Sequence-specific and DNA structure-dependent interactions of Escherichia coli MutS and human p53 with DNA

Many proteins involved in DNA repair systems interact with DNA that has structure altered from the typical B-form helix. Using magnetic beads to immobilize DNAs containing various types of structures, we evaluated the in vitro binding activities of two well-characterized DNA repair proteins, Escherichia coli MutS and human p53. E. coli MutS bound to double-stranded DNAs, with higher affinity for a G/T mismatch compared to a G/A mismatch and highest affinity for larger non-B-DNA structures. E. coli MutS bound best to DNA between pH 6 and 9. Experiments discriminated between modes of p53–DNA binding, and increasing ionic strength reduced p53 binding to nonspecific double-stranded DNA, but had minor effects on binding to consensus response sequences or single-stranded DNA. Compared to nonspecific DNA sequences, p53 bound with a higher affinity to mismatches and base insertions, while binding to various hairpin structures was similar to that observed to its consensus DNA sequence. For hairpins containing CTG repeats, the extent of p53 binding was proportional to the size of the repeat. In summary, using the flexibility of the magnetic bead separation assay we demonstrate that pH and ionic strength influence the binding of two DNA repair proteins to a variety of DNA structures.     

Effects of T antigen and replication protein A on the initiation of DNA synthesis by DNA polymerase alpha-primase.

Studies of simian virus 40 (SV40) DNA replication in a reconstituted cell-free system have established that T antigen and two cellular replication proteins, replication protein A (RP-A) and DNA polymerase alpha-primase complex, are necessary and sufficient for initiation of DNA synthesis on duplex templates containing the SV40 origin of DNA replication. To better understand the mechanism of initiation of DNA synthesis, we analyzed the functional interactions of T antigen, RP-A, and DNA polymerase alpha-primase on model single-stranded DNA templates. Purified DNA polymerase alpha-primase was capable of initiating DNA synthesis de novo on unprimed single-stranded DNA templates. This reaction involved the synthesis of a short oligoribonucleotide primer which was then extended into a DNA chain. We observed that the synthesis of ribonucleotide primers by DNA polymerase alpha-primase is dramatically stimulated by SV40 T antigen. The presence of T antigen also increased the average length of the DNA product synthesized on primed and unprimed single-stranded DNA templates. These stimulatory effects of T antigen required direct contact with DNA polymerase alpha-primase complex and were most marked at low template and polymerase concentrations. We also observed that the single-stranded DNA binding protein, RP-A, strongly inhibits the primase activity of DNA polymerase alpha-primase, probably by blocking access of the enzyme to the template. T antigen partially reversed the inhibition caused by RP-A. Our data support a model in which DNA priming is mediated by a complex between T antigen and DNA polymerase alpha-primase with the template, while RP-A acts to suppress nonspecific priming events.     

DNA unwinding by replication protein A is a property of the 70 kDa subunit and is facilitated by phosphorylation of the 32 kDa subunit.

Replication protein A (RP-A) is a heterotrimeric single-stranded DNA binding protein with important functions in DNA replication, DNA repair and DNA recombination. We have found that RP-A from calf thymus can unwind DNA in the absence of ATP and MgCl2, two essential cofactors for bona fide DNA helicases (Georgaki, A., Strack, B., Podust, V. and Hübscher, U. FEBS Lett. 308, 240-244, 1992). DNA unwinding by RP-A was found to be sensitive to MgCl2, ATP, heating and freezing/thawing. Escherichia coli single stranded DNA binding protein at concentrations that coat the single stranded regions had no influence on DNA unwinding by RP-A suggesting that RP-A binds fast and tightly to single-stranded DNA. DNA unwinding by RP-A did not show directionality. Experiments with monoclonal antibodies strongly suggested that the 70kDa subunit is responsible for DNA unwinding. Phosphorylation of the 32kDa subunit of RP-A by chicken cdc2 kinase facilitated DNA unwinding indicating that this posttranslational modification might be important for modulating this activity of RP-A. Finally, DNA unwinding of a primer recognition complex for DNA polymerase delta which is composed of proliferating cell nuclear antigen, replication factor C and ATP bound to a singly-primed M13DNA slightly inhibited DNA unwinding. An important role for DNA unwinding by RP-A in processes such as initiation of DNA replication, fork propagation, DNA repair and DNA recombination is discussed.     

