Involvement of ATM in homologous recombination after end resection and RAD51 nucleofilament formation.

Ataxia-telangiectasia mutated (ATM) is needed for the initiation of the double-strand break (DSB) repair by homologous recombination (HR). ATM triggers DSB end resection by stimulating the nucleolytic activity of CtIP and MRE11 to generate 3'-ssDNA overhangs, followed by RPA loading and RAD51 nucleofilament formation. Here we show for the first time that ATM is also needed for later steps in HR after RAD51 nucleofilament formation. Inhibition of ATM after completion of end resection did not affect RAD51 nucleofilament formation, but resulted in HR deficiency as evidenced by (i) an increase in the number of residual RAD51/γH2AX foci in both S and G2 cells, (ii) the decrease in HR efficiency as detected by HR repair substrate (pGC), (iii) a reduced SCE rate and (iv) the radiosensitization of cells by PARP inhibition. This newly described role for ATM was found to be dispensable in heterochromatin-associated DSB repair, as KAP1-depletion did not alleviate the HR-deficiency when ATM was inhibited after end resection. Moreover, we demonstrated that ATR can partly compensate for the deficiency in early, but not in later, steps of HR upon ATM inhibition. Taken together, we describe here for the first time that ATM is needed not only for the initiation but also for the completion of HR.

p53 modulates homologous recombination at I-SceI-induced double-strand breaks through cell-cycle regulation.

Inhibition of homologous recombination (HR) is believed to be a transactivation-independent function of p53 that protects from genetic instability. Misrepair by HR can lead to genetic alterations such as translocations, duplications, insertions and loss of heterozygosity, which all bear the risk of driving oncogenic transformation. Regulation of HR by wild-type p53 (wtp53) should prevent these genomic rearrangements. Mutation of p53 is a frequent event during carcinogenesis. In particular, dominant-negative mutants inhibiting wtp53 expressed from the unperturbed allel can drive oncogenic transformation by disrupting the p53-dependent anticancer barrier. Here, we asked whether the hot spot mutants R175H and R273H relax HR control in p53-proficient cells. Utilizing an I-SceI-based reporter assay, we observed a moderate (1.5 × ) stimulation of HR upon expression of the mutant proteins in p53-proficient CV-1, but not in p53-deficient H1299 cells. Importantly, the stimulatory effect was exactly paralleled by an increase in the number of HR competent S- and G2-phase cells, which can well explain the enhanced recombination frequencies. Furthermore, the impact on HR exerted by the transactivation domain double-mutant L22Q/W23S and mutant R273P, both of which were reported to regulate HR independently of G1-arrest execution, is also exactly mirrored by cell-cycle behavior. These results are in contrast to previous concepts stating that the transactivation-independent impact of p53 on HR is a general phenomenon valid for replication-associated and also for directly induced double-strand break. Our data strongly suggest that the latter is largely mediated by cell-cycle regulation, a classical transactivation-dependent function of p53.

Multiple phosphorylation sites of DNA polymerase alpha-primase cooperate to regulate the initiation of DNA replication in vitro.

DNA polymerase alpha-primase (pol-prim) is the only enzyme that can start DNA replication de novo. The 180-kDa (p180) and 68-kDa (p68) subunits of the human four-subunit enzyme are phosphorylated by Cyclin-dependent kinases (Cdks) in a cell cycle-dependent manner. Cyclin A-Cdk2 physically interacts with pol-prim and phosphorylates N-terminal amino acids of the p180 and the p68 subunits, leading to an inhibition of pol-prim in initiating cell-free SV40 DNA replication. Mutation of conserved putative Cdk phosphorylation sites in the N terminus of human p180 and p68 reduced their phosphorylation by Cyclin A-Cdk2 in vitro. In contrast to wild-type pol-prim these mutants were no longer inhibited by Cyclin A-Cdk2 in the initiation of viral DNA replication. Importantly, rather than inhibiting it, Cyclin A-Cdk2 stimulated the initiation activity of pol-prim containing a triple N-terminal alanine mutant of the p180 subunit. Together these results suggest that Cyclin A-Cdk2 executes both stimulatory and inhibitory effects on the activity of pol-prim in initiating DNA replication.

Two immunologically distinct human DNA polymerase alpha-primase subpopulations are involved in cellular DNA replication.

