p53 binds to cisplatin-damaged DNA

We have previously shown that bacterially expressed p53 protein or p53 protein isolated from cis-diamminedichloroplatinum II (cisplatin)-damaged cells is capable of binding to double-stranded platinated DNA molecules lacking any p53 DNA binding sites. Here we report using various p53 mutants that two separate domains of p53 protein affect p53 binding to platinated DNA. Mutations within the central core of p53, the domain responsible for sequence-specific DNA binding activity, completely eliminated p53 binding to platinated DNA. Based on competition experiments p53 preferred binding to sequence-specific DNA molecules over platinated DNA molecules. However, p53 binding to platinated DNA molecules was significantly stronger than p53 interactions with DNA molecules lacking damage and a p53 consensus site. Finally, an antibody specific to the C-terminal domain of p53 (pAb421) which activates sequence-specific DNA binding activity inhibited p53 binding to platinated DNA. Taken together, these results suggest that in addition to binding to p53 DNA binding sites, p53 also interacts with cisplatin-damaged DNA molecules.     

The DNA binding activity of p53 displays reaction-diffusion kinetics

The tumor suppressor protein p53 plays a key role in maintaining the genomic stability of mammalian cells and preventing malignant transformation. In this study, we investigated the intracellular diffusion of a p53-GFP fusion protein using confocal fluorescence recovery after photobleaching. We show that the diffusion of p53-GFP within the nucleus is well described by a mathematical model for diffusion of particles that bind temporarily to a spatially homogeneous immobile structure with binding and release rates k1 and k2, respectively. The diffusion constant of p53-GFP was estimated to be Dp53-GFP=15.4 microm2 s-1, significantly slower than that of GFP alone, DGFP=41.6 microm2 s-1. The reaction rates of the binding and unbinding of p53-GFP were estimated as k1=0.3 s-1 and k2=0.4 s-1, respectively, values suggestive of nonspecific binding. Consistent with this finding, the diffusional mobilities of tumor-derived sequence-specific DNA binding mutants of p53 were indistinguishable from that of the wild-type protein. These data are consistent with a model in which, under steady-state conditions, p53 is latent and continuously scans DNA, requiring activation for sequence-specific DNA binding.     

Analysis of a protein-binding domain of p53.

The tumor suppressor protein p53 was first isolated as a simian virus 40 large T antigen-associated protein and subsequently was found to function in cell proliferation control. Tumor-derived mutations in p53 occur predominantly in four evolutionarily conserved regions spanning approximately 50% of the polypeptide. Previously, three of these regions were identified as essential for T-antigen binding. We have examined the interaction between p53 and T antigen by using Escherichia coli-expressed human p53. By a combination of deletion analysis and antibody inhibition studies, a region of p53 that is both necessary and sufficient for binding to T antigen has been localized. This function is contained within residues 94 to 293, which include the four conserved regions affected by mutation in tumors. Residues 94 to 293 of p53 were expressed in both wild-type and mutant forms. T-antigen binding was unaffected by tumor-derived mutations which have been associated with the wild-type conformation of p53 but was greatly reduced by mutations which were previously shown to alter p53 conformation. Our results show that, like T-antigen binding to the Rb tumor suppressor protein, T antigen appears to interact with the domain of p53 that is commonly mutated in human tumors.     

Identification of a minimal transforming domain of p53: negative dominance through abrogation of sequence-specific DNA binding.

Mutations in the p53 gene are most frequent in cancer. Many p53 mutants possess transforming activity in vitro. In cells transformed by such mutants, the mutant protein is oligomerized with endogenous cell p53. To determine the relevance of oligomerization for transformation, miniproteins containing C-terminal portions of p53 were generated. These miniproteins, although carrying no point mutation, transformed at least as efficiently as full-length mutant p53. Transforming activity was coupled with the ability to oligomerize with wild-type p53, as well as with the ability to abrogate sequence-specific DNA binding by coexpressed wild-type p53. These findings suggest that p53-mediated transformation may operate through a dominant negative mechanism, involving the generation of DNA binding-incompetent oligomers.     