Purification and functional characterization of bovine RP-A in an<Emphasis Type="Italic">in vitro</Emphasis> SV40 DNA replication system

The single-stranded DNA binding protein RP-A is required in SV40 DNAin vitro replication. The RP-A purified from calf thymus contains 4 polypeptides with molecular weights 70kDa, 53kDa, 32kDa, and 14kDa. The p70 subunit and its proteolysed form p53 are recognized by the monoclonal antibody 70C (Kenny et al. (1990)) and bind to ssDNA. The p70 and p32 subunits of bovine RP-A are phosphorylated by CDC2-cyclin B kinase. Bovine RP-A supports the origin dependent unwinding of SV40 DNA by T antigen. Furthermore, bovine RP-A can efficiently substitute for human RP-A in SV40 DNA replicationin vitro. A modified blotting technique revealed that RP-A interacts specifically and directly with the p48 subunit of DNA polymerase α-primase complex.     

63 EMSA detection of p53 sequence non-specific binding in PCR produced human DNA analogues

p53 is a tumor suppressor that induces cell cycle arrest and apoptosis in response to DNA damage and cancerogenesis. Its ability to bind DNA, and thus play its biological role, is possible in two manners: sequence-specific binding to its consensus sequence (p53CON) and sequence non-specific binding, which occurs preferably in higher DNA structures. Recently, it has been proven that DNA quadruplexes occur in regulation areas of most cancer genes. In our study, we have tested human DNA cloned into plasmid vectors. The DNAs were obtained by chromatin immunoprecipitation of regions which were bound by p53 with high affinity, although they do not contain p53CON. The sequence studied in this work is located in a noncoding region of human chromosome 7. We suggest that structure-specific binding is responsible for higher affinity of p53 binding in these areas. It has been previously found that some single-stranded regions appeared in these areas, suggesting the presence of higher DNA structures by S1 nuclease digestion (unpublished results). Because we were unable to detect the exact location of p53 binding with sufficient resolution by standard methods, we have amplified different parts of immunoprecipitated DNAs by PCR and found, using EMSA, to what part of the insert p53 binds with the highest affinity. This area is represented by cca 150 nucleotides. The strongest preference of p53 was found for the region which contained repeated short tracts of 3–4 Ts and a short polyPu.polyPy sequence. It is known that dAn:dTn blocks can cause DNA curvature, and the polyPu.polyPy sequence is able to form an intramolecular triplex.     

Binding properties of replication protein A from human and yeast cells.

Replication protein A (RP-A; also known as replication factor A and human SSB), is a single-stranded DNA-binding protein that is required for simian virus 40 DNA replication in vitro. RP-A isolated from both human and yeast cells is a very stable complex composed of 3 subunits (70, 32, and 14 kDa). We have analyzed the DNA-binding properties of both human and yeast RP-A in order to gain a better understanding of their role(s) in DNA replication. Human RP-A has high affinity for single-stranded DNA and low affinity for RNA and double-stranded DNA. The apparent affinity constant of RP-A for single-stranded DNA is in the range of 10(9) M-1. RP-A has a binding site size of approximately 30 nucleotides and does not bind cooperatively. The binding of RP-A to single-stranded DNA is partially sequence dependent. The affinity of human RP-A for pyrimidines is approximately 50-fold higher than its affinity for purines. The binding properties of yeast RP-A are similar to those of the human protein. Both yeast and human RP-A bind preferentially to the pyrimidine-rich strand of a homologous origin of replication: the ARS307 or the simian virus 40 origin of replication, respectively. This asymmetric binding suggests that RP-A could play a direct role in the process of initiation of DNA replication.     

Interaction of DNA polymerase alpha-primase with cellular replication protein A and SV40 T antigen.

