An N-terminal p14ARF peptide blocks Mdm2-dependent ubiquitination in vitro and can activate p53 in vivo.

The p53 tumour suppressor protein is down-regulated by the action of Mdm2, which targets p53 for rapid degradation by the ubiquitin-proteasome pathway. The p14ARF protein is also a potent tumour suppressor that acts by binding to Mdm2 and blocking Mdm2-dependent p53 degradation and transcriptional silencing. We have screened a series of overlapping synthetic peptides derived from the p14ARF protein sequence and found that a peptide corresponding to the first 20 amino acids of ARF (Peptide 3) could bind human Mdm2. The binding site for Peptide 3 on Mdm2 was determined by deletion mapping and lies adjacent to the binding site of the anti-Mdm2 antibody 2A10, which on microinjection into cells can activate p53-dependent transactivation of a reporter plasmid. To determine whether Peptide 3 could similarly activate p53, we expressed a fusion of green fluorescent protein and Peptide 3 in MCF7 and U-2 OS cells and were able to demonstrate induction of p53 protein and p53-dependent transcription. Peptide 3 was able to block in vitro ubiquitination of p53 mediated by Mdm2. Small peptides which are sufficient to block degradation of p53 could provide therapeutic agents able to restore p53-dependent cell death pathways in tumours that retain wild-type p53 expression.

Mdm2 binding to a conformationally sensitive domain on p53 can be modulated by RNA.

Biochemical characterisation of the interaction of mdm2 protein with p53 protein has demonstrated that full-length mdm2 does not bind stably to p53-DNA complexes, contrasting with C-terminal truncations of mdm2 which do bind stably to p53-DNA complexes. In addition, tetrameric forms of the p53His175 mutant protein in the PAb1620+ conformation are reduced in binding to mdm2 protein. These data suggest that the mdm2 binding site in the BOX-I domain of p53 becomes concealed when either p53 binds to DNA or when the core domain of p53 is unfolded by missense mutation. This further suggests that the C-terminus of mdm2 protein contains a negative regulatory domain that affects mdm2 protein binding to a second, conformationally sensitive interaction site in the core domain of p53. We investigated whether there was a second docking site on p53 for mdm2 protein by examining the interaction of full-length mdm2 with p53 lacking the BOX-I domain. Although mdm2 protein did bind very weakly to p53 protein lacking the BOX-I domain, addition of RNA activated mdm2 protein binding to this truncated form of p53. These data provide evidence for three previously undefined regulatory stages in the p53-mdm2 binding reaction: (1) conformational changes in p53 protein due to DNA binding or point mutation conceals a secondary docking site of mdm2 protein; (2) the C-terminus of mdm2 is the primary determinant which confers this property upon mdm2 protein; and (3) mdm2 protein binding to this secondary interaction site within p53 can be stabilised by RNA.

SUMO-1 modification activates the transcriptional response of p53.

The p53 tumour suppressor protein is regulated by ubiquitin-mediated proteasomal degradation. In normal cells p53 is constitutively ubiquitylated by the Mdm2 ubiquitin ligase. When the p53 response is activated by stress signals p53 levels rise due to inhibition of this degradative pathway. Here we show that p53 is modified by the small ubiquitin-like protein SUMO-1 at a single site, K386, in the C-terminus of the protein. Modification in vitro requires only SUMO-1, the SUMO-1 activating enzyme and ubc9. SUMO-1 and ubiquitin modification do not compete for the same lysine acceptor sites in p53. Overexpression of SUMO-1 activates the transcriptional activity of wild-type p53, but not K386R p53 where the SUMO-1 acceptor site has been mutated. The SUMO-1 modification pathway therefore acts as a potential regulator of the p53 response and may represent a novel target for the development of therapeutically useful modulators of the p53 response.

p53 suppresses the activation of the Bcl-2 promoter by the Brn-3a POU family transcription factor.

The Brn-3a POU family transcription factor has been shown to strongly activate expression of the Bcl-2 proto-oncogene and thereby protect neuronal cells from programmed cell death (apoptosis). This activation of the Bcl-2 promoter by Brn-3a is strongly inhibited by the p53 anti-oncogene protein. This inhibitory effect of p53 on Brn-3a-mediated transactivation is observed with nonoverlapping gene fragments containing either the Bcl-2 p1 or p2 promoters but is not observed with other Brn-3a-activated promoters such as in the gene encoding alpha-internexin or with an isolated Brn-3a binding site from the Bcl-2 promoter linked to a heterologous promoter. In contrast, p53 mutants, which are incapable of binding to DNA, do not affect Brn-3a-mediated activation of the Bcl-2 p1 and p2 promoters. Moreover, Brn-3a and p53 have been shown to bind to adjacent sites in the p2 promoter and to directly interact with one another, both in vitro and in vivo, with this interaction being mediated by the POU domain of Brn-3a and the DNA binding domain of p53. The significance of these effects is discussed in terms of the antagonistic effects of Bcl-2 and p53 on the rate of apoptosis and the overexpression of Brn-3a in specific tumor cell types.

