Distinct regulation of p53 and p73 activity by adenovirus E1A, E1B, and E4orf6 proteins.

Multiple adenovirus (Ad) early proteins have been shown to inhibit transcription activation by p53 and thereby to alter its normal biological functioning. Since these Ad proteins affect the activity of p53 via different mechanisms, we examined whether this inhibition is target gene specific. In addition, we analyzed whether the same Ad early proteins have a comparable effect on transcription activation by the recently identified p53 homologue p73. Our results show that the large E1B proteins very efficiently inhibited the activity of p53 on the Bax, p21(Waf1), cyclin G, and MDM2 reporter constructs but had no effect on the activation of the same reporter constructs by p73, with the exception of some inhibition of the Bax promoter by Ad12 E1B. The repressive effect of the E1A proteins on p53 activity is less than that seen with the large E1B proteins, but the E1A proteins inhibit the activity of both p53 and p73. We could not detect significant inhibition of p53 functions by E4orf6, but a clear repression of the transcription activation by p73 by this Ad early protein was observed. In addition, we found that stable expression of the Ad5 E1A and that of the E1B protein both caused increased p73 protein expression. The large E1B and the E4orf6 proteins together do not target the p73 protein for rapid degradation after adenoviral infection, as has previously been found for the p53 protein, probably because the large E1B protein does not interact with p73. Our results suggest that the p53 and p73 proteins are both inactivated after Ad infection and transformation but via distinct mechanisms.

Adenovirus E1A proteins inhibit activation of transcription by p53.

p53 stimulates the transcription of a number of genes, such as MDM2, Waf1, and GADD45. We and others have shown previously that this activity of p53 can be inhibited by adenovirus type 2 or 12 large E1B proteins. Here we show that the adenovirus E1A proteins also can repress the stimulation of transcription by p53, both in transient transfections and in stably transfected cell lines. The inhibition by E1A occurs without a significant effect on the DNA-binding capacity of p53. Furthermore, the activity of a fusion protein containing the N-terminal part of p53 linked to the GAL4 DNA-binding domain can be suppressed by E1A. This indicates that E1A affects the transcription activation domain of p53, although tryptic phosphopeptide mapping revealed that the level of phosphorylation of this domain does not change significantly in E1A-expressing cell lines. Gel filtration studies, however, showed p53 to be present in complexes of increased molecular weight as a result of E1A expression. Apparently, E1A can cause increased homo- or hetero-oligomerization of p53, which might result in the inactivation of the transcription activation domain of p53. Additionally, we found that transfectants stably expressing E1A have lost the ability to arrest in G1 after DNA damage, indicating that E1A can abolish the normal biological function of p53.

Wilms' tumor 1-KTS isoforms induce p53-independent apoptosis that can be partially rescued by expression of the epidermal growth factor receptor or the insulin receptor.

The Wilms' tumor 1 gene (WT1) encodes a transcription factor of the zinc-finger family. As a result of alternative RNA splicing, the gene can be expressed as four polypeptides that differ in the presence or absence of a stretch of 17 amino acids just NH2 terminal of the four zinc fingers and a stretch of three amino acids (+/-KTS) between zinc fingers 3 and 4. In this study, cDNA constructs encoding the four human Wilms' tumor 1 splice variants were transiently transfected into the p53-negative Hep3B and the p53-positive HepG2 hepatoma cell lines. Morphological assessment of the WT1-expressing cells showed that the WT1(-KTS) splice variants induced apoptosis in both cell lines, whereas the WT1(+KTS) isoforms did not. The induction of apoptosis by the WT1(-KTS) isoforms appears to be p53 independent in the hepatoma cell lines. Furthermore, it was found that the WT1(-KTS)-induced apoptosis could not be suppressed by coexpression of either the Mr 21,000 E1B, the Bcl-2, or the BAG-1 protein. Coexpression of either the epidermal growth factor receptor or the insulin receptor, however, partially rescued the cells from apoptosis.

Infectivity and expression of the early adenovirus proteins are important regulators of wild-type and DeltaE1B adenovirus replication in human cells.

An adenovirus mutant lacking the expression of the large E1B protein (DeltaE1B) has been reported to replicate selectively in cells lacking the expression of functionally wild-type (wt) p53. Based on these results the DeltaE1B or ONYX-015 virus has been proposed to be an oncolytic virus which might be useful to treat p53-deficient tumors. Recently however, contradictory results have been published indicating that p53-dependent cell death is required for productive adenovirus infection. Since there is an urgent need for new methods to treat aggressive, mutant p53-expressing primary tumors and their metastases we carefully examined adenovirus replication in human cells to determine whether or not the DeltaE1B virus can be used for tumor therapy. The results we present here show that not all human tumor cell lines take up adenovirus efficiently. In addition, we observed inhibition of the expression of adenovirus early proteins in tumor cells. We present evidence that these two factors rather than the p53 status of the cell determine whether adenovirus infection results in lytic cell death. Furthermore, the results we obtained by infecting a panel of different tumor cell lines show that viral spread of the DeltaE1B is strongly inhibited in almost all p53-proficient and -deficient cell lines compared to the wt virus. We conclude that the efficiency of the DeltaE1B virus to replicate efficiently in tumor cells is determined by the ability to infect cells and to express the early adenovirus proteins rather than the status of p53.