The purified human single-stranded DNA binding protein, replication protein A (RP-A), forms specific complexes with purified SV40 large T antigen and with purified DNA polymerase alpha-primase, as shown by ELISA and a modified immunoblotting technique. RP-A associated efficiently with the isolated primase, as well as with intact polymerase alpha-primase. The 70 kDa subunit of RP-A was sufficient for association with polymerase alpha-primase. Purified SV40 large T antigen bound to intact RP-A and to polymerase-primase, but not to any of the separated subunits of RP-A or to the isolated primase. These results suggest that the specific protein-protein interactions between RP-A, polymerase-primase and T antigen may play a role in the initiating of SV40 DNA replication.     

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.     

Searching for target sequences by p53 protein is influenced by DNA length

One of the most important functions of the tumor suppressor p53 protein is its sequence-specific binding to DNA. Using a competition assay on agarose gels we found that the p53 consensus sequences in longer DNA fragments are better targets than the same sequences in shorter DNAs. Semi-quantitative evaluation of the competition experiments showed a correlation between the relative p53-DNA binding and the DNA lengths. Our results are consistent with a model of the p53-DNA interactions involving one-dimensional migration of the p53 protein along the DNA for distances of about 1000 bp while searching for its target sites. Positioning of the p53 target in the DNA fragment did not substantially affect the apparent p53-DNA binding, suggesting that p53 can slide along the DNA in a bi-directional manner. In contrast to full-length p53, the isolated core domain did not show any significant correlation between sequence-specific DNA binding and fragment length.     

p53 Ser15 phosphorylation disrupts the p53-RPA70 complex and induces RPA70-mediated DNA repair in hypoxia

Cellular stressors are known to inhibit the p53-RPA70 (replication protein A, 70 kDa subunit) complex, and RPA70 increases cellular DNA repair in cancer cells. We hypothesized that regulation of RPA70-mediated DNA repair might be responsible for the inhibition of apoptosis in hypoxic tumours. We have shown that, in cancer cells, hypoxia disrupts the p53-RPA70 complex, thereby enhancing RPA70-mediated NER (nucleotide excision repair)/NHEJ (non-homologous end-joining) repair. In normal cells, RPA70 binds to the p53-NTD (N-terminal domain), whereas this binding is disrupted in hypoxia. Phosphorylation of p53-NTD is a crucial event in dissociating both NTD-RPA70 and p53-RPA70 complexes. Serial mutations at serine and threonine residues in the NTD confirm that p53(Ser15) phosphorylation induces dissociation of the p53-RPA70 complex in hypoxia. DNA-PK (DNA-dependent protein kinase) is shown to induce p53(Ser15) phosphorylation, thus enhancing RPA70-mediated NER/NHEJ repair. Furthermore, RPA70 gene silencing induces significant increases in cellular apoptosis in the resistant hypoxic cancer cells. We have thus elucidated a novel pathway showing how DNA-PK-mediated p53(Ser15) phosphorylation dissociates the p53-RPA70 complex, thus enhancing NER/NHEJ repair, which causes resistance to apoptosis in hypoxic cancer cells. This novel finding may open new strategies in developing cancer therapeutics on the basis of the regulation of RPA70-mediated NER/NHEJ repair.     