A resistant genetic background leading to incomplete penetrance of intestinal neoplasia and reduced loss of heterozygosity in ApcMin/+ mice.

Previous studies of Min/+ (multiple intestinal neoplasia) mice on a sensitive genetic background, C57BL/6 (B6), showed that adenomas have lost heterozygosity for the germ-line ApcMin mutation in the Apc (adenomatous polyposis coli) gene. We now report that on a strongly resistant genetic background, AKR/J (AKR), Min-induced adenoma multiplicity is reduced by about two orders of magnitude compared with that observed on the B6 background. Somatic treatment with a strong mutagen increases tumor number in AKR Min/+ mice in an age-dependent manner, similar to results previously reported for B6 Min/+ mice. Immunohistochemical analyses indicate that Apc expression is suppressed in all intestinal tumors from both untreated and treated AKR Min/+ mice. However, the mechanism of Apc inactivation in AKR Min/+ mice often differs from that observed for B6 Min/+ mice. Although loss of heterozygosity is observed in some tumors, a significant percentage of tumors showed neither loss of heterozygosity nor Apc truncation mutations. These results extend our understanding of the effects of genetic background on Min-induced tumorigenesis in several ways. First, the AKR strain carries modifiers of Min in addition to Mom1. This combination of AKR modifiers can almost completely suppress spontaneous intestinal tumorigenesis associated with the Min mutation. Second, even on such a highly resistant genetic background, tumor formation continues to involve an absence of Apc function. The means by which Apc function is inactivated is affected by genetic background. Possible scenarios are discussed.

The N terminus of the murine p53 tumour suppressor is an independent regulatory domain affecting activation and thermostability.

The contribution of each of the structural domains of p53 to its function has been discussed widely in the literature. Crystallographic studies have revealed much about the structure of the core DNA binding domain, but as it has not been possible to use this approach for the intact protein, the effect of the domains flanking the core must be investigated by more indirect techniques. In this study a series of truncated murine p53 proteins has been investigated for DNA binding activity at 4 degrees C and 37 degrees C, transcriptional activation, and tumour suppression activity. Full-length p53, and truncations lacking the N terminus, purified from a baculovirus expression system all show latency for DNA binding; that is, they must be activated to bind by association with a C-terminal antibody such as PAb421. This demonstrates that latency for DNA binding is independent of the N terminus. Truncations lacking the C-terminal oligomerisation domain, and the isolated core domain, can only be activated to bind DNA and PAb1620 (an antibody recognising the wild-type conformation of the core domain) in the presence of cross-linking antibodies, while murine core only binds to DNA in the presence of PAb1620. An analysis of the thermostability of DNA binding revealed that antibodies that bind the N terminus of p53 could protect the protein against loss of activity at 37 degrees C. C-terminal antibodies, however, were ineffective unless the N-terminal 37 amino acid residues were absent. The N terminus may retain some secondary structure, since it is the main contributor to the anomalous migration in SDS-polyacrylamide gels. Our results suggest that the N terminus has a destabilising effect that influences conformation of p53 at 37 degrees C, so cellular proteins binding to the N terminus in vivo may modulate p53 conformation and stability. The effects on thermostability are also direct evidence showing that antibodies binding to N-terminal deletions create a conformational change in the rest of the molecule. In addition, longer deletions of the C terminus reduce the ability of p53 to transactivate target genes and inactivate tumour suppression activity, while truncations of the N terminus retain partial tumour suppression activity. Our results clearly show participation of both the N and C termini in the regulation of all the functions of p53 at 37 degrees C, indicating that distinct, independent domains interact with each other within, the flexible structure of p53.

p53 protein stability in tumour cells is not determined by mutation but is dependent on Mdm2 binding.

