Cellular factors required for multiple stages of SV40 DNA replication in vitro

Physical interaction between human RAD52 and RPA is required for homologous recombination in mammalian cells

The yeast RAD52 protein is essential for DNA double-strand break repair, and meiotic and mitotic recombination. RPA is a protein complex of three subunits (70, 34, and 11 kDa) that has been shown to be involved in DNA replication, nucleotide excision repair, and homologous recombination. Here, we demonstrate a physical interaction between human RAD52 and RPA in vivo and in vitro. In addition, the domain (amino acids 221-280) in RAD52 protein that mediates the interaction with the 34-kDa subunit of RPA was also determined. Overexpression of mutant RAD52 proteins lacking the interaction domain (amino acids 221-240, 241-260, and 261-280) failed to induce homologous recombination in monkey cells. We have previously shown that overexpression of human RAD52 induced homologous recombination in these cells. These results suggest that direct physical interactions between RAD52 and RPA are essential for homologous recombination in mammalian cells.

Dissection of functional domains of the human DNA replication protein complex replication protein A

Replication protein A (RPA) is a mammalian single-stranded DNA binding factor essential for DNA replication, repair, and recombination. It is composed of three subunits of 70, 34, and 13 kDa (Rpa1, Rpa2, and Rpa3, respectively). Deletion mapping of the Rpa2 subunit identified the domain required for interaction with Rpa1 and Rpa3 which does not include the N-terminal domain that is phosphorylated during S phase. Deletion mapping of Rpa1 defined three domains. The C-terminal third of the Rpa1 polypeptide binds Rpa2 which itself forms a bridge between Rpa1 and Rpa3. The N-terminal third of Rpa1 bound single-stranded DNA under low stringency conditions only (0.1 M NaCl), while a central domain binds to single-stranded DNA under both low and high stringency conditions (0.5 M NaCl). Binding to p53 requires the N-terminal third of Rpa1 with some contribution from the C-terminal third. The evolutionarily conserved putative zinc finger near the C terminus of Rpa1 was not required for binding to single-stranded DNA, Rpa2, or p53. However, all three subdomains of Rpa1 and the zinc finger were essential for supporting DNA replication in vitro. These experiments are a first step toward defining peptide components responsible for the many functions of the RPA protein complex.

The DNA-dependent protein kinase, DNA-PK: 10 years and no ends in sight

The phenomenon of DNA-dependent protein phosphorylation was first described little over 10 years ago. Since then a DNA-dependent protein kinase, DNA-PK, has been purified from human cells and many of its biochemical properties have been characterized. DNA-PK is composed of a large catalytic subunit, DNA-PKcs, and a DNA-targeting protein, Ku. When assembled on a suitable DNA molecule, the DNA-PK holoenzyme acts as a serine/threonine protein kinase that in vitro phosphorylates many DNA binding and non-binding proteins and transcription factors. Recent genetic studies point strongly to functions in DNA double-strand break repair and V(D)J recombination. In addition, biochemical studies suggest a role in the regulation of transcription. Here we discuss, from a historical perspective, the events leading up to our current understanding of the function of DNA-PK, including recent results from our own studies suggesting the involvement of DNA-PK in apoptosis and in viral infection of human cells.

Role of the 70-kDa subunit of human replication protein A (I). Single-stranded dna binding activity, but not polymerase stimulatory activity, is required for DNA replication

Replication protein A (RPA), also known as human single-stranded DNA-binding protein, is a three-subunit protein complex with multiple functions. Here, we investigated the role of the 70-kDa RPA subunit (p70) in DNA replication, by generating a series of deletion mutants. Mutant p70, which lacked 50 amino acids at the C-terminus, failed to interact with the 11-kDa RPA subunit (p11) and, when deleted further at the C terminus, was unable to interact with either the 34-kDa subunit (p34) or with p11, suggesting that p70 directly interacts with both p34 and p11. Studies with purified RPA mutants indicated that deletions at the N-terminal domain of p70 had very little effect on RPA's single-stranded DNA (ssDNA) binding activity, whereas deletion of amino acids 169-246 significantly weakened the DNA binding ability of RPA. By deleting amino acids 296-373 or 374-458, we totally abolished p70's ssDNA binding activity, suggesting that multiple p70 domains are involved in DNA binding. Two p70 domains, the N-terminal domain and the DNA binding domain, were required to stimulate DNA polymerase (pol) alpha, yet the DNA binding domain alone supported pol delta activity. Interestingly, RPA containing p70 with a zinc-finger domain deletion retained its DNA binding activity, but inhibited pol alpha and delta activity. RPA that lacked ssDNA binding activity failed to support simian virus 40 (SV40) DNA replication in vitro, whereas mutant RPA that lacked pol alpha stimulatory activity (including the zinc-finger p70 mutant) functioned normally. We conclude that RPA's DNA binding activity, but not its pol alpha stimulatory activity, is required for DNA replication.