The interaction of p53 with 3'-terminal mismatched DNA

The diversity of p53 functions involves its interaction with sequence-specific, non-sequence-specific and various damaged sites in DNA. The preferential excision of misincorporated over correct nucleotides by the 3′→5′ exonuclease activity of p53 provides a molecular basis for p53 involvement in the correction of the DNA replication errors. However, p53 exhibits variations in its comparative efficiency to excise different 3'-terminal mismatched nucleotides. To determine the importance of the binding capacity of the protein to various 3'-terminal damaged sites, we have examined the interaction of p53 with linear dsDNAs containing various 3'-terminal mismatches, employing a gel retardation assay. The data demonstrate the intrinsic 3'-terminal mismatched DNA binding capacity of p53. Since p53 binds directly to various 3'-terminal purine:pyrimidine and purine:purine mispairs to an equal extent, p53 can be considered as a general 3'-mismatched DNA binding protein. Apparently, 3'-terminal mismatched bases are structural element to which p53 can bind, that extends the spectrum of damage sites to which p53 may respond. The formation of the p53-mismatched DNA complex is independent of the sequence context. Thus, the dissimilarities in mispair excision efficiency are probably due to an inherent property of the p53 in excision of 3'-mismatched nucleotides by a bound protein. The results establish a framework for understanding the mechanism of cooperative interaction between p53 and exonuclease-deficient DNA polymerase (e.g. HIV-1 RT). Within the context of error-correction events, p53 by recognition and excision of 3'-mismatched nucleotides from DNA, may be involved in DNA repair, thus increasing the accuracy of DNA synthesis by DNA polymerases.     

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.     

Regulation and localization of the Bloom syndrome protein in response to DNA damage

Bloom syndrome (BS) is an autosomal recessive disorder characterized by a high incidence of cancer and genomic instability. BLM, the protein defective in BS, is a RecQ-like helicase, presumed to function in DNA replication, recombination, or repair. BLM localizes to promyelocytic leukemia protein (PML) nuclear bodies and is expressed during late S and G2. We show, in normal human cells, that the recombination/repair proteins hRAD51 and replication protein (RP)-A assembled with BLM into a fraction of PML bodies during late S/G2. Biochemical experiments suggested that BLM resides in a nuclear matrix-bound complex in which association with hRAD51 may be direct. DNA-damaging agents that cause double strand breaks and a G2 delay induced BLM by a p53- and ataxia-telangiectasia mutated independent mechanism. This induction depended on the G2 delay, because it failed to occur when G2 was prevented or bypassed. It coincided with the appearance of foci containing BLM, PML, hRAD51 and RP-A, which resembled ionizing radiation-induced foci. After radiation, foci containing BLM and PML formed at sites of single-stranded DNA and presumptive repair in normal cells, but not in cells with defective PML. Our findings suggest that BLM is part of a dynamic nuclear matrix-based complex that requires PML and functions during G2 in undamaged cells and recombinational repair after DNA damage.     

Analysis of the binding of p53 to DNAs containing mismatched and bulged bases

The tumor suppressor protein p53 modulates cellular response to DNA damage by a variety of mechanisms that may include direct recognition of some forms of primary DNA damage. Linear 49-base pair duplex DNAs were constructed containing all possible single-base mismatches as well as a 3-cytosine bulge. Filter binding and gel retardation assays revealed that the affinity of p53 for a number of these lesions was equal to or greater than that of the human mismatch repair complex, hMSH2-hMSH6, under the same binding conditions. However, other mismatches including G/T, which is bound strongly by hMSH2-hMSH6, were poorly recognized by p53. The general order of affinity of p53 was greatest for a 3-cytosine bulge followed by A/G and C/C mismatches, then C/T and G/T mismatches, and finally all the other mismatches.     

Choreography of the DNA damage response: spatiotemporal relationships among checkpoint and repair proteins

DNA repair is an essential process for preserving genome integrity in all organisms. In eukaryotes, recombinational repair is choreographed by multiprotein complexes that are organized into centers (foci). Here, we analyze the cellular response to DNA double-strand breaks (DSBs) and replication stress in Saccharomyces cerevisiae. The Mre11 nuclease and the ATM-related Tel1 kinase are the first proteins detected at DSBs. Next, the Rfa1 single-strand DNA binding protein relocalizes to the break and recruits other key checkpoint proteins. Later and only in S and G2 phase, the homologous recombination machinery assembles at the site. Unlike the response to DSBs, Mre11 and recombination proteins are not recruited to hydroxyurea-stalled replication forks unless the forks collapse. The cellular response to DSBs and DNA replication stress is likely directed by the Mre11 complex detecting and processing DNA ends in conjunction with Sae2 and by RP-A recognizing single-stranded DNA and recruiting additional checkpoint and repair proteins.