The tumour suppressor protein p53 is expressed at very low levels in normal cells but accumulates in response to DNA damaging agents such as u.v. irradiation. This increase is accompanied by transcriptional upregulation of the expression of a number of proteins including Mdm2 which can in turn inhibit p53 dependent transcriptional activation, creating a feedback loop resulting in down-regulation of p53 activity. Mutant p53 proteins are however frequently detected at constitutively high levels in many tumours and tumour cell lines, indeed this phenomenon has been used in several studies to diagnose p53 mutation in patient tumours. We show here that expression of mouse mutant p53 in tumour cell lines of this type results in high levels of both the endogenous p53 protein and the exogenously expressed mutant mouse protein, whereas the human tumour line MCF7 does not exhibit high levels of either endogenous human or exogenously expressed mouse mutant p53 unless stabilisation is induced by DNA damage. This suggests that the stability of mutant p53 is not intrinsic to mutant p53 protein structure but may vary in different cell backgrounds. We present evidence that p53 protein stability in tumour cell lines is determined by association with the Mdm2 tumour suppressor protein, and that p53 mutants which are unable to bind Mdm2 are stable in MCF7 cells. We propose that tumour lines which express high levels of transcriptionally inactive mutant p53 are unable to induce the expression of the Mdm2 protein which would normally provide a feedback mechanism down-regulating p53 protein levels in the absence of DNA damage signals. MCF7 cells however express a transcriptionally active p53 and retain the feedback regulation of p53 protein levels by Mdm2.

APC expression in normal human tissues.

The tumour suppressor gene APC codes for a 2843-amino acid protein whose precise functions are still poorly understood. This paper describes the development of two new antisera to APC (to amino- and carboxy-terminal epitopes) which permit localization of the protein by immunohistochemistry in archival paraffin sections. The protein is expressed in a wide variety of normal epithelial tissues. Its distribution frequently coincides with the location of post-replicative cells within tissues. Staining patterns demonstrate that the APC protein, although often diffusely cytoplasmic in distribution, may also accumulate in the apical and immediately subapical regions, or along the lateral margins of certain cells. These results indicate that APC is significant in many tissues in addition to the colorectal epithelium. They are compatible with a function related to signalling at the adherens junction and possibly with other more complex roles in cells committed to terminal differentiation.

The p53 response to ionising radiation in adult and developing murine tissues.

The induction of the p53 response to ionising radiation has been studied during murine development and in the adult animal. The response has been assessed by precise quantitative assay of p53 protein levels in tissues and by immunohistochemistry. Newly developed transgenic mice in which a lacZ transgene is driven by a p53 response element have also been used to directly assess the transcriptional activity of the induced protein. There is striking developmental control of the p53 response so that in early development all tissues accumulate high levels of p53 following radiation and indeed p53 is present at elevated levels in some unirradiated tissues. Later in development clear heterogeneity of the p53 response becomes apparent, both in terms of the responses of individual tissues and of cell populations, within those tissues. The study of lacZ transgene expression and the occurrence of apoptosis in different tissues that accumulate p53 protein point to a further level of control regulating the nature and degree of the downstream response to elevated levels of p53 in cells. These findings have important implications for the susceptibility of different tissue types to carcinogenic and other insults. The early expression of the p53 response is consistent with novel models of p53 function that suggest it may have evolved principally as a defense against teratogenic insult that permits plasticity of development.

Modification of two distinct COOH-terminal domains is required for murine p53 activation by bacterial Hsp70.

Activation of the latent DNA binding function of human p53 protein by the bacterial Hsp70, DnaK, represents a unique reaction in which a heat shock protein can interact with a native protein to affect its function. We have localized a likely DnaK interaction site on native human p53 tetramers to a motif flanking the COOH-terminal casein kinase II and protein kinase C phosphorylation sites. Murine p53 is less efficiently activated by DnaK, which has permitted a search for factors that might cooperate in p53 activation by DnaK. We show that optimal activation by DnaK may be dependent upon the phosphorylation state of murine p53, in particular, modification of p53 at the cdc2 phosphorylation site by point mutation decreases the extent of activation by DnaK. Additionally, the monoclonal antibody PAb241, binding in the vicinity of the cdc2 phosphorylation site, is able to activate the specific DNA binding function of p53. This has led us to propose a second regulatory motif flanking the tetramerization domain of p53 that cooperates with factors binding at the negative regulatory domain in the extreme COOH terminus.

Epitope analysis of the murine p53 tumour suppressor protein.

