p73 and MDM2 confer the resistance of epidermoid carcinoma to cisplatin by blocking p53

p73 responds to DNA damage and exerts its pro-apoptotic function. However, p73 might contribute to the development of drug-resistance in certain tumor cells. In this study, we found that p73 and MDM2 correlate with cisplatin-resistant phenotype of human epidermoid carcinoma-derived cells. p73 and MDM2 were kept at low levels in the cisplatin-sensitive KB-3-1 cells, whereas p53 was induced to be phosphorylated at Ser-15 in response to cisplatin. In contrast, p73 and MDM2 were expressed at higher levels, and cisplatin-mediated p53 phosphorylation was undetectable in the cisplatin-resistant KCP-4 cells. Enforced expression of p73 in KB-3-1 cells caused an accumulation of unphosphorylated form of p53 and MDM2, and conferred the cisplatin resistance. Collectively, our results suggest that a loss of the cisplatin sensitivity is at least in part due to a lack of cisplatin-induced p53 phosphorylation, and p73 might cooperate with MDM2 to be involved in this process.     

Up-regulation of NFkappaB-responsive gene expression by DeltaNp73alpha in p53 null cells

Transactivation domain (TAD)-truncated p73, DeltaNp73, associates with p53, resulting in suppression of p53's functions. Using p53 null cell lines, we examined whether or not DeltaNp73 can regulate gene expression in a p53-independent manner. When DeltaNp73alpha was co-transfected with a luciferase reporter plasmid with various enhancer elements, NFkappaB-responsive luciferase gene expression was selectively up-regulated by DeltaNp73alpha, but not by other p73-isoforms with TAD and DeltaNp73beta. Deletion of the TAD endowed p73alpha with the ability to enhance the responsive gene's expression, but deletion of the N-terminal proline-rich domain (PRD) rendered the TAD-deleted p73alpha inactive. Considering the inability of DeltaNp73beta, which is the C-terminus-truncated form of DeltaNp73alpha, to function, these results indicate that both the PRD and C-terminus are necessary for DeltaNp73alpha to can activate NFkappaB-responsive luciferase expression. Over-expression of p53 suppressed the TAD-truncated p73alpha-mediated luciferase expression, suggesting that p53 interferes with the TAD-truncated p73alpha-mediated activation of NFkappaB. Inhibitors for NFkappaB activation reduced the TAD-truncated p73alpha-dependent NFkappaB-responsive gene expression, indicating that TAD-truncated p73alpha activates NFkappaB as does TNFalpha. In addition to the results obtained in the reporter gene assay, TAD-truncated p73alpha stimulated the translocation of NFkappaB to the nucleus and the expression of an endogenous NFkappaB-responsive gene, Bcl-XL. Taken together, these results demonstrate that TAD-truncated p73alpha can activate NFkappaB.     

GLS2 is transcriptionally regulated by p73 and contributes to neuronal differentiation

The amino acid Glutamine is converted into Glutamate by a deamidation reaction catalyzed by the enzyme Glutaminase (GLS). Two isoforms of this enzyme have been described, and the GLS2 isoform is regulated by the tumor suppressor gene p53. Here, we show that the p53 family member TAp73 also drives the expression of GLS2. Specifically, we demonstrate that TAp73 regulates GLS2 during retinoic acid-induced terminal neuronal differentiation of neuroblastoma cells, and overexpression or inhibition of GLS2 modulates neuronal differentiation and intracellular levels of ATP. Moreover, inhibition of GLS activity, by removing Glutamine from the growth medium, impairs in vitro differentiation of cortical neurons. Finally, expression of GLS2 increases during mouse cerebellar development. Although, p73 is dispensable for the in vivo expression of GLS2, TAp73 loss affects GABA and Glutamate levels in cortical neurons. Together, these findings suggest a role for GLS2 acting, at least in part, downstream of p73 in neuronal differentiation and highlight a possible role of p73 in regulating neurotransmitter synthesis.     

Regulation of HSF1-responsive gene expression by N-terminal truncated form of p73alpha

DNp73 is a transactivation domain (TAD)-truncated form of p73. The ability of DNp73alpha to regulate gene expression was examined using reporter assays with luciferase gene constructs. Among various promoter-regulated reporter genes tested, heat shock factor (HSF)-responsive gene expression was selectively activated by DNp73alpha, but not by other p73-isoforms with TAD and DNp73beta. Deletion of TAD endowed p73alpha with the ability to activate HSF-responsive gene expression, but deletion of N-terminal proline-rich domain (PRD) rendered both DNp73alpha and the TAD-deleted p73alpha inactive. Considering the inability of DNp73beta, which is the C-terminus-truncated form of DNp73alpha, to function, these results indicate that both the PRD and C-terminus are necessary for DNp73alpha to be able to activate the HSF-dependent gene expression. In addition to the reporter gene expression, both DNp73alpha and TAD-deleted p73alpha activated the expression of an endogenous gene, hsp70, corresponding with an increase in the active form of HSF1. Taken together, these results demonstrate that TAD-truncated p73alpha can activate HSF-dependent gene expression via induction of active HSF1.     

p73 deficiency results in impaired self renewal and premature neuronal differentiation of mouse neural progenitors independently of p53

