Mutant p53 in MDA-MB-231 breast cancer cells is stabilized by elevated phospholipase D activity and contributes to survival signals generated by phospholipase D.

p53 is the most commonly mutated gene in human cancer. Although the loss of tumor suppressor functions for p53 in tumorigenesis is well characterized, gain-of-function p53 mutations observed in most cancers are not as widely appreciated. The human breast cancer cell line MDA-MB-231, which has high levels of a mutant p53, has high levels of phospholipase D (PLD) activity, which provides a survival signal in these cells when deprived of serum growth factors. We report here that the mutant p53 in MDA-MB-231 cells is stabilized by the elevated PLD activity in these cells. Surprisingly, the survival of MDA-MB-231 cells deprived of serum was dependent on the mutant p53. These data indicate that a mutant p53, stabilized by elevated PLD activity, can contribute to the suppression of apoptosis in a human breast cancer cell line and suggest a rationale for the selection of p53 mutations early in tumorigenesis to suppress apoptosis in an emerging tumor.

Camptothecin and Zeocin can increase p53 levels during all cell cycle stages.

The ability of DNA damage to stabilize p53 in all cell cycle stages has not been examined in actively growing cells. The chemotherapeutic drug camptothecin is a topoisomerase I poison. Zeocin is a member of the bleomycin/phleomycin family of antibiotics, known to bind DNA. Both increase the level of p53 albeit by different mechanisms. We have utilized centrifugal elutriation to separate exponentially growing ML-1 cells (containing wild-type p53) into cell cycle fractions and have subsequently treated these cells with the two drugs. We provide evidence that both drugs can mediate an increase in p53 protein levels independent of the cell cycle stage. The p53 induced by both drugs was able to bind to DNA; however, only the p53 induced by camptothecin was phosphorylated at serine-392. This is the first demonstration that camptothecin and Zeocin can differentially signal for increased levels of modified p53 during all stages of the cell cycle.

Mutant p53 forms a complex with Sp1 on HIV-LTR DNA.

Many mutants of p53 activate HIV-LTR driven transcription and promote HIV replication. The region of the HIV-LTR containing Sp1-binding sites is important for this effect. In this study we test the hypothesis that mutant p53 interacts with DNA-bound Sp1 and in this way can increase transcription from Sp1-dependent promoters. We have used the breast cancer cell line MDA-MB-468 that expresses endogenous mutant p53(His273) as our source of p53 protein. First, we demonstrated that this mutant p53 participates in activating transcription from the HIV-LTR by showing that HIV-LTR-directed transcription in MDA-MB-468 cells is inhibited in a dominant-negative manner by p53(Val135). Using HIV-LTR DNA affinity chromatography, we detected coelution of p53(His273) and Sp1. We also demonstrated that this mutant p53 binds sequence specifically to the super consensus sequence (SCS) and that Sp1 coeluted with p53(His273) from a column containing this site. These data indicate that p53(His273) can associate with DNA-bound Sp1 suggesting that activated HIV-LTR transcription associated with mutant p53 occurs through a DNA driven multi-protein complex.

A DNA damage signal is required for p53 to activate gadd45.

We provide direct evidence that overexpression of p53 is not sufficient for robust p53-dependent activation of the endogenous gadd45 gene. When p53 was induced in TR9-7 cells in the absence of DNA damage, waf1/p21 and mdm2 mRNA levels were increased, but a change in gadd45 mRNA was barely detectable. Activation of the gadd45 gene was observed when camptothecin was added to cells containing p53 in the absence of a further increase in the p53 level. Phosphorylation of p53 at serine 15 and acetylation at lysine 382 were detected after drug treatment. It has been suggested that p53 posttranslational modification is critical during activation. However, inhibition of these modifications by wortmannin was not sufficient to block the transactivation of gadd45. Interestingly, after camptothecin treatment, increased DNase I sensitivity was detected at the gadd45 promoter, suggesting that an undetermined DNA damage signal is involved in inducing chromatin remodeling at the gadd45 promoter while cooperating with p53 to activate gadd45 transcription.

Infrared spectroscopy of human tissue. V. Infrared spectroscopic studies of myeloid leukemia (ML-1) cells at different phases of the cell cycle.

