The C-terminus of mutant p53 is necessary for its ability to interfere with growth arrest or apoptosis.

The ability to suppress wild type p53-independent apoptosis may play an important role in the oncogenicity of p53 mutant proteins. However, structural elements necessary for this activity are unknown. Furthermore, it is unclear whether this mutant p53 mediated inhibition is specific to the apoptotic pathway or a more general suppression of the cellular response to stress. We observed that an unmodified C-terminus was required for the suppression of apoptosis by the p53 135(Ala to Val) oncogenic p53 mutant. It was also required for the novel activity of G2 arrest suppression, the predominant response at low levels of genotoxic stress. These observations are consistent with a model whereby mutant p53 suppressive activity is not specific to the apoptotic pathway, but rather increases the threshold of genotoxic stress needed for a DNA damage response to occur. Furthermore, these observations indicate that it may be possible to selectively kill mutant p53 expressing cells based on the lower sensitivity of their growth arrest response.

The role of the C' terminus of murine p53 in the p53/mdm-2 regulatory loop.

Mdm-2 plays a central role in the regulation of p53 protein level and activity. Although the interaction of mdm-2 and p53 occurs through the N-terminus of the p53 protein, our present data suggest that the C' terminus plays an important role in the regulation of the p53/mdm-2 loop. Comparative analysis of the murine regularly spliced form of p53 (RSp53) and a physiological C-terminally modified p53 protein, which results from alternative splicing of the p53 mRNA (ASp53), indicated that the two isoforms behave differently in the p53/mdm-2 loop. We found that ASp53 can preferentially induce higher levels of the mdm-2 protein, compared with RSp53. Although the transactivation capacity of both forms is inhibited by mdm-2, only RSp53 is directed to proteolytic degradation by mdm-2, while ASp53 is relatively resistant. We present evidence that suggests that ASp53 protein levels determine the biological activities mediated by RSp53, such as the induction of apoptosis, through the mdm-2/p53 regulatory loop. We suggest, therefore, a new mechanism for the regulation of p53, and show that alteration of the p53 extreme C' terminus can significantly change the transcription activity and the resistance to degradation properties of the p53 protein.

p53-dependent apoptosis is regulated by a C-terminally alternatively spliced form of murine p53.

It is now well accepted that the p53 C-terminus plays a central role in controlling the activity of the wild-type molecule. In our previous studies, we observed that a C-terminally altered p53 protein (p53AS), generated by an alternative spliced p53 mRNA, induces an attenuated p53-dependent apoptosis, compared to that induced by the regularly spliced form (p53RS). In the present study we analysed the interrelationships between these two physiological variants of wild-type p53, and found that in cells co-expressing both forms, in contrast to the expected additive effect on the induction of apoptosis, p53AS inhibits apoptosis induced by p53RS. This inhibitory effect is specific for p53-dependent apoptosis and was not evident in a p53-independent apoptotic pathway induced by growth factor deprivation. Furthermore, the expression of p53AS in transiently transfected cells caused both inhibition of apoptosis and inhibition of the p53RS-dependent transactivation of a number of p53 target genes. These results suggest that expression of an alternatively spliced p53 form may serve as an additional level in controlling the complexity of p53 function by the C-terminal domain.

Epithelial cells of different organs exhibit distinct patterns of p53-dependent and p53-independent apoptosis following DNA insult.

The present study shows that DNA damage induces different patterns of p53-dependent and p53-independent apoptosis in epithelial cells of various organs of adult mice. Genotoxic stress induced a biphasic apoptotic response in the small intestine and tongue. While the first immediate apoptotic wave was p53-dependent, the second was slower in rate and was p53-independent. Under the same experimental conditions a single rapid, but a more extended, p53-independent response was evident in the skin of the tail. Indeed, exposure of p53+/+ mice to 400 R induced in epithelium of the small intestine and tongue an immediate rapid response that was followed by a second delayed p53-independent apoptotic wave. p53-/- mice exhibited in these organs the second wave only. However, epithelium of the tail derived from the same mice showed a single rapid apoptotic response that lasted much longer than the p53-dependent response and was similar in the p53-/- and the p53+/+ mice. Variations in apoptotic patterns observed in epithelial cells derived of the different tissues may point to differences in the physiological pathways expressed.