The identification and characterisation of the p53 tumour suppressor has relied extensively on the use of immunological reagents. To facilitate further characterisation of the murine p53 protein (Mp53), and its interaction with other proteins, we have characterised the antigenic sites of Mp53 in fine detail. Using an overlapping Mp53 peptide library we report the identification by Pepscan ELISA of the epitopes of nine antibodies. We have also used this technique to determine whether corresponding epitopes were present in a human p53 (Hp53) peptide library. This comparison was extended to include polyclonal sera of mice immunized with either Mp53 or Hp53, to compare the overall range of antigenic sites. The range of antigenic sites identified by polyclonal sera is very similar, although the N-terminus of Mp53 is clearly not an immunodominant region, in contrast to the N-terminus of Hp53. However, the N-terminus of Mp53 is immunogenic in rabbits as demonstrated by the Pepscan ELISA of CM5 serum (a rabbit anti-Mp53 serum used in analysing p53 expression in mice). Since, very few new antigenic sites were identified in either Mp53 or Hp53, new approaches will have to be employed to identify novel immunological reagents against human and murine p53.

A direct effect of activated human p53 on nuclear DNA replication.

p53 is a transcriptional activator and repressor, but recent evidence suggests that some of its many biological functions may not be dependent on transcription. To determine whether p53 exerts a direct influence on nuclear DNA replication, purified human p53 was added to a transcription-free DNA replication extract from Xenopus eggs. Full-length human p53 that inhibits SV40 DNA replication in vitro had no effect on nuclear DNA synthesis in the Xenopus system. In contrast, a C-terminal truncated form of p53 (p53 delta 30), which is constitutively active for DNA binding and similar to an alternately spliced form found in vivo, showed a concentration-dependent inhibition of DNA replication in both the soluble SV40 system and eukaryotic nuclei. This inhibition occurred primarily at initiation of DNA synthesis. Oxidation of p53 delta 30, which eliminates DNA binding activity, also abrogated the protein's ability to inhibit nuclear DNA synthesis. The p53 binding DNA consensus sequence enhanced rather than competed away inhibitory activity of p53 delta 30. Therefore, p53 that is constitutively active for DNA binding can inhibit nuclear DNA replication in the absence of transcription. This inhibition may require binding of p53 to DNA, in addition to interactions between p53 and proteins of the replication complex.

Coupling between gamma irradiation, p53 induction and the apoptotic response depends upon cell type in vivo.

The accumulation of p53 protein following whole body irradiation of adult mice was studied using a new polyclonal antibody to mouse p53. While dramatic accumulation of the protein was apparent in splenocytes, thymocytes and osteocytes no p53 protein accumulation was detected in the hepatocytes of the irradiated mouse. Thus, the upstream initiating signals that control the induction of p53 are controlled in a tissue specific manner. While massive apoptosis accompanies p53 induction in thymocytes and splenocytes it is not seen in the osteocytes. Thus the downstream consequences of p53 induction are also tightly controlled. These results have profound significance for an understanding of the role of the p53 tumour suppression pathway in different tissues.

Conformational changes in p53 analysed using new antibodies to the core DNA binding domain of the protein.

The p53 protein contains a protease resistant core section that binds to DNA in a sequence specific manner and whose crystal structure has been determined. This core is flanked at the N-terminus by the transcriptional transactivation domain and at the C-terminus by sequences involved in the oligomerisation of the protein. Extensive immunochemical analysis of p53 has shown that dominant antigenic sites lie within these N- and C-terminal domains while few antibodies to the central core have been identified. One of these, PAb240, has been extensively characterised as its epitope is cryptic in the native DNA binding core structure but is exposed by denaturation. This epitope is also exposed on many p53 proteins that contain point mutations in the core domain suggesting that these mutations may have a common affect on the structure of the core. To investigate this further we have generated several new antibodies to novel sites on p53 and mapped their epitopes using synthetic peptides. We find that antibodies to two other discrete sites in the core can also, like PAb240, recognize cryptic epitopes and distinguish mutant from wild-type conformations implying that the point mutations found in p53 in human tumours have widespread effects on the folding pattern of the DNA binding domain.

On the regulation of the p53 tumour suppressor, and its role in the cellular response to DNA damage.

The p53 gene is required for the normal apoptotic response of mammalian cells to DNA damage caused by ionizing radiation and DNA damaging drugs. DNA damage results in the accumulation of biologically active p53. This response is potentially lethal and is therefore highly regulated. By using both biochemical and cell biological approaches a number of discrete control pathways have been identified. These include analysis of cellular and viral proteins that bind to p53 to inactivate its function, the discovery of cells with defects in the p53 activation pathway and the analysis of an allosteric regulation of p53 function controlled by phosphorylation.

Xenopus p53 is biochemically similar to the human tumour suppressor protein p53 and is induced upon DNA damage in somatic cells.