Infrared spectra of myeloid leukemia (ML-1) cells are reported for cells derived from an asynchronous, exponentially growing culture, as well as for cells that were fractionated according to their stage within the cell division cycle. The observed results suggest that the cells' DNA is detectable by infrared spectroscopy mainly when the cell is in the S phase, during the replication of DNA. In the G1 and G2 phases, the DNA is so tightly packed in the nucleus that it appears opaque to infrared radiation. Consequently, the nucleic acid spectral contributions in the G1 and G2 phases would be mostly that of cytoplasmic RNA. These results suggest that infrared spectral changes observed earlier between normal and abnormal cells may have been due to different distributions of cells within the stages of the cell division cycle.

p53 binds to a constitutively nucleosome free region of the mdm2 gene.

The mdm2 oncogene is a p53 responsive gene which contains both a p53 independent and a p53 dependent promoter (P1 and P2 respectively). We have utilized ligation mediated PCR genomic footprinting in order to investigate the intra-nuclear binding of p53 to the mdm2 P2 promoter. The DNase I protection pattern in nuclei from murine cells lacking p53 has been compared to the protection pattern in cells containing a temperature sensitive p53-Val135. At 32 degrees C p53-Val135 assumes a wild-type conformation while at 37 degrees C this p53 is conformationally mutant. We observed clear wild-type p53 dependent protection of the putative p53 response elements (REs) as well as protection of the adjacent TATA box. Interestingly the protection pattern observed with purified wild-type p53 on naked DNA showed less nucleotide sequence protection than the protection observed to be p53 dependent in nuclei. Constitutive DNase I hypersensitivity at both the mdm2 P1 and P2 promoters was detected by indirect Southern blot analysis. DNase I hypersensitivity reflects altered chromatin conformations resulting, most likely, from the absence of nucleosomes. Taken together our findings suggest that the mdm2 P2 promoter is maintained in a nucleosome free state which is pre-primed for transcriptional activation by p53.

p53 represses Sp1 DNA binding and HIV-LTR directed transcription.

The HIV-LTR region contains binding sites for, and is regulated by, a number of transcription factors including Sp1 and NF-kB. The wild-type p53 tumor suppressor protein represses transcription from the HIV-LTR promoter while oncogenic mutant forms of p53 stimulate expression from the HIV-LTR. We have shown previously that wild-type p53 is a site specific DNA binding protein that binds to a region of the SV40 virus which contains GC-box DNA binding sites for the ubiquitously expressed transcription factor Sp1. In this study using DNase I footprinting, we have shown that purified p53 is able to protect the Sp1 binding sites and the adjacent NF-kB site of the HIV-LTR. Furthermore we have demonstrated that when p53 and Sp1 are mixed together both proteins change each other's interaction with DNA. Interestingly, we noted that oncogenic mutant p53 is also able to change the interaction of Sp1 with DNA. We confirmed p53 dependent repression of HIV-LTR driven transcription by comparing the expression from an HIV-LTR reporter construct in the presence and absence of p53. EMSA of an oligonucleotide sequence derived from the HIV-LTR sequence demonstrated a slight decrease in Sp1 DNA binding activity with nuclear extract derived from the cell line expressing a high level of wild-type p53. These data suggest that the influence of p53 on the transcription of promoters with Sp1 binding sites may be partially due to a change in the DNA binding ability of Sp1.

p53, through p21 (WAF1/CIP1), induces cyclin D1 synthesis.

Cells induced to accumulate the p53 tumor suppressor protein have been shown to arrest in G1. This arrest is characterized by accumulation of the cyclin-dependent kinase inhibitor p21 (WAF1/CIP1) and of under-phosphorylated forms of retinoblastoma protein. We show here that accumulation of the wild-type p53 protein in either human or murine cells markedly increases expression of cyclin D1. The induction of cyclin D1 can also be mediated by a target of p53, the p21 (WAF1/CIP1) inhibitor of cyclin-dependent kinases. The relationship between the induction of cyclin D1 and G1 arrest defines a new cellular response to p53.