Evidence that replication of human neurotropic JC virus DNA in glial cells is regulated by the sequence-specific single-stranded DNA-binding protein Pur alpha

Initiation of polyomavirus DNA replication in eukaryotic cells requires the participation of the viral early protein T antigen, cellular replication factors, and DNA polymerases. The human polyomavirus JC virus (JCV) is the etiologic agent of the fatal demyelinating disease progressive multifocal leukoencephalopathy in immunocompromised individuals. This virus exhibits a narrow host range and a tissue specificity that restricts its replication to glial cells of the central nervous system. Restriction of viral DNA replication due to species specificity of the DNA polymerase, coupled with glial cell-specific transcription of the viral early promoter, is thought to account for the brain-specific replication of JCV. In this report we demonstrate that overexpression of Pur alpha, a protein which binds to single-stranded DNA in a sequence-specific manner, suppresses replication of JCV DNA in glial cells. Results from footprinting studies indicate that Pur alpha and T antigen share a common binding region spanning the single-stranded ori sequence of JCV. Further, T antigen was capable of stimulating the association of Pur alpha with the ori sequence in a band shift assay. Whereas no evidence for simultaneous binding of Pur alpha and T antigen to single-stranded DNA has been observed, results from coimmunoprecipitation and Western blot (immunoblot) analyses of proteins derived from cells producing JCV T antigen indicate a molecular association of JCV T antigen and Pur alpha. The binding of Pur alpha to the single-stranded ori sequence and its association with T antigen suggest that Pur alpha interferes with the activity of T antigen and/or other regulatory proteins to exert its negative effect on JCV DNA replication. The importance of these findings in the reactivation of JCV in the latently infected individual under immunosuppressed conditions is discussed.

Proteolytic mapping of human replication protein A: evidence for multiple structural domains and a conformational change upon interaction with single-stranded DNA

Replication protein A (RPA) is multisubunit single-stranded DNA-binding protein required for multiple processes in DNA metabolism including DNA replication, DNA repair, and recombination. Human RPA is a stable complex of three subunits of 70, 32, and 14 kDa (RPA70, RPA32, and RPA14, respectively). We examined the structure of both wild-type and mutant forms of human RPA by mapping sites sensitive to proteolytic cleavage. For all three subunits, only a subset of the possible protease cleavage sites was sensitive to digestion. RPA70 was cleaved into multiple fragments of defined lengths. RPA32 was cleaved rapidly to a approximately 28-kDa polypeptide containing the C-terminus that was partially resistant to further digestion. RPA14 was refractory to digestion under the conditions used in these studies. The digestion properties of a complex of RPA32 and RPA14 were similar to those of the native heterotrimeric RPA complex, indicating that the structure of these subunits is similar in both complexes. Epitopes recognized by monoclonal antibodies to RPA70 were mapped, and this information was used to determine the position of individual cleavage events. These studies suggest that RPA70 is composed of at least two structural domains: an approximately 18-kDa N-terminal domain and a approximately 52-kDa C-terminal domain. The N-terminus of RPA70 was not required for single-stranded DNA-binding activity. Multiple changes in the digestion pattern were observed when RPA bound single-stranded DNA: degradation of the approximately 52-kDa domain of RPA70 was inhibited while proteolysis of RPA32 was stimulated. These data indicate that RPA undergoes a conformational change upon binding to single-stranded DNA.

Regulation of the cell cycle following DNA damage in normal and Ataxia telangiectasia cells

A proportion of the population is exposed to acute doses of ionizing radiation through medical treatment or occupational accidents, with little knowledge of the immediate effects. At the cellular level, ionizing radiation leads to the activation of a genetic program which enables the cell to increase its chances of survival and to minimize detrimental manifestations of radiation damage. Cytotoxic stress due to ionizing radiation causes genetic instability, alterations in the cell cycle, apoptosis, or necrosis. Alterations in the G1, S and G2 phases of the cell cycle coincide with improved survival and genome stability. The main cellular factors which are activated by DNA damage and interfere with the cell cycle controls are: p53, delaying the transition through the G1-S boundary; p21WAF1/CIP1, preventing the entrance into S-phase; proliferating cell nuclear antigen (PCNA) and replication protein A (RPA), blocking DNA replication; and the p53 variant protein p53 as together with the retinoblastoma protein (Rb), with less defined functions during the G2 phase of the cell cycle. By comparing a variety of radioresistant cell lines derived from radiosensitive ataxia telangiectasia cells with the parental cells, some essential mechanisms that allow cells to gain radioresistance have been identified. The results so far emphasise the importance of an adequate delay in the transition from G2 to M and the inhibition of DNA replication in the regulation of the cell cycle after exposure to ionizing radiation.

Ionizing radiation-induced phosphorylation of RPA p34 is deficient in ataxia telangiectasia and reduced in aged normal fibroblasts

Replication protein A (RPA, also called human single stranded DNA binding protein, hSSB) is a trimeric, multifunctional protein complex involved in DNA replication, DNA repair and recombination. Phosphorylation of RPA p34 subunit is observed after exposure of cells to radiation and other DNA damaging agents, which implicates the protein not only in repair but also in the regulation of replication on damaged DNA template. Here, we show that the phosphorylation observed in RPA p34 after exposure to ionizing radiation, X- or gamma-rays, is reduced and occurs later in primary fibroblasts from patients suffering from ataxia telangiectasia (AT), as compared to normal fibroblasts. We also show that in primary normal human fibroblasts, radiation-induced phosphorylation of RPA p34 is 'age'-dependent and decreases significantly as cultures senesce. Radiation-induced phosphorylation of RPA p34 is nearly absent in non-cycling cells, while the expression of p21cipl/wafl/sdil remains inducible. The results demonstrate a growth-state and culture-age dependency in radiation-induced RPA p34 phosphorylation, and suggest the operation of a signal transduction pathway that is inactivated in senescing or quiescent fibroblasts and defective in AT cells.

