p63 and p73 expression and co-expression in human tumors, and for potential use of these reagents in molecular diagnostics and therapeutic decision-making.     

TAp73/Delta Np73 influences apoptotic response, chemosensitivity and prognosis in hepatocellular carcinoma

We investigated the mechanisms by which TAp73 beta and dominant-negative p73 (Delta Np73) regulate apoptosis. TAp73 beta transactivated the CD95 gene via the p53-binding site in the first intron. In addition, TAp73 beta induced expression of proapoptotic Bcl-2 family members and led to apoptosis via the mitochondrial pathway. Endogenous TAp73 was upregulated in response to DNA damage by chemotherapeutic drugs. On the contrary, DeltaNp73 conferred resistance to chemotherapy. Inhibition of CD95 gene transactivation was one mechanism by which DeltaNp73 functionally inactivated the tumor suppressor action of p53 and TAp73 beta. Concomitantly, DeltaNp73 inhibited apoptosis emanating from mitochondria. Thus, DeltaNp73 expression in tumors selects against both the death receptor and the mitochondrial apoptosis activity of TAp73 beta. The importance of these data is evidenced by our finding that upregulation of DeltaNp73 in hepatocellular carcinoma patients correlates with reduced survival. Our data indicate that Delta Np73 is an important gene in hepatocarcinogenesis and a relevant prognostic factor.     

In good times and bad: p73 in cancer

It is widely accepted in cancer biology that p53 has a tumor suppressive activity, which is lost during tumorigenesis most frequently by mutations in the p53 gene. The discovery of p73 as the first homologue of p53 raised immediate expectations about p53-like tumor suppressor activities. Although tumors show changes in the expression level of p73 and differences in the expression pattern of p73 isoforms, mutations are not commonly observed making it difficult to infer p73's role in tumorigenesis. An experimental model of human cell transformation closely mimics the expression changes observed in cancer patients and provides novel insights into the regulation and function of p73 in the various steps on the road to malignant transformation. p53-like isoforms of p73 (TAp73) are upregulated early during the transformation process in response to RB pathway alterations and block progression to the fully transformed state. Antagonists of TAp73 such as the dominant-negative p73 protein ΔNp73 overcome this block and pave the way to full transformation. Here we review these findings in the context of patient data and recent advances on molecular aspects of p73 function and discuss the implications for p73 as a target for cancer therapy.     

Mammary epithelial cell polarity is regulated differentially by p73 isoforms via epithelial-to-mesenchymal transition

p73 is expressed as TA and ΔN isoforms, both of which are implicated in tumor suppression and/or promotion. To address how p73 possesses these opposing functions, we developed three-dimensional culture of MCF10A cells, which undergo cell morphogenesis to form polarized spheroids with hollow lumen similar to normal mammary acini in vivo. Here, we showed that upon knockdown of p73, particularly TAp73 but not ΔNp73, MCF10A cells formed irregular and near-normal acini without hollow lumen in three-dimensional culture. We also found that upon knockdown of p73 or TAp73, but not ΔNp73, MCF10A cells underwent epithelial-to-mesenchymal transition (EMT) via down-regulation of E-cadherin coupled with up-regulation of β-catenin and laminin V. In addition, we found that Snail-1, Slug, and Twist, all of which are known to act as EMT inducers by repressing E-cadherin expression, were increased markedly upon knockdown of p73 and TAp73 but little if any by ΔNp73. Furthermore, we showed that knockdown of p73 or TAp73 in MCF10A cells led to a marked increase in cell proliferation and migration. Together, our data suggest that TAp73 is necessary for maintaining normal cell polarity by suppressing EMT.     

p73 induces apoptosis by different mechanisms

p73, like its homologue, the tumor suppressor p53, is able to induce apoptosis in several cell types. This property is important for the involvement of p73 in cancer development and therapy. However, in contrast with p53, the TAp73 gene has two distinct promoters coding for two protein isoforms with opposite effects: while the transactivation proficient TAp73 shows pro-apoptotic effects, the amino-terminal-deleted DeltaNp73 has an anti-apoptotic function. Indeed, the relative expression of these two proteins is related to the prognosis of several cancers. Here we discuss recent developments in the control of p73-induced apoptosis. First, TAp73 induces ER stress via the direct transactivation of Scotin. Second, TAp73 induces the mitochondrial pathway by directly transactivating both Bax and the BH3 only protein PUMA promoters. While the first transactivation is weak, and not sufficient to trigger apoptosis (at least in the in vitro cellular models so far evaluated), the induction of PUMA is strong and lethal. Third, the promoter of the death receptor CD95 contains a p53 responsive element and preliminary experiments suggest that TAp73 also activates the death receptor pathway. In addition, TAp73 is able to transactivate its own second promoter, thus inducing the expression of the anti-apoptotic DeltaNp73 isoform. Therefore, the balance between TAp73 and DeltaNp73 finely regulates cellular sensitivity to death.