Metabolic labeling of primate cells revealed the existence of phosphorylated and hypophosphorylated DNA polymerase alpha-primase (Pol-Prim) populations that are distinguishable by monoclonal antibodies. Cell cycle studies showed that the hypophosphorylated form was found in a complex with PP2A and cyclin E-Cdk2 in G1, whereas the phosphorylated enzyme was associated with a cyclin A kinase in S and G2. Modification of Pol-Prim by PP2A and Cdks regulated the interaction with the simian virus 40 origin-binding protein large T antigen and thus initiation of DNA replication. Confocal microscopy demonstrated nuclear colocalization of hypophosphorylated Pol-Prim with MCM2 in S phase nuclei, but its presence preceded 5-bromo-2'-deoxyuridine (BrdU) incorporation. The phosphorylated replicase exclusively colocalized with the BrdU signal, but not with MCM2. Immunoprecipitation experiments proved that only hypophosphorylated Pol-Prim associated with MCM2. The data indicate that the hypophosphorylated enzyme initiates DNA replication at origins, and the phosphorylated form synthesizes the primers for the lagging strand of the replication fork.

The dual role model for p53 in maintaining genomic integrity.

The tumour suppressor p53 is a potent mediator of cellular responses against genotoxic insults. In this review we describe the multiple functions of p53 in response to DNA damage, with an emphasis on p53's role in DNA repair. We summarize data demonstrating that p53 actively participates in various processes of DNA repair and DNA recombination via its ability to interact with components of the repair and recombination machinery, and by its various biochemical activities. An important aspect in evaluating p53 functions is provided by the finding that the core domain of p53 harbours two mutually exclusive biochemical activities, sequence-specific DNA binding required for its transactivation function, and 3'-5' exonuclease activity, possibly involved in aspects of DNA repair. Based on the finding that modifications of p53 which lead to activation of its sequence-specific DNA-binding activity result in inactivation of its 3'-5' exonuclease activity, we propose that p53 exerts its functions as a 'guardian of the genome' at various levels: in its noninduced state, p53 should not be regarded as a 'dead' protein but, for example, via its exonuclease activity might be actively involved in prevention and repair of endogenous DNA damage. Upon induction through exogenous DNA damage, p53 will exert its well-documented functions as a superior response element in various types of cellular stress. This dual role model for p53 in maintaining genomic integrity significantly enhances p53's possibilities as a guardian of the genome.

Maintenance of genomic integrity by p53: complementary roles for activated and non-activated p53.

In this review we describe the multiple functions of p53 in response to DNA damage, with an emphasis on p53's role in DNA repair. We summarize data demonstrating that p53, through its various biochemical activities and via its ability to interact with components of the repair and recombination machinery, actively participates in various processes of DNA repair and DNA recombination. An important aspect in evaluating p53 functions arises from the finding that the p53 core domain harbors two mutually exclusive biochemical activities, sequence-specific DNA binding, required for its transactivation function, and 3'->5' exonuclease activity, possibly involved in various aspects of DNA repair. As modifications of p53 that lead to activation of its sequence-specific DNA-binding activity result in inactivation of its 3'-> 5' exonuclease activity, we propose that p53 exerts its functions as a 'guardian of the genome' at various levels: in its non-induced state, p53 should not be regarded as a non-functional protein, but might be actively involved in prevention and repair of endogenous DNA damage, for example via its exonuclease activity. Upon induction through exogenous DNA damage, p53 will exert its well-documented functions as a superior response element in various types of cellular stress. The dual role model for p53 in maintaining genomic integrity significantly enhances p53's possibilities as a guardian of the genome.

DNA polymerase epsilon may be dispensable for SV40- but not cellular-DNA replication.

The contributions of DNA polymerases alpha, delta, and epsilon to SV40 and nuclear DNA syntheses were evaluated. Proteins were UV-crosslinked to nascent DNA within replicating chromosomes and the photolabelled polymerases were immunopurified. Only DNA polymerases alpha and delta were detectably photolabelled by nascent SV40 DNA, whether synthesized in soluble viral chromatin or within nuclei isolated from SV40-infected cells. In contrast, all three enzymes were photolabelled by the nascent cellular DNA. Mitogenic stimulation enhanced the photolabelling of the polymerases in the alpha>delta>epsilon order of preference. The data agree with the notion that DNA polymerases alpha and delta catalyse the principal DNA polymerisation reactions at the replication fork of SV40 and, perhaps, also of nuclear chromosomes. DNA polymerase epsilon, implicated by others as a cell-cycle checkpoint regulator sensing DNA replication lesions, may be dispensable for replication of the small, fast propagating virus that subverts cell cycle controls.

Species-specific functional interactions of DNA polymerase alpha-primase with simian virus 40 (SV40) T antigen require SV40 origin DNA.