Expression, purification, and characterization of DNA polymerases involved in papovavirus replication

In recent years, work from a large number of laboratories has greatly expanded our knowledge of the biochemical characteristics and the genetic structure of the DNA polymerases used during papovavirus DNA replication. The development of in vitro DNA replication systems for both SV40 and polyoma virus has been paramount in facilitating the development of the current models describing how DNA polymerase alpha and delta function to replicate the genomes of these two viruses. Our studies have demonstrated that the proteins recognized to be essential for both in vitro SV40 and polyoma viral origin-dependent DNA synthesis can be isolated from cells as an intact complex. We have shown that the human cell MRC closely resembles the murine cell MRC, in both its protein composition and its fractionation and chromatographic profile. In addition, our data regarding both the human and the murine MRC support the dipolymerase model proposed from in vitro DNA replication studies using reconstituted assay systems. In addition, analysis of the nucleotide sequence of the genes encoding DNA polymerase alpha and delta has revealed that the amino acids encoded by several regions of these two genes have been rigorously maintained across evolutionary lines. This information has permitted the identification of protein domains which mediate the complex series of protein-protein interactions that direct the DNA polymerases to the cell nucleus, specify complete or partial exonuclease active sites, and participate in the interaction of each DNA polymerase with the DNA template. Expression studies examining each of the genes encoding DNA polymerase alpha and delta clearly indicate that both DNA polymerases are cell cycle regulated and undergo a dramatic induction in their expression when quiescent cells are stimulated to enter the cell cycle. This is in contrast to the two- to three-fold upregulation in the level of expression of these two genes when cycling cells cross the G1/S boundary. In addition, both proteins are phosphorylated in a cell cycle-dependent manner, and phosphorylation appears to be mediated through the action of a cdc2-dependent protein kinase. Despite all of this new information, much remains to be learned about how papovavirus DNA replication is regulated and how these two DNA polymerases act in vivo to faithfully copy the viral genomes. Studies have yet to be performed which identify all of the cellular factors which potentially mediate papovavirus DNA replication. The reconstituted replication systems have yielded a minimum number of proteins which are required to replicate SV40 and polyoma viral genomes in vitro. However, further studies are needed to identify additional factors which may participate in each step of the initiation, elongation, and termination phases of viral genome replication. As an example, models describing the potential role of cellular helicases, which are components of the MRC isolated from murine and human cells, have yet to be described. It is also conceivable that there are a number of other proteins which serve to attach the MRC to the nuclear matrix, stimulate viral DNA replication, and potentially regulate various aspects of the activity of the MRC throughout viral DNA replication. We are currently working toward characterizing the biochemical composition of the MRC from both murine and human cells. Our goals are to identify all of the structural components of the MRC and to define the role of these components in regulating papovavirus and cellular DNA replication. We have also begun studies to visualize the spatial organization of these protein components within the MRC, examine the regulatory processes controlling the activity of the various components of the MRC, and then develop this information into a coherent picture of the higher order structure of the MRC within the cell nucleus. We believe that this information will enable us to develop an accurate view of the detailed processes mediating both pa

Human xeroderma pigmentosum group A protein interacts with human replication protein A and inhibits DNA replication

Human replication protein A (RPA; also known as human single-stranded DNA binding protein, or HSSB) is a multisubunit complex involved in both DNA replication and repair. While the role of RPA in replication has been well studied, its function in repair is less clear, although it is known to be involved in the early stages of the repair process. We found that RPA interacts with xeroderma pigmentosum group A complementing protein (XPAC), a protein that specifically recognizes UV-damaged DNA. We examined the effect of this XPAC-RPA interaction on in vitro simian virus 40 (SV40) DNA replication catalyzed by the monopolymerase system. XPAC inhibited SV40 DNA replication in vitro, and this inhibition was reversed by the addition of RPA but not by the addition of DNA polymerase alpha-primase complex, SV40 large tumor antigen, or topoisomerase I. This inhibition did not result from an interaction between XPAC and single-stranded DNA (ssDNA), or from competition between RPA and XPAC for DNA binding, because XPAC does not show any ssDNA binding activity and, in fact, stimulates RPA's ssDNA binding activity. Furthermore, XPAC inhibited DNA polymerase alpha activity in the presence of RPA but not in RPA's absence. These results suggest that the inhibitory effect of XPAC on DNA replication probably occurs through its interaction with RPA.