Accentuated apoptosis in normally developing p53 knockout mouse embryos following genotoxic stress.

In order to identify the alternative pathways which may substitute for the p53 function during embryogenesis, we have focused our studies on p53 -/- normally developing mouse embryos that survived a genotoxic stress. We assumed that under these conditions p53-independent pathways, which physiologically control genomic stability, are enhanced. We found that while p53 +/+ mouse embryos elicited, as expected, a p53-dependent apoptosis, p53-/- normally developing mice exhibited an accentuated p53-independent apoptotic response. The p53-dependent apoptosis detected in p53+/+ embryos, was an immediate reaction mostly detected in the brain, whereas the p53-independent apoptosis was a delayed reaction with a prominent pattern observed in epithelial cells of most organs in the p53-deficient mice only. These results suggest that in the absence of p53-dependent apoptosis, which is a fast response to damaged DNA, p53-independent apoptotic pathways, with slower kinetics, are turned on to secure genome stability.

Mutant p53 protein expression interferes with p53-independent apoptotic pathways.

Loss of normal p53 function was found frequently to interfere with response of cancer cells to conventional anticancer therapies. Since more than half of all human cancers possess p53 mutations, we decided to explore the involvement of mutant p53 in drug induced apoptosis. To further evaluate the relationship between the p53-dependent and p53-independent apoptotic pathways, and to elucidate the function of mutant p53 in modulating these processes, we investigated the role of a p53 temperature-sensitive (ts) mutant in a number of apoptotic pathways induced by chemotherapeutic drugs that are currently used in cancer therapy. To that end, we studied the M1/2, myeloid p53 non-producer cells, and M1/2-derived temperature-sensitive mutant p53 expressing clones. Apoptosis caused by DNA damage induced with gamma-irradiation, doxorubicin or cisplatin, was enhanced in cells expressing wild type p53 as compared to that seen in parental p53 non-producer cells; mutant p53 expressing clones were found to be more resistant to apoptosis induced by these factors. Actinomycin D, a potent inhibitor of transcription, as well as a DNA damaging agent, abrogated the restraint apoptosis mediated by mutant p53. These observations suggest that while loss of wild type p53 function clearly reduces the rate of apoptosis, p53 mutations may result in a gain of function which significantly interferes with chemotherapy induced apoptosis. Therefore, to achieve a successful cancer therapy, it is critical to consider the specific relationship between a given mutation in p53 and the chemotherapy selected.

Role of wild type p53 in the G2 phase: regulation of the gamma-irradiation-induced delay and DNA repair.

Upregulation of the p53 protein was shown to induce cell cycle arrest at the G1/S border and in some cases at the G2/M border. Furthermore, it was suggested that p53 is associated with the induction of the various DNA repair pathways. Previously, we demonstrated that cells co-expressing endogenous wild type p53 protein, together with dominant negative mutant p53, exhibit deregulation of apoptosis, G1 arrest and delay in G2 following gamma-irradiation. In the present study, we investigated the role of p53 protein in the DNA damage response at the G2 phase. Using p53-null, wild type p53 and mutant p53-producer cell lines, we found that the two C-terminally spliced p53 forms could prevent gamma-irradiation induced mutagenesis prior to mitosis, at the G2/M checkpoint. We found that at the G2 phase, p53 may facilitate repair of DNA breaks giving rise to micronuclei, and regulate the exit from the G2 checkpoint. At the G1 phase, only the regularly spliced form of p53 caused growth arrest. In contrast, both the regularly and the alternatively spliced p53 forms directed postmitotic micronucleated cells towards apoptosis. These results provide a functional explanation for the cell cycle-independent expression of p53 in normal cycling cells, as well as in cells where p53 is up-regulated, following DNA damage.

Differential expression of the regularly spliced wild-type p53 and its COOH-terminal alternatively spliced form during epidermal differentiation.