The large E1B protein together with the E4orf6 protein target p53 for active degradation in adenovirus infected cells.

It has recently been shown that an adenovirus mutant lacking expression of the large E1B protein (deltaE1B) selectively replicates in p53 deficient cells. However, apart from the large E1B protein the adenovirus early region encodes the E1A and E4orf6 proteins which also have been reported to affect p53 expression as well as its functioning. After infection with wild-type adenovirus we observed a dramatic decrease in wild-type p53 expression while no down-regulation of p53 could be detected after infection with the deltaE1B virus. The different effects of the wild-type and deltaE1B adenovirus on p53 expression were not only found in cells expressing wild-type p53 but were also observed when tumor cells expressing highly stabilized mutant p53 were infected with these two viruses. Infection with different adenovirus mutants indicated the importance of a direct interaction between p53 and the large E1B protein for reduced p53 expression after infection. Moreover, coexpression of the E4orf6 protein was found to be required for this phenomenon, while expression of E1A is dispensable. In addition, we provide evidence that p53 is actively degraded in wild-type adenovirus-infected cells but not in deltaE1B-infected cells.

EGR-1 enhances tumor growth and modulates the effect of the Wilms' tumor 1 gene products on tumorigenicity.

The Wilms' tumor 1 gene (WT1) encodes a transcription factor of the zinc-finger family and is homozygously mutated or deleted in a subset of Wilms' tumors. Through alternative mRNA splicing, the gene is expressed as four main polypeptides that differ by a stretch of 17 amino acids just N-terminal of the four zinc-fingers and three amino acids between zinc fingers 3 and 4. We have previously shown that expression of the WT1(-/-) isoform, lacking both inserts, increases the tumor growth rate of the adenovirus-transformed baby rat kidney (AdBRK) cell line 7C3H2, whereas expression of the WT1(-/+) isoform, lacking the 17aa insert, strongly suppresses the tumorigenic phenotype. In the present study we show that expression of these splice variants does not affect the tumorigenic potential of the similar AdBRK cell line, 7C1T1. In contrast to the 7C3H2 cell line, this AdBRK cell line expresses high endogenous levels of EGR-1 (early growth response-1) protein, a transcription factor structurally related to WT1. Ectopic expression of EGR-1 in the 7C3H2 AdBRK cells significantly increases their in vivo growth rate and nullifies the tumor suppressor activity of the WT1(-/+) protein. Furthermore, we find that EGR-1 levels are elevated in some Wilms' tumors. These data are the first to show that EGR-1 overexpression causes enhanced tumor growth and that WT1 and EGR-1 exert antagonizing effects on growth regulation in baby rat kidney cells, which might reflect the situation in some Wilms' tumors.

Wilms' tumor 1 splice variants have opposite effects on the tumorigenicity of adenovirus-transformed baby-rat kidney cells.

The Wilms' Tumor 1 gene (WT1) encodes a transcription factor of the zinc-finger family. As a result of alternative RNA splicing, the gene can be expressed as four polypeptides which differ in the presence or absence of two stretches of amino acids: one of 17 residues (17aa) just N-terminal of the four zinc-fingers and of three residues (K-T-S) between zinc finger 3 and 4. In this study, four human cDNA constructs encoding the Wilms' tumor 1 splice variants were stably transfected into adenovirus-transformed baby rat kidney (Ad-BRK) cells. The in vivo produced WT1 proteins that lacked the KTS residues were found to bind efficiently to both the Egr-1 consensus sequence and the recently described WTE DNA sequence, as determined by electrophoretic mobility shift assays. Our studies show distinct effects of the different WT1 isoforms. Expression of the WT1 (-/+) protein, lacking the 17aa insert, strongly suppressed the tumorigenic phenotype of the Ad-BRK cells. Intriguingly, expression of the WT1 (-/-) protein, lacking both inserts, increased the tumor growth rate. In contrast to the growth in vivo, the growth rate of the transfectants in tissue culture is not influenced by any of the WT1 isoforms. However, the suppression of tumorigenicity appears to be correlated with a reduced ability of the cells to grow in serum-free medium.

MDMX: a novel p53-binding protein with some functional properties of MDM2.

Here we report the isolation of a cDNA encoding a new p53-associating protein. This new protein has been called MDMX on the basis of its structural similarity to MDM2, which is especially notable in the p53-binding domain. In addition, the putative metal binding domains in the C-terminal part of MDM2 are completely conserved in MDMX. The middle part of the MDMX and MDM2 proteins shows a low degree of conservation. We can show by co-immunoprecipitation that the MDMX protein interacts specifically with p53 in vivo. This interaction probably occurs with the N-terminal part of p53, because the activity of the transcription activation domain of p53 was inhibited by co-transfection of MDMX. Northern blotting showed that MDMX, like MDM2, is expressed in all tissues tested, and that several mRNAs for MDMX can be detected. Interestingly, the level of MDMX mRNA is unchanged after UV irradiation, in contrast to MDM2 transcription. This observation suggests that MDMX may be a differently regulated modifier of p53 activity in comparison with MDM2. Our study indicates that at least one additional member of the MDM protein family exists which can modulate p53 function.