The question of how neural progenitor cells maintain its self-renewal throughout life is a fundamental problem in cell biology with implications in cancer, aging and neurodegenerative diseases. In this work, we have analyzed the p73 function in embryonic neural progenitor cell biology using the neurosphere (NS)-assay and showed that p73-loss has a significant role in the maintenance of neurosphere-forming cells in the embryonic brain. A comparative study of NS from Trp73−/−, p53KO, p53KO;Trp73−/− and their wild-type counterparts demonstrated that p73 deficiency results in two independent, but related, phenotypes: a smaller NS size (related to the proliferation and survival of the neural-progenitors) and a decreased capacity to form NS (self-renewal). The former seems to be the result of p53 compensatory activity, whereas the latter is p53 independent. We also demonstrate that p73 deficiency increases the population of neuronal progenitors ready to differentiate into neurons at the expense of depleting the pool of undifferentiated neurosphere-forming cells. Analysis of the neurogenic niches demonstrated that p73-loss depletes the number of neural-progenitor cells, rendering deficient niches in the adult mice. Altogether, our study identifies TP73 as a positive regulator of self-renewal with a role in the maintenance of the neurogenic capacity. Thus, proposing p73 as an important player in the development of neurodegenerative diseases and a potential therapeutic target.     

From p63 to p53 across p73

Most genes are members of a family. It is generally believed that a gene family derives from an ancestral gene by duplication and divergence. The tumor suppressor p53 was a striking exception to this established rule. However, two new p53 homologs, p63 and p73, have recently been described [1, 2, 3, 4, 5 and 6]. At the sequence level, p63 and p73 are more similar to each other than each is to p53, suggesting the possibility that the ancestral gene is a gene resembling p63/p73, while p53 is phylogenetically younger [1 and 2].

The complexity of the family has also been enriched by the alternatively spliced forms of p63 and p73, which give rise to a complex network of proteins involved in the control of cell proliferation, apoptosis and development [1, 2, 4, 7, 8 and 9].

In this review we will mainly focus on similarities and differences as well as relationships among p63, p73 and p53.     

Accumulation of p27 KIP1 is associated with BMP2-induced growth arrest and neuronal differentiation of human neuroblastoma-derived cell lines

Bone morphogenetic proteins (BMPs) play an essential role in cell fate determination. In this study, we found that BMP2 treatment resulted in growth arrest and differentiation in human neuroblastoma-derived cell lines, SH-SY5Y and RTBM1. Within 30min of BMP2 exposure, phosphorylation of Smad1/5 was observed in these cell lines. In RTBM1 cells, BMP2-induced differentiation was accompanied by a significant decrease in the expression level of DAN, an antagonist of BMP in frog embryos. Immunoblot analysis revealed that BMP2 treatment caused a down-regulation of p53 family members and hence of cyclin-dependent kinase inhibitor p21(WAF1). We found a significant accumulation of p27(KIP1) in response to BMP2, whereas the expression level of Skp2, which is required for ubiquitin-dependent p27(KIP1) degradation, was decreased during this differentiation process. Our results suggest that p27(KIP1) contributes to the BMP-induced growth arrest and neuronal differentiation of neuroblastoma, and BMP treatment might provide a new therapeutic strategy.     

Gene expression changes accompanying p53 activity during estrogen treatment of osteoblasts

Estrogen is known to be anabolic for bone and we have used estrogen treatment as a paradigm to understand how p53 may affect osteoblast differentiation. In previous studies we have shown estrogen treatment to increase p53 functional activity in osteoblasts. Estrogen has been suggested to inhibit apoptosis in osteoblasts. Since the significance of a p53 increase during estrogen treatment is not apparent, we investigated the environment within osteoblasts after treatment with estrogen. We observed two peaks of p53 activity during continuous treatment of 17-[beta]-estradiol (E2) for 72h. The gene expression profile of different cell cycle regulators and apoptosis related genes at different times during treatment with 17-[beta]-estradiol were tested using gene arrays. There was an early increase in expression of several genes involved in apoptosis. This was followed by changes in expression of several genes involved in cell survival and stress response. The second peak of activity was associated with increase in expression of cell cycle regulators. Our results suggest that p53 activity may be a result of activation of several signaling pathways involving apoptosis, cell survival and cell cycle arrest. P53 may have a role in integrating these responses, which eventually results in cell cycle arrest and expression of differentiation markers.     

p63 and p73 expression in extrahepatic bile duct carcinoma and their clinical significance

p53 plays a pivotal role in the prevention of human tumor formation. p73 and p63 are new members of the p53 tumor suppressor family, which are becoming increasingly recognized as important players in human tumorigenesis. However, the roles of these proteins are not well elucidated in extrahepatic bile duct (EBD) carcinoma. We examined expressions of the p63 and p73 genes and proteins in normal biliary epithelia, biliary dysplasias, and EBD carcinomas using immunohistochemistry and RT-PCR analysis. p63 and p73 proteins were overexpressed in 26.3 and 41.0% of EBD carcinomas, respectively. p63 protein expression was more frequent in tumors with vascular invasion (P = 0.002) and distal location (P = 0.04), while p73 expression was more common in cancers with deeper tumor invasion (P = 0.04). Patients with tumors co-expressing both p63 and p73 were found to have a significantly worse overall survival rate compared to those with either p63 or p73 expression (P < 0.05) as determined in univariate and multivariate analyses. Our results strongly imply that the p53 family members have different functions in EBD carcinomas. Our data also indicate that interactions between p63 and p73 play an important role in tumorigenesis of EBD carcinoma.