Xenopus p53 cDNA, homologous to the human tumour suppressor p53, has previously been cloned from oocyte and gastrula libraries. In this report, we describe a polyclonal antibody 2674 raised against Xenopus p53 (Xp53) expressed in bacteria, that recognises proteins of approximately 52, 46 and 35 kDa present in Xenopus oocytes, parthenogenically activated eggs and in somatic tissue culture cells. We report here purification of Xp53 from insect cells infected with Xp53-baculovirus, and this protein is shown to be phosphorylated by casein kinase II but has low sequence-specific DNA binding activity. Using similar purification conditions, we have isolated endogenous Xp53, showing that Xenopus eggs contain high levels of p53 protein. Xp53 from eggs binds to the p53-specific DNA-binding consensus sequence. Two dimensional gel analysis indicates that Xp53 from eggs may exist in various states of phosphorylation. u.v.-induced DNA damage of somatic Xenopus cells results in accumulation of Xp53. We suggest that the high levels of putative Xp53 detected in eggs may represent maternal stockpiles of a protein necessary to protect rapidly dividing cells from the effects of DNA damage.

Activation of the cryptic DNA binding function of mutant forms of p53.

Wild type p53 assembles into a latent multiprotein complex which can be activated for sequence-specific DNA binding in vitro by proteins targeting the carboxy-terminal domain. Using an optimized system coupling the post-translational modification of wild type p53 to activation of sequence specific DNA binding, we examined the affects of common mutations on the cryptic DNA binding function of p53. Two mutant forms of p53 were shown to be efficiently converted from the latent state by PAb421 and DnaK, but were defective in activation by casein kinase II, indicating that mutant p53 may not be receptive to allosteric regulation by casein kinase II phosphorylation. A reactive sulfhydryl group is absolutely required for DNA binding by wild type and mutant forms of p53 once converted to the activated state. Together, these data show that some mutant forms of p53 harbour the wild-type machinery required to engage in sequence-specific DNA binding and define a signalling pathway whose inactivation may directly result in a loss of p53 function.

Regulation of the specific DNA binding function of p53.

The DNA binding activity of p53 is required for its tumor suppressor function; we show here that this activity is cryptic but can be activated by cellular factors acting on a C-terminal regulatory domain of p53. A gel mobility shift assay demonstrated that recombinant wild-type human p53 binds DNA sequence specifically only weakly, but a monoclonal antibody binding near the C terminus activated the cryptic DNA binding activity stoichiometrically. p53 DNA binding could be activated by a C-terminal deletion of p53, mild proteolysis of full-length p53, E. coli dnaK (which disrupts protein-protein complexes), or casein kinase II (and coincident phosphorylation of a C-terminal site on p53). Activation of p53 DNA binding may be critical in regulation of its ability to arrest cell growth and thus its tumor suppressor function.

An immunochemical analysis of the human nuclear phosphoprotein p53. New monoclonal antibodies and epitope mapping using recombinant p53.

Somatic mutation of the p53 gene is a very frequent event in the development of human neoplasia, and germ line mutations in p53 are responsible for an inherited cancer susceptibility syndrome. Many of the mutations in p53 found in human tumours are point mutations that result in the substitution of a single amino acid in the protein. These point mutant proteins are much more stable than the normal protein and the mutant product accumulates to a high level which permits important information about p53 expression to be obtained by immunochemical analysis. Using bacterial expression systems to produce fragments of human p53 we have isolated and characterized new monoclonal antibodies to p53. These antibodies are suitable for the measurement of p53 in ELISA, immunoblotting and immunoprecipitation analyses. They are especially useful in immunohistochemistry as they are able to react strongly with p53 in conventionally fixed and processed histological sections.

Analysis of p53 expression in human tumours: an antibody raised against human p53 expressed in Escherichia coli.

A cDNA encoding the complete normal human p53 protein was expressed in Escherichia coli using an expression system based on the bacteriophage T7 promoter. The cDNA was adapted so that the full-length protein was produced without fusion to any other sequence. Large amounts of the protein were isolated and the purified protein used to produce very high titre polyclonal antibodies to p53. These new antibodies permit the sensitive detection of p53 and p53 complexes in ELISA and immunoblotting assays. Most importantly, they also permit the detection of p53 in archival tumour material that has been conventionally fixed in formalin and embedded in paraffin wax. Using this reagent we have found that aberrant expression of p53 is a frequent feature of human breast cancer. We are able to recognise six different classes of p53 expression pattern that may be of help in the subclassification of breast tumours.