Further characterization of the human cell multiprotein DNA replication complex

Evidence for multiprotein complexes playing a role in DNA replication has been growing over the years. We have previously reported on a replication-competent multiprotein form of DNA polymerase isolated from human (HeLa) cell extracts. The proteins that were found at that time to co-purify with the human cell multiprotein form of DNA polymerase included: DNA polymerase alpha, DNA primase, topoisomerase I, RNase H, PCNA, and a DNA-dependent ATPase. The multiprotein form of the human cell DNA polymerase was further purified by Q-Sepharose chromatography followed by glycerol gradient sedimentation and was shown to be fully competent to support origin-specific and large T-antigen dependent simian virus 40 (SV40) DNA replication in vitro [Malkas et al. (1990b): Biochemistry 29:6362-6374]. In this report we describe the further characterization of the human cell replication-competent multiprotein form of DNA polymerase designated MRC. Several additional DNA replication proteins that co-purify with the MRC have been identified. These proteins include: DNA polymerase delta, RF-C, topoisomerase II, DNA ligase I, DNA helicase, and RP-A. The replication requirements, replication initiation kinetics, and the ability of the MRC to utilize minichromosome structures for DNA synthesis have been determined. We also report on the results of experiments to determine whether nucleotide metabolism enzymes co-purify with the human cell MRC. We recently proposed a model to represent the MRC that was isolated from murine cells [Wu et al. (1994): J Cell Biochem 54:32-46]. We can now extend this model to include the human cell MRC based on the fractionation, chromatographic and sedimentation behavior of the human cell DNA replication proteins. A full description of the model is discussed. Our experimental results provide further evidence to suggest that DNA synthesis is mediated by a multiprotein complex in mammalian cells.

The role of the 34-kDa subunit of human replication protein A in simian virus 40 DNA replication in vitro

Human replication protein A (RPA) is a three subunit protein complex involved in DNA replication, repair, and recombination. We investigated the role of the 34-kDa subunit (p34) of RPA in DNA replication by generating a series of p34 mutants. While deletion of the N-terminal domain of p34 prevented its phosphorylation by both cyclin-dependent kinase (Cdk) and DNA-dependent kinase, a double point mutant that lacks the major phosphorylation sites for Cdk could be phosphorylated by DNA-dependent kinase. In simian virus 40 (SV40) DNA replication, RPA containing either of these mutants functioned as efficiently as wild-type RPA. However, mutant RPA containing C-terminally deleted p34 was only marginally active. This indicates that the C-terminal region, but not the phosphorylation domain of p34, is necessary for RPA function in DNA replication. Furthermore, RPA containing the C-terminally deleted p34 mutant could stimulate DNA polymerase alpha, and bind to single-stranded DNAs but was limited in its ability to unwind DNA or interact with SV40 large T antigen (T Ag). These results suggest that RPA p34 interacts with SV40 T Ag during the initiation of SV40 DNA replication and may be necessary for DNA unwinding.

Identification of the yeast MCM3-related protein as a component of Xenopus DNA replication licensing factor

Replication licensing factor is thought to be involved in the strict control of the initiation of DNA replication in eukaryotes. We identified a 100 kDa protein as a candidate for the licensing factor in Xenopus egg extracts. This protein was required for replication; it bound to sperm DNA before the formation of nuclei and apparently dissociated from the nuclear DNA during the progression of replication without being transported into the nuclei. An immunologically homologous protein in HeLa cells behaved similarly to the Xenopus protein during the cell cycle. Cloning and sequencing of the cDNAs encoding the Xenopus and human proteins revealed that they are homologs of yeast Mcm3, a putative yeast DNA replication licensing factor.

Nucleotide excision repair DNA synthesis by DNA polymerase epsilon in the presence of PCNA, RFC, and RPA

In eukaryotes, nucleotide excision repair of DNA is a complex process that requires many polypeptides to perform dual incision and remove a segment of about 30 nucleotides containing the damage, followed by repair DNA synthesis to replace the excised segment. Nucleotide excision repair DNA synthesis is dependent on proliferating cell nuclear antigen (PCNA). To study gap-filling DNA synthesis during DNA nucleotide excision repair, UV-damaged DNA was first incubated with PCNA-depleted human cell extracts to create repair incisions. Purified DNA polymerase delta or epsilon, with DNA ligase, was then used to form the repair patch. DNA polymerase delta could perform repair synthesis and was strictly dependent on the presence of both PCNA and replication factor C, but gave rise to a very low proportion of complete, ligated circles. The presence of replication protein A (which is also required for nucleotide excision repair) did not alter this result, while addition of DNase IV increased the fraction of ligated products. DNA polymerase epsilon, on the other hand, could fill the repair patch in the absence of PCNA and replication factor C, and most of the products were ligated circles. Addition of replication protein A changed the situation dramatically, and synthesis by polymerase epsilon became dependent on both PCNA and replication factor C. A combination of DNA polymerase epsilon, PCNA, replication factor C, replication protein A, and DNA ligase I appears to be well-suited to the task of creating nucleotide excision repair patches.

RPA involvement in the damage-recognition and incision steps of nucleotide excision repair

Human replication protein (RPA) functions in DNA replication, homologous recombination and nucleotide excision repair. This multisubunit single-stranded DNA-binding protein may be required to make unique protein-protein contacts because heterologous single-stranded binding proteins cannot substitute for RPA in these diverse DNA transactions. We report here that, by using affinity chromatography and immunoprecipitation, we found that human RPA bound specifically and directly to two excision repair proteins, the xeroderma pigmentosum damage-recognition protein XPA (refs 8, 9) and the endonuclease XPG (refs 10-13). Although it had been suggested that RPA might function before the DNA synthesis repair stage, our finding that a complex of RPA and XPA showed a striking cooperativity in binding to DNA lesions indicates that RPA may function at the very earliest stage of excision repair. In addition, by binding XPG, RPA may target this endonuclease to damaged DNA.

