A p38-dependent pathway regulates DeltaNp63 DNA binding to p53-dependent promoters in UV-induced apoptosis of keratinocytes.

The p53 protein plays a pivotal role in determining the quality of the response to DNA damage through its transcriptional activity. Upon DNA damage, p53 is activated by post-translational modifications, binds its cognate sequences on the promoters of its target genes and stimulates transcription. In proliferating keratinocytes, the activity of p53 is blunted by its inhibitor DeltaNp63alpha. Here, we describe a novel mechanism through which DeltaNp63 functions in order to prevent the survival and propagation of ultraviolet (UV)-damaged keratinocytes. We found that UVB stimulation induces the rapid phosphorylation of DeltaNp63, which precedes DeltaNp63 transcriptional downregulation and protein degradation, which is mediated by the p38 MAPK. Phosphorylated DeltaNp63 has a lower affinity for p53REs and detaches from cell cycle arrest and apoptotic promoters, thus allowing the rapid activation of p53-dependent transcriptional apoptotic program.

The p73 gene is an anti-tumoral target of the RARbeta/gamma-selective retinoid tazarotene.

Tazarotene, a member of the new class of acetylenic retinoids, has been shown to be effective in the treatment of several hyperproliferative skin diseases, including non-melanoma skin cancer. Its effectiveness is thought to rely on the ability to activate retinoic acid receptors beta and gamma and to induce a number of downstream anti-proliferative genes. Here, we show that the p53-related gene p73 is a target of tazarotene. Indeed, tazarotene modulates the expression of the p73 gene in immortalized keratinocyte cell lines by inducing the pro-apoptotic and anti-proliferative TAp73 isoforms and by repressing the anti-apoptotic and pro-proliferative DeltaNp73 isoforms. This occurs at the transcriptional level through a coordinated action on P1p73 and P2p73 promoters that control the expression of TA and DeltaN isoforms, respectively. The selective downregulation of DeltaNp73 expression by small interfering RNA led to an enhancement of tazarotene-induced bax activation and apoptosis, whereas the downregulation of both TA and DeltaN isoforms impairs tazarotene-mediated apoptosis. These results indicate the relevance of p73 gene products in tazarotene-induced growth inhibition and effectiveness in the treatment of skin tumors.

Cross-talks in the p53 family: deltaNp63 is an anti-apoptotic target for deltaNp73alpha and p53 gain-of-function mutants.

The p53 family of transcription factors plays a pivotal role in the control of the cellular response to DNA damaging agents. In addition to pro-apoptotic molecules such as p53, TAp73 and TAp63, this gene family also encodes for the anti-apoptotic molecules deltaNp73, deltaNp63, deltaNp53, and p53 mutants are often found in tumor cells, that have the role to limit and to modulate the pro-apoptotic side of the family. The ratio between the different members of the family is critical to make the life or death decision following DNA damage and is tightly regulated by post-translational and transcriptional mechanisms. In this study we have uncovered a novel positive feedback that involves the transcriptional activation of the anti-apoptotic molecule deltaNp63 by the anti-apoptotic molecules deltaNp73 and mutant p53, and that is put into motion upon treatment with a subset of DNA damaging agents such as Doxorubicin and 5-FU. DeltaNp73 and mutant p53 associate with the deltaNp63 promoter inducing its transcription and this is enhanced by doxorubicin treatment. Furthermore we have observed that deltaNp73- and mutp53-mediated activation of the deltaNp63 promoter requires the functionality of the proximal CCAAT boxes of this promoter, being hampered by mutation of CCAAT boxes or by dominant negative NFYA expression. This mechanism may serve as an additional control of the response of a normal cell to DNA damage or as an anti-apoptotic barrier of cancer cells subjected to DNA damage.