Cooperative binding of tetrameric p53 to DNA

We analysed by analytical ultracentrifugation and fluorescence anisotropy the binding of p53 truncation mutants to sequence-specific DNA. The synthetic 30 base-pair DNA oligomers contained the 20 base-pair recognition elements for p53, consisting of four sites of five base-pairs per p53 monomer. We found that the binding at low ionic strengths was obscured by artifacts of non-specific binding and so made measurements at higher ionic strengths. Analytical ultracentrifugation of the construct p53CT (residues 94-360, containing the DNA-binding core and tetramerization domains) gave a dissociation constant of approximately 3 microM for its dimer-tetramer equilibrium, similar to that of full-length protein. Analytical ultracentrifugation and fluorescence anisotropy showed that p53CT formed a complex with the DNA constructs with 2:1 stoichiometry (dimer:DNA). The binding of p53CT (1-100 nm range) to DNA was highly cooperative, with a Hill coefficient of 1.8 (dimer:DNA). The dimeric L344A mutant of p53CT has impaired tetramerization. It bound to full-length DNA p53 recognition sequence, but with sixfold less affinity than wild-type protein. It did not form a detectable complex with a 30-mer DNA construct containing two specific five base-pair sites and two random sites, emphasizing the high co-operativity of the binding. The fundamental active unit of p53 appears to be the tetramer, which is induced by DNA binding, although it is a dimer at low concentrations.     

Discrimination of DNA binding sites by mutant p53 proteins.

Critical determinants of DNA recognition by p53 have been identified by a molecular genetic approach. The wild-type human p53 fragment containing amino acids 71 to 330 (p53(71-330)) was used for in vitro DNA binding assays, and full-length human p53 was used for transactivation assays with Saccharomyces cerevisiae. First, we defined the DNA binding specificity of the wild-type p53 fragment by using systematically altered forms of a known consensus DNA site. This refinement indicates that p53 binds with high affinity to two repeats of PuGPuCA.TGPyCPy, a further refinement of an earlier defined consensus half site PuPuPuC(A/T).(T/A) GPyPyPy. These results were further confirmed by transactivation assays of yeast by using full-length human p53 and systematically altered DNA sites. Dimers of the pentamer AGGCA oriented either head-to-head or tail-to-tail bound efficiently, but transactivation was facilitated only through head-to-head dimers. To determine the origins of specificity in DNA binding by p53, we identified mutations that lead to altered specificities of DNA binding. Single-amino-acid substitutions were made at several positions within the DNA binding domain of p53, and this set of p53 point mutants were tested with DNA site variants for DNA binding. DNA binding analyses showed that the mutants Lys-120 to Asn, Cys-277 to Gln or Arg, and Arg-283 to Gln bind to sites with noncanonical base pair changes at positions 2, 3, and 1 in the pentamer (PuGPuCA), respectively. Thus, we implicate these residues in amino acid-base pair contacts. Interestingly, mutant Cys-277 to Gln bound a consensus site as two and four monomers, as opposed to the wild-type p53 fragment, which invariably binds this site as four monomers.     

A split-ubiquitin-based assay detects the influence of mutations on the conformational stability of the p53 DNA binding domain in vivo

Many mutations in the human tumor suppressor p53 affect the function of the protein by destabilizing the structure of its DNA binding domain. To monitor the effects of those mutations in vivo the stability of the DNA binding domain of p53 and some of its mutants was investigated with the split-ubiquitin (split-Ub) method. The split-Ub-derived in vivo data on the relative stability of the mutants roughly correlate with the quantitative data from in vitro denaturation experiments as reported in the literature. A variation of this assay allows visualizing the difference in stability between the wild-type p53 core and the mutant p53(V143A) by a simple growth assay.     

Investigations of the supercoil-selective DNA binding of wild type p53 suggest a novel mechanism for controlling p53 function.