Bovine papillomavirus E1 protein binds specifically DNA polymerase alpha but not replication protein A

Extracts prepared from either mouse cells or monkey cells were examined for the ability to support in vitro bovine papillomavirus type 1 (BPV1) DNA replication, and they were used in parallel as a source of host replication proteins for affinity chromatography. DNA synthesis exhibited an absolute requirement for BPV1 E1 protein. In contrast to previous observations, we found that low levels of E1 were highly efficient in initiating DNA replication in the absence of the BPV1 transcription factor E2. Surprisingly, COS-1 cell extract allowed a high rate of BPV1 DNA replication, supporting an efficient production of mature circular DNA molecules, whereas in mouse cell extracts, the replication products mostly consisted of replicative intermediates. Submitting the extracts to affinity chromatography allowed specific binding of DNA polymerase alpha-primase to E1 protein, up to a total depletion of the extract, regardless of the origin of the cell extract. Furthermore, replication protein A was not retained on E1 affinity columns, even when E2 was complexed with E1. These data confirm that the interactions between E1 and DNA polymerase alpha-primase do not exhibit cell-type specificity, as had already been suggested by data from in vivo and in vitro replication assays, but they imply that other cellular proteins may affect the level of E1-dependent replication.

Structural analysis of human replication protein A. Mapping functional domains of the 70-kDa subunit

Replication protein A (RPA) is a heterotrimeric single-stranded DNA-binding protein that is essential for DNA metabolism. Human RPA is composed of subunits of 70, 32, and 14 kDa with intrinsic DNA-binding activity localized to the 616-amino acid, 70-kDa subunit (RPA70). We have made a series of C-terminal deletions to map the functional domains of RPA70. Deletion of the C terminus resulted in polypeptides that were significantly more soluble than RPA70 but were unable to form stable complexes with the other two subunits of RPA. These data suggest that the C-terminal region of RPA70 may be important for complex formation. The DNA-binding domain was localized to a region of RPA70 between residues 1 and 441. A mutant containing residues 1-441 bound oligonucleotides with an intrinsic affinity close to wild-type RPA complex. This mutant also appeared to bind with reduced cooperativity. We conclude that the C terminus of RPA70 and the 32- and 14-kDa subunits are not involved directly with interactions with DNA but may have a role in cooperativity of RPA binding. RPA70 deletion mutants were not able to support DNA replication even in the presence of a complex of the 32- and 14-kDa subunits, suggesting that the heterotrimeric complex is essential for DNA replication. The putative zinc finger in the C terminus of RPA70 is not required for single-stranded DNA-binding activity.

DNA repair protein XPA binds replication protein A (RPA)

XPA is a zinc finger DNA-binding protein, which is missing or altered in group A xeroderma pigmentosum cells and known to be involved in the damage-recognition step of the nucleotide excision repair (NER) processes. Using the yeast two-hybrid system to search for proteins that interact with XPA, we obtained the 34-kDa subunit of replication protein A (RPA, also known as HSSB and RFA). RPA is a stable complex of three polypeptides of 70, 34, 11 kDa and has been shown to be essential in the early steps of NER as well as in replication and recombination. We also demonstrate here that the RPA complex associates with XPA. These results suggest that RPA may cooperate with XPA in the early steps of the NER processes.

Changes in the subcellular localization of replication initiation proteins and cell cycle proteins during G1- to S-phase transition in mammalian cells

DNA replication in eukaryotic cells is restricted to the S-phase of the cell cycle. In a cell-free replication model system, using SV40 origin-containing DNA, extracts from G1 cells are inefficient in supporting DNA replication. We have undertaken a detailed analysis of the subcellular localization of replication proteins and cell cycle regulators to determine when these proteins are present in the nucleus and therefore available for DNA replication. Cyclin A and cdk2 have been implicated in regulating DNA replication, and may be responsible for activating components of the DNA replication initiation complex on entry into S-phase. G1 cell extracts used for in vitro replication contain the replication proteins RPA (the eukaryotic single-stranded DNA binding protein) and DNA polymerase alpha as well as cdk2, but lack cyclin A. On localizing these components in G1 cells we find that both RPA and DNA polymerase alpha are present as nuclear proteins, while cdk2 is primarily cytoplasmic and there is no detectable cyclin A. An apparent change in the distribution of these proteins occurs as the cell enters S-phase. Cyclin A becomes abundant and both cyclin A and cdk2 become localized to the nucleus in S-phase. In contrast, the RPA-34 and RPA-70 subunits of RPA, which are already nuclear, undergo a transition from the uniform nuclear distribution observed during G1, and now display a distinct punctate nuclear pattern. The initiation of DNA replication therefore most likely occurs by modification and activation of these replication initiation proteins rather than by their recruitment to the nuclear compartment.

