Defects in transcription coupled repair interfere with expression of p90(MDM2) in response to ultraviolet light.

Ultraviolet (UV) irradiation transiently stabilizes p53 through a mechanism that may require a decrease in the activity of the ubiquitin ligase, p90(MDM2). Conversely, the recovery of low levels of p53 following UV exposure may depend on an increase in p90(MDM2). The level of p90(MDM2) is increased by UV light following the p53-dependent induction of an internal mdm2 promoter, P2. If this induction of mdm2 were critical for the recovery of low levels of p53 following UV exposure, defects in mdm2's transcription would result in a prolonged increase in p53. Cells defective in transcription coupled repair (TCR) maintain high levels of p53 for a prolonged period following UV exposure. Such cells also have defects in general transcription after UV irradiation. We investigated whether TCR-deficient cells express diminished levels of mdm2 mRNA and p90(MDM2) following UV exposure. We found that transcription of mdm2 was reduced in TCR-deficient cells. The uninducible mdm2 promoter, P1, was more sensitive to the inhibitory effects of UV irradiation than the P2 promoter. The decrease in transcription from the P1 promoter was sufficient to reduce the level of p90(MDM2) and correlated with a prolonged increase in p53. Thus, p53-independent transcription of mdm2 appears critical to p53's regulation.

Characterization of the 5' and 3' untranslated regions in murine mdm2 mRNAs.

The murine double minute 2 (mdm2) gene is essential for embryogenesis in mice that express the p53 tumor suppressor protein. Mdm2 levels must be regulated tightly because overexpression of mdm2 contributes to tumorigenesis. We investigated whether the 5' and 3' untranslated regions (UTRs) of murine mdm2 affect the expression of MDM2 proteins. Induction of mdm2 expression by p53 results in synthesis of an mdm2 mRNA with a short 5' UTR. The long 5' UTR increases internal initiation of translation of a minor MDM2 protein, p76(MDM2), without affecting the efficiency of translation of the full-length p90(MDM2). We discovered two alternative 3' untranslated regions in murine mdm2 mRNA expressed in the testis. The longer 3' UTR contains a consensus instability element, but mdm2 mRNAs containing the long and short 3' UTRs have comparable half-lives. The 3' UTRs do not affect either initiation codon use or translation efficiency. Thus, the murine 5' UTR, but not the 3'UTR, influences the ratio of the two MDM2 proteins but neither UTR affects MDM2 abundance significantly.

p76(MDM2) inhibits the ability of p90(MDM2) to destabilize p53.

The mdm2 oncogene encodes p90(MDM2), which binds to and inactivates the p53 tumor suppressor protein. p90(MDM2) inhibits p53 by blocking the transcriptional activation domain of p53 as well as by stimulating its degradation. Recently, we showed that another product of the wild-type mdm2 gene, p76(MDM2), lacks the first 49 amino acids of p90(MDM2) and cannot bind p53. Here, we report that, like p90(MDM2), p76(MDM2) is expressed in both the nuclear and cytoplasmic compartments. Overexpression of p76(MDM2) antagonizes the ability of p90(MDM2) to stimulate the degradation of p53 and leads to an increase in the levels and activity of p53. Seven murine tissues express an alternatively spliced mdm2 mRNA that can encode p76(MDM2) but not p90(MDM2), as well as the normally spliced mdm2 mRNA that encodes both MDM2 proteins. All seven tissues express both MDM2 proteins. p90(MDM2) is much more abundant than p76(MDM2) in the testis, brain, heart, and kidney. However, in those tissues known to undergo p53-mediated apoptosis in response to gamma-irradiation, the thymus, spleen, and intestine, the levels of the MDM2 proteins are roughly equivalent. Our results indicate that the ratio of the two MDM2 proteins may regulate the response of tissues to DNA damage.

The p53 tumor suppressor protein does not regulate expression of its own inhibitor, MDM2, except under conditions of stress.

MDM2 is an important regulator of the p53 tumor suppressor protein. MDM2 inhibits p53 by binding to it, physically blocking its ability to transactivate gene expression, and stimulating its degradation. In cultured cells, mdm2 expression can be regulated by p53. Hence, mdm2 and p53 can interact to form an autoregulatory loop in which p53 activates expression of its own inhibitor. The p53/MDM2 autoregulatory loop has been elucidated within cultured cells; however, regulation of mdm2 expression by p53 has not been demonstrated within intact tissues. Here, we examine the role of p53 in regulating mdm2 expression in vivo in order to test the hypothesis that the p53/MDM2 autoregulatory loop is the mechanism by which low levels of p53 are maintained. We demonstrate that basal expression of mdm2 in murine tissues is p53 independent, even in tissues that express functional p53. Transcription of mdm2 is induced in a p53-dependent manner following gamma irradiation, indicating that p53 regulates mdm2 expression in vivo following a stimulus. The requirement for a stimulus to activate p53-dependent regulation of mdm2 expression in vivo appeared to differ from the situation in early-passage mouse embryo fibroblasts, where mdm2 expression is enhanced by the presence of p53. Analysis of mdm2 expression in intact and dispersed embryos revealed that establishment of mouse embryo fibroblasts in culture induces p53-dependent mdm2 expression, suggesting that an unknown stimulus activates p53 function in cultured cells. Together, these results indicate that p53 does not regulate expression of its own inhibitor, except in response to stimuli.

Apoptotic suppression by baculovirus P35 involves cleavage by and inhibition of a virus-induced CED-3/ICE-like protease.

Baculovirus p35 prevents programmed cell death in diverse organisms and encodes a protein inhibitor (P35) of the CED-3/interleukin-1 beta-converting enzyme (ICE)-related proteases. By using site-directed mutagenesis, we have identified P35 domains necessary for suppression of virus-induced apoptosis in insect cells, the context in which P35 evolved. During infection, P35 was cleaved within an essential domain at or near the site DQMD-87G required for cleavage by CED-3/ICE family proteases. Cleavage site substitution of alanine for aspartic acid at position 87 (D87A) of the P1 residue abolished P35 cleavage and antiapoptotic activity. Although the P4 residue substitution D84A also caused loss of apoptotic suppression, it did not eliminate cleavage and suggested that P35 cleavage is not sufficient for antiapoptotic activity. Apoptotic insect cells contained a CED-3/ICE-like activity that cleaved in vitro-translated P35 and was inhibited by recombinant wild-type P35 but not P1- or P4-mutated P35. Thus, baculovirus infection directly or indirectly activates a novel CED-3/ICE-like protease that is inhibited by P35, thereby preventing virus-induced apoptosis. Our findings confirmed the inhibitory activity of P35 towards the CED-3/ICE protease, including recombinant mammalian enzymes, and were consistent with a mechanism involving P35 stoichiometric interaction and cleavage. P35's inhibition of phylogenetically diverse proteases accounts for its general effectiveness as an apoptotic suppressor.