The tumor suppressor protein, p53, selectively binds to supercoiled (sc) DNA lacking the specific p53 consensus binding sequence (p53CON). Using p53 deletion mutants, we have previously shown that the p53 C-terminal DNA-binding site (CTDBS) is critical for this binding. Here we studied supercoil-selective binding of bacterially expressed full-length p53 using modulation of activity of the p53 DNA-binding domains by oxidation of cysteine residues (to preclude binding within the p53 core domain) and/or by antibodies mapping to epitopes at the protein C-terminus (to block binding within the CTDBS). In the absence of antibody, reduced p53 preferentially bound scDNA lacking p53CON in the presence of 3 kb linear plasmid DNAs or 20 mer oligonucleotides, both containing and lacking the p53CON. Blocking the CTDBS with antibody caused reduced p53 to bind equally to sc and linear or relaxed circular DNA lacking p53CON, but with a high preference for the p53CON. The same immune complex of oxidized p53 failed to bind DNA, while oxidized p53 in the absence of antibody restored selective scDNA binding. Antibodies mapping outside the CTDBS did not prevent p53 supercoil-selective (SCS) binding. These data indicate that the CTDBS is primarily responsible for p53 SCS binding. In the absence of the SCS binding, p53 binds sc or linear (relaxed) DNA via the p53 core domain and exhibits strong sequence-specific binding. Our results support a hypothesis that alterations to DNA topology may be a component of the complex cellular regulatory mechanisms that control the switch between latent and active p53 following cellular stress.     

Wild-type alternatively spliced p53: binding to DNA and interaction with the major p53 protein in vitro and in cells.

A p53 variant protein (p53as) generated from alternatively spliced p53 RNA is expressed in normal and malignant mouse cells and tissues, and p53as antigen activity is preferentially associated with the G2 phase of the cell cycle, suggesting that p53as and p53 protein may have distinct properties. Using p53as and p53 proteins translated in vitro, we now provide evidence that p53as protein has efficient sequence-specific DNA-binding ability. DNA binding by p53 protein is inefficient in comparison and requires activation. Furthermore, p53as and p53 proteins formed hetero-oligomers when co-translated in vitro, resulting in inactivation of p53as DNA-binding activity. Gel filtration indicated that p53as translated in vitro, like p53, formed tetramers. In support of a functional role of p53as in cells, p53as/p53 hetero-oligomers were coimmunoprecipitated from mouse cells, and both protein forms were detectable in nuclear extracts by electrophoretic mobility shift assays. These results suggest that the biochemical functions of p53 are mediated by interaction between two endogenous protein products of the wild-type p53 gene.     

Tight DNA binding and oligomerization are dispensable for the ability of p53 to transactivate target genes and suppress transformation.

The p53 tumor suppressor protein can bind tightly to specific sequence elements in the DNA and induce the transactivation of genes harboring such p53 binding sites. Various lines of evidence suggest that p53 binds to its target site as an oligomer. To test whether oligomerization is essential for the biological and biochemical activities of p53, we deleted a major part of the dimerization domain of mouse wild-type p53. The resultant protein, termed p53wt delta SS, was shown to be incapable of forming detectable homo-oligomers in vitro and is, therefore, likely to be predominantly if not exclusively monomeric. In agreement with the accepted model, p53wt delta SS indeed failed to exhibit measurable DNA binding in vitro. Surprisingly, though, it was still capable of suppressing oncogene-mediated transformation and of transactivating in vivo a target gene containing p53 binding sites. These findings indicate that dimerization-defective p53 is biologically active and may engage in productive sequence-specific DNA interactions in vivo. Furthermore, p53 dimerization probably leads to cooperative binding to specific DNA sequences.     

p53 binds single-stranded DNA ends through the C-terminal domain and internal DNA segments via the middle domain.

We have previously reported that wild-type p53 can bind single-stranded (ss) DNA ends and catalyze renaturation of ss complementary DNA molecules. Here we demonstrate that p53 can also bind to internal segments of ss DNA molecules via a binding site (internal DNA site) distinct from the binding site for DNA ends (DNA end site). Using p53 deletion mutants, the internal DNA site was mapped to the central region (residues 99-307), while the DNA end site was mapped to the C-terminal domain (residues 320-393) of the p53 protein. The internal DNA site can be activated by the binding of ss DNA ends to the DNA end site. The C-terminal domain alone was sufficient to catalyze DNA renaturation, although the central domain was also involved in promotion of renaturation by the full-length protein. Our results suggest that the interaction of the C-terminal tail of p53 with ss DNA ends generated by DNA damage in vivo may lead to activation of non-specific ss DNA binding by the central domain of p53.