Interactions of human replication protein A with oligonucleotides

Replication protein A (RPA) is a heterotrimeric, single-stranded DNA binding protein that is essential for eukaryotic DNA replication. In order to gain a better understanding of the interactions between RPA and DNA, we have examined the interactions of human RPA with single-stranded oligonucleotides. Our analysis of RPA.DNA complexes demonstrated that RPA binds as a heterotrimer. Stoichiometric binding reactions monitored by fluorescence quenching indicated that the binding site size of human RPA is 30 nucleotides and that between 20-30 nucleotides of DNA directly interact with RPA. The binding of RPA to DNA of different lengths was systematically examined using deoxythymidine-containing oligonucleotides. We found that the binding affinity of RPA for short oligonucleotides was length dependent. The apparent association constant of RPA varied over 200-fold from approximately 7 x 10(7) M-1 for oligo(dT)10 to approximately 1.5 x 10(10) M-1 for oligo(dT)50. Human RPA binds to oligonucleotides with low cooperativity; the cooperativity parameter (omega) for RPA binding was estimated to be approximately 15.

Purification and characterisation of dRP-A: a single-stranded DNA binding protein from Drosophila melanogaster

Replication protein A (RP-A) is an essential single-stranded DNA binding protein (SSB) involved in the initiation and elongation phases of eukaryotic DNA replication. It has the ability to bind single-stranded DNA extremely tightly and possesses a characteristic hetero-trimeric structure. Here we present a method for the purification of RP-A from Drosophila melanogaster embryos. Drosophila RP-A (dRP-A) has subunits of about 66, 31 and 8 kDa, in line with analogues from other species. It binds single-stranded DNA very tightly via the large subunit. The complete protein has at least a 10- to 20-fold preference for single-stranded DNA over double-stranded DNA and it appears that binding is only weakly co-operative. Band shift experiments suggest that it has an approximate site covering the size of 16 nucleotides or less, however, it shows a greater affinity for long oligonucleotides than for short ones. We also demonstrate that dRP-A can stimulate the activity of its homologous DNA polymerase alpha in excess of 20 fold. Analysis of the protein's abundance during embryo development indicates that it varies in a manner akin to other replication proteins.

In vitro replication of adeno-associated virus DNA

The study of eukaryotic viral DNA replication in vitro has led to the identification of cellular enzymes involved in DNA replication. Adeno-associated virus (AAV) is distinct from previously reported systems in that it is believed to replicate entirely by leading-strand DNA synthesis and requires coinfection with adenovirus to establish completely permissive replication. In previous work, we demonstrated that two of the AAV nonstructural proteins, Rep78 and -68, are site-specific endonucleases and DNA helicases that are capable of resolving covalently closed AAV termini, a key step in AAV DNA replication. We have now cloned the AAV nonstructural proteins Rep78, Rep68, and Rep52 in the baculovirus expression system. Using the baculovirus-expressed proteins, we have developed an efficient in vitro AAV DNA replication system which mimics the in vivo behavior of AAV in every respect. With no-end AAV DNA as the starting substrate, the reaction required an adenovirus-infected cell extract and the presence of either Rep78 or Rep68. Rep52, as expected, did not support DNA replication. A mutant in the AAV terminal resolution site (trs) was defective for DNA replication in the in vitro assay. Little, if any, product was formed in the absence of the adenovirus-infected HeLa cell extract. In general, uninfected HeLa extracts were less efficient in supporting AAV DNA replication than adenovirus-infected extracts. Thus, the requirement for adenovirus infection in vivo was partially duplicated in vitro. The reduced ability of uninfected HeLa extracts to support complete DNA replication was not due to a defect in terminal resolution but rather to a defect in the reinitiation reaction or in elongation. Rep78 produced a characteristic monomer-dimer pattern of replicative intermediates, but surprisingly, Rep68 produced little, if any, dimer replicative form. The reaction had a significant lag (30 min) before incorporation of 32P-deoxynucleoside triphosphate could be detected in DpnI-resistant monomer replicative form and was linear for at least 4 h after the lag. The rate of incorporation in the reaction was comparable to that in the simian virus 40 in vitro system. Replication of the complete AAV DNA molecule was demonstrated by the following criteria. (i) Most of the monomer and dimer product DNAs were completely resistant to digestion with DpnI. (ii) Virtually all of the starting substrate was converted to heavy-light or heavy-heavy product DNA in the presence of bromo-dUTP when examined on CsCl density gradients.(ABSTRACT TRUNCATED AT 400 WORDS)

Isolation of the genes encoding the 51-kilodalton and 28-kilodalton subunits of Crithidia fasciculata replication protein A

The genes encoding the 51-kilodalton subunit (p51) and the 28-kilodalton subunit (p28) of replication protein A (RP-A), designated CfaRPA1 and CfaRPA2 respectively, were cloned from the trypanosomatid Crithidia fasciculata by screening a genomic DNA library in the expression vector lambda gt11 with antibodies raised against purified C. fasciculata RP-A. CfaRPA1 has a single open reading frame encoding a polypeptide of 467 amino acids and a molecular mass of 52.0 kDa. The predicted p51 polypeptide has sequence similarity to the corresponding subunits from human, Xenopus laevis, and Saccharomyces cerevisiae, but is lacking a segment of approximately 20 kDa from its amino terminus, accounting for its smaller molecular weight when compared to the large subunits of RP-A from these other organisms. CfaRPA1 contains a zinc-finger motif that is also found in the RP-A large subunits from human, frog, and yeast. CfaRPA2 contains a single large open reading frame encoding a polypeptide of 258 amino acids and a molecular mass of 27.5 kDa. The predicted polypeptide has significant sequence similarity to the middle subunit of RP-A from human cells, mouse cells, and the budding yeast S. cerevisiae. Northern hybridization analysis of polyadenylated RNA from C. fasciculata indicates that both cloned genes are expressed as polyadenylated transcripts. CfaRPA1 hybridized with a 2.30-kb transcript and CfaRPA2 hybridized with a 1.44-kb transcript.