A proteolytic fragment from the central region of p53 has marked sequence-specific DNA-binding activity when generated from wild-type but not from oncogenic mutant p53 protein.

p53 is a sequence-specific DNA-binding oligomeric protein that can activate transcription from promoters bearing p53-binding sites. Whereas the activation region of p53 has been identified within the amino terminus, the location of the specific DNA-binding domain has not been reported. Thermolysin treatment of p53 protein generates a stable protease-resistant fragment that binds with marked specificity to p53 DNA-binding sites. Amino-terminal sequencing of the fragment located the thermolysin cleavage site to residue 91. Because the fragment does not contain the cdc2 phosphorylation site at Ser-315, we conclude that the the site-specific DNA-binding domain of p53 spans the central region of the protein. The vast majority of the mutations in oncogenically derived p53 proteins are located within this central portion of the molecule. Such mutant p53 proteins exhibit defective sequence-specific DNA-binding. Although thermolysin digestion of mutant p53 proteins generates proteolytic patterns that differ from wild-type protein, one mutant tested, His-273, generates a resistant fragment that migrates with a similar electrophoretic mobility to the wild-type protease-resistant fragment. Interestingly, although intact mutant His-273 protein binds to DNA at 20 degrees C, the thermolysin-resistant mutant fragment does not. In addition, the central protease-resistant, site-specific binding region of wild-type p53 does not demonstrate nonspecific DNA-binding. Thus, although sequences outside of the central region of p53 contribute to both nonspecific DNA-binding and oligomerization, they are not required for sequence-specific DNA-binding.

Measurement of gene expression by translational coupling: effect of copy mutations on pT181 initiator synthesis.

We have prepared and analyzed two types of gene fusion between the replication initiator gene, repC, and the reporter gene, blaZ, in order to investigate the relationship between pT181 plasmid copy number and RepC initiator protein production. A series of pT181 copy mutant plasmids, with copy numbers ranging from 70 to 800 copies per cell, were analyzed. In one type of gene fusion used in this study, blaZ was translationally coupled to the C-terminal end of the repC coding sequence such that native forms of both proteins were produced. This gene fusion arrangement, which permitted monitoring of RepC production (as BlaZ activity) by plasmids using the protein for their own replication, demonstrated a linear relationship, with one exception, between RepC production and plasmid copy number over a 20-fold range. In the second type of fusion, blaZ was translationally fused to the C-terminal end of repC. As the translational fusion did not produce active RepC protein, the fusion-containing pT181 derivatives were maintained in a strain which provided RepC in trans, and were thus analyzed at constant copy number. In contrast to previous analyses of this type, our translational fusion constructs expressed repC at levels proportional to the copy numbers of the plasmids from which the fusions were prepared. Using these data, we have calculated a minimum figure for the number of RepC molecules synthesized per replication event.

The p53 protein is an unusually shaped tetramer that binds directly to DNA.

We have analyzed the size and structure of native immunopurified human p53 protein. By using a combination of chemical crosslinking, gel filtration chromatography, and zonal velocity gradient centrifugation, we have determined that the predominant form of p53 in such preparations is a tetramer. The behavior of purified p53 in gels and sucrose gradients implies that the protein has an extended shape. Wild-type p53 has been shown to bind specifically to sites in cellular and viral DNA. We show in this study by Southwestern ligand blotting and by analysis of DNA-bound crosslinked p53 that p53 monomers, dimers, and tetramers can bind directly to DNA.

Site-specific binding of wild-type p53 to cellular DNA is inhibited by SV40 T antigen and mutant p53.

Wild-type p53 protein was shown to bind specifically to DNA sequences within SV40 (Bargonetti et al. 1991), the human ribosomal gene cluster (RGC) (Kern et al. 1991a), and the murine muscle creatine kinase gene (MCK) (Zambetti et al. 1992). However, a direct comparison of these three sites was not performed. Here we demonstrate, by filter binding and gel mobility-shift assays, that wild-type p53 binds with similar affinities to MCK and RGC sites but less tightly to the SV40 site. We examined the effects of two candidate regulators of p53 function, SV40 large T antigen and oncogenic mutant p53, on the binding of wild-type p53 to RGC DNA. We show that wild-type T antigen prevents p53 from binding to the RGC site under all conditions tested. Moreover, two temperature-sensitive mutant SV40 T antigens, which fail to transform cells at the nonpermissive temperature, prevent p53 from binding to the RGC site at the permissive, but not at the restrictive, temperature. The ability of complexes containing wild-type p53 and tumor-derived mutant p53 proteins to bind to RGC DNA varies according to the position of the mutation. Complexes containing wild-type and either his175 or his273 mutant p53 proteins are completely unable to bind to the RGC DNA sequence. Interestingly, a complex containing wild-type p53 and the trp248 mutant p53 characteristic of Li-Fraumeni syndrome patients displays nearly wild-type levels of binding. Perhaps this mutant allele can be tolerated in these individuals because the wild-type mutant p53 complex maintains the ability to bind to DNA. Our data indicate that the oncogenic potential of both T antigen and some mutant p53 proteins is the result of their ability to block binding of wild-type p53 to DNA.