Physical and functional interactions of simian virus 40 (SV40) and polyomavirus large-T antigens with DNA polymerase alpha-primase were analyzed to elucidate the molecular basis for the species specificity of polymerase alpha-primase in viral DNA replication. SV40 T antigen associated more efficiently with polymerase alpha-primase in crude human extracts than in mouse extracts, while polyomavirus T antigen interacted preferentially with polymerase alpha-primase in mouse extracts. The apparent species specificity of complex formation was not observed when purified polymerase alpha-primases were substituted for the crude extracts. Several functional interactions between T antigen and purified polymerase alpha-primase, including stimulation of primer synthesis and primer elongation on M13 DNA in the presence or absence of the single-stranded DNA binding protein RP-A, also proved to be independent of the species from which polymerase alpha-primase had been purified. However, the human DNA polymerase alpha-primase was specifically required for primosome assembly and primer synthesis on SV40 origin DNA in the presence of T antigen and RP-A.

Initiation of simian virus 40 DNA replication requires the interaction of a specific domain of human DNA polymerase alpha with large T antigen.

Initiation of cell-free simian virus 40 (SV40) DNA replication requires the interaction of DNA polymerase alpha/primase with a preinitiation complex containing the viral T antigen and cellular proteins, replication protein A, and topoisomerase I or II. To further understand the molecular mechanisms of the transition from preinitiation to initiation, the intermolecular interaction between human DNA polymerase alpha and T antigen was investigated. We have demonstrated that the human DNA polymerase alpha catalytic polypeptide is able to associate with SV40 large T antigen directly under physiological conditions. A physical association between these two proteins was detected by coimmunoprecipitation with monoclonal antibodies from insect cells coinfected with recombinant baculoviruses. A domain of human polymerase alpha physically interacting with T antigen was identified within the amino-terminal region from residues 195 to 313. This domain of human polymerase alpha was able to form a nonproductive complex with T antigen, causing inhibition of the SV40 DNA replication in vitro. Kinetics of the inhibition indicated that this polymerase domain can inhibit viral replication only during the preinitiation stage. Extra molecules of T antigen could partially overcome the inhibition only prior to initiation complex formation. The data support the conclusion that initiation of SV40 DNA replication requires the physical interaction of T antigen in the preinitiation complex with the amino-terminal domain of human polymerase alpha from amino acid residues 195 to 313.

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.

Purification and functional characterization of bovine RP-A in an in vitro SV40 DNA replication system.

The single-stranded DNA binding protein RP-A is required in SV40 DNA in 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 replication in vitro. A modified blotting technique revealed that RP-A interacts specifically and directly with the p48 subunit of DNA polymerase alpha-primase complex.

Altered phosphorylation pattern of simian virus 40 T antigen expressed in insect cells by using a baculovirus vector.

The phosphorylation pattern of simian virus 40 (SV40) large tumor (T) antigen purified from insect cells infected with a recombinant baculovirus was compared with that reported previously for T antigen from SV40-infected monkey cells. The specific activity of metabolic phosphate labeling of baculovirus T antigen was reduced, and the phosphopeptide map of the baculovirus protein, while qualitatively similar to that of lytic T, revealed several quantitative differences. The most striking difference was the prominence in the baculovirus map of peptides containing phosphothreonine 124. These peptides are known to arise from other phosphopeptides upon dephosphorylation of neighboring serines, suggesting that baculovirus T may be underphosphorylated at these serines and perhaps other sites. Functional assays used to further investigate the phosphorylation state of the baculovirus protein included SV40 DNA binding after enzymatic dephosphorylation with alkaline phosphatase and after phosphorylation by a murine homolog of cdc2 protein kinase. The results imply that baculovirus T antigen is underphosphorylated, in particular at those serine residues whose phosphorylation is responsible for down regulation of DNA-binding activity at site II in the core origin of DNA replication. In contrast, no evidence for a functionally significant underphosphorylation at threonine 124 could be found.

SV40 T antigen binds directly to the large subunit of purified DNA polymerase alpha.

Purified SV40 large T antigen and purified DNA polymerase alpha-primase form a complex detectable by ELISA and by a modified immunoblotting technique. The interaction is specific for the large catalytic subunit of polymerase alpha. The amino terminal 83 amino acids of T antigen are both necessary and sufficient for binding to the polymerase. However, antibody epitopes located in the carboxy terminal ATPase domain of T antigen are masked in the polymerase-T antigen complex, and complex formation is inhibited by an antibody directed against the carboxy terminus of T antigen, suggesting that this region of T antigen, though not required for binding, is in close proximity to the bound polymerase. The affinity of human DNA polymerase alpha for T antigen is approximately 10-fold greater than that of polymerase alpha from calf thymus, consistent with the interpretation that polymerase alpha is at least in part responsible for the primate-specific replication of SV40 DNA in vivo and in vitro. The results suggest that specific protein-protein interaction between DNA polymerase alpha and T antigen plays an important role in viral DNA replication.