Further purification and characterization of a multienzyme complex for DNA synthesis in human cells

The 21 S complex of enzymes for DNA synthesis in the combined low salt nuclear extract-post microsomal supernatant from HeLa cells [Malkas et al. (1990) Biochemistry 29:6362-6374] was purified by poly (ethylene glycol) precipitation, Q-Sepharose chromatography, Mono Q Fast Protein Liquid Chromatography (FPLC), and velocity gradient centrifugation. The procedure gives purified enzyme complex at a yield of 45%. The 21 S enzyme complex remains intact and functional in the replication of simian virus 40 DNA throughout the purification. Sedimentation analysis showed that the 21 S enzyme complex exists in the crude HeLa cell extract and that simian virus 40 in vitro DNA replication activity in the cell extract resides exclusively with the 21 S complex. The results of enzyme and immunological analysis indicate that DNA polymerase alpha-primase, a 3',5' exonuclease, DNA ligase I, RNase H, and topoisomerase I are associated with the purified enzyme complex. Denaturing polyacrylamide gel electrophoresis of the purified enzyme complex showed the presence of about 30 polypeptides in the size range of 300 to 15 kDa. Immunofluorescent imaging analysis, with antibodies to DNA polymerase alpha,beta and DNA ligase I, showed that polymerase alpha and DNA ligase I are localized to granular-like foci within the nucleus during S-phase. In contrast, DNA polymerase beta, which is not associated with the 21 S complex, is diffusely distributed throughout the nucleoplasm.

Distinct roles of cdk2 and cdc2 in RP-A phosphorylation during the cell cycle

RP-A is a single-stranded DNA-binding protein, which has been shown to be required for DNA replication using an SV40 model system. The protein has also been shown to be phosphorylated at the G1-S phase transition. Using Xenopus cell-free extracts we have investigated the role of RP-A in nuclear replication and characterized the kinases and conditions that lead to phosphorylation of RP-A during the cell cycle. By immunodepleting RP-A from Xenopus extracts we have shown that RP-A is essential for replication of chromosomal DNA. Our results show that, during S phase, only that RP-A which is associated with nuclei is phosphorylated. Furthermore our results indicate that during S phase RP-A is only phosphorylated when associated with single-stranded DNA. By immunodepleting cdk2 kinase we show that cdk2 kinase is required for the observed phosphorylation of RP-A in nuclei during S phase. However, using purified cdk2 kinase and RP-A we are unable to detect a direct phosphorylation of RP-A by cdk2 kinase. This observation suggests that phosphorylation of DNA-bound RP-A at S phase is carried out by a kinase distinct from cdk2. Consistent with this we find that when single-stranded DNA is added to S phase extracts depleted of cdk2 kinase, RP-A is phosphorylated. Together these results suggest that cdk2 kinase participates in the activation of DNA replication at a stage prior to the binding of RP-A to the initiation complex. In addition to RP-A phosphorylation in S phase, we have also found that at the onset of mitosis RP-A is quantitatively phosphorylated and that phosphorylation is directly mediated by cdc2 kinase. However, at this time during the cell cycle, cdc2-dependent phosphorylation of RP-A is independent of DNA binding. These observations further demonstrate the distinctions between cdk2 and cdc2 kinases.

Inhibition of DNA replication factor RPA by p53

The tumour suppressor p53 specifically interferes with the onset of S phase. The mechanism of the growth suppression action of the protein is unclear, though recent evidence points to transcriptional activation and repression functions of the protein. A competing hypothesis suggests that p53 interacts with the DNA replication apparatus and directly interferes with DNA replication. The major evidence for this hypothesis is that p53 interacts with the simian virus 40 (SV40)-encoded protein T antigen and interferes with the ability of T antigen to unwind the SV40 origin of DNA replication, and recruit DNA polymerase alpha to the replication initiation complex. Here we report that p53 physically interacts with and inhibits the function of a cellular DNA replication factor, the single-stranded DNA-binding protein complex RPA.

Characterization of Ustilago maydis DNA binding protein one (UBP1)

The DNA binding properties of a protein from the lower eukaryote Ustilago maydis have been characterized. Using both filter binding and gel retention assays, we demonstrate that this protein, termed UBP1 (Ustilago binding protein one), binds preferentially to DNA molecules lacking chain interruptions. The introduction of DNA breaks by a restriction enzyme or a purified nuclease, from Ustilago maydis, causes the dissociation of protein-DNA complexes. UBP1 stimulates the relaxation of negatively supercoiled DNA, mediated by Ustilago type I topoisomerase, through a mechanism most likely involving the association of UBP1 with the DNA rather than with the topoisomerase. The prebinding of UBP1 to DNA templates, subsequently assembled into minichromosomes, results in the development of a disorganized nucleosomal array. Possible roles for UBP1 in processes that involve changes in DNA topology, such as chromatin assembly, are discussed.