In the present study, we investigated the role of p53 in the differentiation of epidermal keratinocyte cells. The interrelationship between p53 expression and the various stages of epidermal differentiation and the role of the COOH terminus of the p53 molecule in this process were determined by comparing the expression of the regularly spliced p53 (RSp53) molecule and that of the COOH-terminal alternatively spliced (ASp53) form. p53 mRNA distribution was studied by in situ analysis of frozen skin sections and by reverse transcription-PCR analysis of the various wild-type p53 forms expressed in neonatal skin cell fractions separated by Percoll gradient. p53 protein levels were measured by fluorescence-activated cell sorting analysis and immunohistochemistry, using antibodies that recognize either the COOH terminus of RSp53 or ASp53. The results show that although less mature keratinocyte cells predominantly express the RSp53 form, the more mature cells preferentially express the ASp53 form. Therefore, it is possible that the two p53 forms are associated with different functions required at the various stages of keratinocyte differentiation. The results suggest that the COOH-terminal domain of the p53 molecule is important for its activity in the process of keratinocyte differentiation.

The murine C'-terminally alternatively spliced form of p53 induces attenuated apoptosis in myeloid cells.

The onset of p53-dependent apoptosis results from the accumulation of damaged DNA. Recently, it was shown that the C' terminus of the p53 protein plays a central role in sensing damaged DNA. In our present study, we examined the role of the C' terminus in the induction of apoptosis. A temperature-sensitive (ts) mutant of the alternatively spliced form of p53 (p53AS-ts) and the ts mutant of the regularly spliced form (p53RS-ts) were used to generate series of stable clones with increasing amounts of p53 protein. Apoptotic patterns induced by either the regularly spliced p53 product (p53RS) or a C'-terminally alternatively spliced p53 product (p53AS) were compared. We found that although both forms of p53 induced apoptosis following expression of the wild-type protein conformation, the kinetics were different. Apoptosis induced by the p53AS protein was attenuated compared to that induced by p53RS. The delay in the manifestation of the apoptotic features following p53AS expression was in agreement with a delay in the regulation of the expression of apoptosis-related genes. The observation that p53 with an altered C' terminus is still capable of inducing apoptosis suggests that the actual onset of the apoptotic process most probably involves structural domains other than the C' terminus of the p53 molecule. However, the fact that the apoptotic activity mediated by the p53AS product was slower than that mediated by the p53RS product suggests that the C' terminus indeed exerts a certain control on the apoptotic activity of the p53 molecule.

A p6Pol-protease fusion protein is present in mature particles of human immunodeficiency virus type 1.

Human immunodeficiency virus type 1 (HIV-1) protease (PR) and p6(Pol) are translated as part of the Gag-Pol polyprotein after a ribosomal frameshift. PR is essential to virus replication and is responsible for cleaving Gag and Gag-Pol precursors, but the role of p6(Pol) in HIV-1 infection is poorly understood. Here, we report that (i) PR is present in mature HIV-1 virions primarily as a p6(Pol)-PR fusion protein; (ii) HIV-1 PR cleaves viral precursor proteins expressed in bacterial cells at the Phe-Leu bond (positions 1639 to 1642) located at the junction of the NC and p6(Pol) proteins, releasing the p6(Pol)-PR fusion protein; and (iii) purified p6(Pol)-PR fusion protein undergoes autocleavage in vitro at at least three sites.

Avian sarcoma leukemia virus protease linked to the adjacent Gag polyprotein is enzymatically active.

The activity of avian sarcoma leukemia virus (ASLV) protease (PR) prior to its release from the precursor protein was determined by introducing mutations at the cleavage site between PR and the adjacent upstream nucleocapsid (NC) protein. Gag DNA fragments containing these mutations were cloned into expression vectors and introduced into Escherichia coli in which the ASLV proteins were expressed. The dipeptide NC-PR containing these mutations did not undergo autoprocessing when expressed in bacterial cells and the fused proteins were devoid of enzymatic activity. However, when the whole Gag polyprotein containing these mutations was expressed in bacterial cells, other PR cleavage sites in the viral Gag polyprotein underwent normal cleavage, indicating that the release of free PR is not a prerequisite for correct processing of the ASLV Gag precursor.