Wild-type p53 mediates positive regulation of gene expression through a specific DNA sequence element.

It has been reported recently that the wild-type p53 gene product can positively regulate the expression of a test gene adjacent to the enhancer-promoter elements of the murine muscle-specific creatine kinase (MCK) gene. This discussion reports the identification of a wild-type p53 protein-specific DNA-binding element located within the p53-responsive region of the MCK enhancer-promoter element. This p53 protein/DNA-binding element has been defined by DNase I footprint analysis, which identified a 50-bp region. This 50-bp sequence was sufficient to confer wild-type p53 responsiveness on a heterologous minimal promoter. The mutant forms of p53 protein are much less capable of stimulating this DNA element. This study has identified the first example of a naturally occurring wild-type p53-specific DNA-binding element that is able to mediate positive regulation of a test gene. The results suggest a biological function in gene regulation for the wild-type p53 protein that is lost or altered in the mutant p53 proteins.

Wild-type p53 activates transcription in vitro.

The p53 protein is an important determinant in human cancer and regulates the growth of cells in culture. It is known to be a sequence-specific DNA-binding protein with a powerful activation domain, but it has not been established whether it regulates transcription directly. Here we show that intact purified wild-type human and murine p53 proteins strongly activate transcription in vitro. This activation depends on the ability of p53 to bind to a template bearing a p53-binding sequence. By contrast, tumour-derived mutant p53 proteins cannot activate transcription from the template at all, and when complexed to wild-type p53, these mutants block transcriptional activation by the wild-type protein. Moreover, the simian virus 40 large T antigen inhibits wild-type p53 from activating transcription. Our results support a model in which p53 directly activates transcription but this activity can be inhibited by mutant p53 and SV40 large T antigen through interaction with wild-type p53.

Wild-type but not mutant p53 immunopurified proteins bind to sequences adjacent to the SV40 origin of replication.

The DNA from a wide variety of human tumors has sustained mutations within the conserved p53 coding regions. We have purified wild-type and tumor-derived mutant p53 proteins expressed from baculovirus vectors and examined their interactions with SV40 DNA. Using DNAase I footprinting assays, we observed that both human and murine wild-type p53 proteins bind specifically to sequences adjacent to the late border of the viral replication origin. By contrast, mutant p53 proteins failed to bind specifically to these sequences. SV40 T antigen prevented wild-type p53 from interacting with this region. These data show that normal but not oncogenic forms of p53 are capable of sequence-specific interactions with viral DNA. Furthermore, they provide insights into the mechanisms by which viral proteins might regulate the control of viral growth and cell division.

Initiation of rolling-circle replication in pT181 plasmid: initiator protein enhances cruciform extrusion at the origin.

Plasmid pT181 DNA secondary structures have been analyzed in vitro by nuclease S1 digestion and in vivo by bromoacetaldehyde treatment. A cruciform structure occurring at the pT181 replication origin in vitro is greatly enhanced by the binding of the plasmid-encoded initiator protein RepC. In vivo a DNA secondary structure also existed in the replication origin. Its frequency of formation was correlated with efficiency of RepC utilization. These data suggest that cruciform extrusion at the origin is involved in initiation of pT181 rolling-circle replication. A neighboring DNA structure influences the conformation of the origin in vivo.

Staphylococcus aureus chromosomal mutations that decrease efficiency of Rep utilization in replication of pT181 and related plasmids.

Staphylococcus aureus chromosomal mutants which maintain pT181 and related plasmids at a much reduced copy number but which do not affect the replication of other plasmids have been isolated. The origin of replication and the initiator protein of the affected plasmids are the only elements required for the response to these mutations. The host mutations do not interfere with the pT181 replication control mechanism.