The acidic transcriptional activation domains of VP16 and p53 bind the cellular replication protein A and stimulate in vitro BPV-1 DNA replication

For papillomavirus DNA replication, the E2 enhancer protein cooperatively assists in binding of the E1 helicase to the origin. We report that, at limiting E1 and E2 levels, the enhancer proteins GAL4-VP16 and GAL4-p53(1-73) stimulate BPV in vitro DNA replication. This cell-free system was used to ascertain whether the acidic activation domains have a cellular target important for replication. Cellular extracts were depleted of replication activity by passage through a VP16 affinity column. The protein depleted was the cellular factor replication protein A. The direct interaction between replication protein A and VP16, as well as the activation of replication by VP16, is dependent upon the C-terminus of the VP16 activation domain. E2 and the activation domain of p53 also interact with replication protein A. We suggest that a link between transcription and replication involves factors that help convert a closed DNA complex to an open complex.

A single-stranded DNA binding protein from Drosophila melanogaster: characterization of the heterotrimeric protein and its interaction with single-stranded DNA

We describe the purification to near homogeneity of a single-stranded DNA binding protein from 0-18-h embryos of Drosophila melanogaster. Drosophila SSB (D-SSB) is a heterotrimer with subunits of molecular weight of 70,000, 30,000, and 8000. It has a Stokes radius of 48.6 +/- 2 A and s20,w = 5.0 +/- 0.2 S. The interaction of D-SSB with ssDNA was examined by the quenching of intrinsic protein fluorescence. The binding site size was determined to be n = 22 +/- 4 nucleotides with a maximum quenching Qm = 35 +/- 3%. Equilibrium titrations indicate that D-SSB binds with low cooperativity, omega = 10-300, and high apparent affinity, K omega = (0.7-5) x 10(7) M-1, at 225 mM NaCl. Sedimentation of D-SSB bound to small oligonucleotides demonstrates that D-SSB does not require protein association for binding. D-SSB stimulates the extent and processivity of DNA synthesis of its cognate DNA polymerase alpha. On the basis of these properties, we conclude that D-SSB is the Drosophila cognate of the human and yeast SSB/RP-A proteins.

Cloning and sequencing of the Serratia marcescens gene encoding a single-stranded DNA-binding protein (SSB) and its promoter region

The gene (ssb) coding for a single-stranded DNA-binding protein (SSB) was identified on a 1.2-kb EcoRI-SalI fragment cloned from chromosomal DNA of Serratia marcescens. The cloned fragment conferred increased resistance against UV and mitomycin C (MC) to ssb- mutants of Escherichia coli. The nucleotide (nt) sequence revealed that SSB consists of 175 amino acids (aa) and has an M(r) of 18,677. It shows 89% aa sequence homology with the SSB of E. coli. The nt sequence preceding the gene contains three promoters. Two of them overlap with a presumptive SOS box, and the distal one overlaps with a second SOS box that coincides with the promoter of the adjacent uvrA (gene encoding the UvrA protein). The uvrA is transcribed in a direction opposite to that of ssb. The sequence coding for the N terminus of the UvrA of S. marcescens indicates that the first 74 aa are identical to those of the E. coli protein. The results suggest that the two bacterial SSBs are members of a group which differs from the known SSBs of prokaryotic transmissible plasmids, because their aa sequence homology with these proteins is only about 60%.

Single-stranded DNA binding protein from calf thymus. Purification, properties, and stimulation of the homologous DNA-polymerase-alpha-primase complex

A binding protein for single-stranded DNA (ssDNA) was purified from calf thymus to near homogeneity by chromatography on DEAE-cellulose, blue-Sepharose, ssDNA-cellulose and FPLC Mono Q. The most purified fraction consisted of four polypeptides with molecular masses of 70, 55, 30, and 11 kDa. The polypeptide with the molecular mass of 55 kDa is most likely a degraded form of the largest polypeptide. The complex migrated as a whole on both glycerol gradient ultracentrifugation (s = 5.1 S) and gel filtration (Stokes' radius approximately 5.1 nm). Combining these data indicates a native molecular mass of about 110 kDa, which is in accord with a 1:1:1 stoichiometry for the 70 + 55/30/11-kDa complex. The ssDNA binding protein (SSB) covered approximately 20-25 nucleotides on M13mp8 ssDNA, as revealed from both band shift experiments and DNase I digestion studies. The homologous DNA-polymerase-alpha-primase complex was stimulated by the ssDNA binding protein 1.2-fold on poly(dA).(dT)14 and 10-13-fold on singly primed M13mp8 DNA. Stimulation was mainly due to facilitated DNA synthesis through stable secondary structures, as demonstrated by the vanishing of many, but not all, pausing sites. Processivity of polymerase-primase was not affected on poly(dA).(dT)14; with poly(dT).(rA)10 an approximately twofold increase in product lengths was observed when SSB was present. The increase was attributed to a facilitated rebinding of polymerase alpha to an already finished DNA fragment rather than to an enhancement of the intrinsic processivity of the polymerase. Similarly, products 300-600 nucleotides long were formed on singly primed M13 DNA in the presence of SSB, in contrast to 20-120 nucleotides when SSB was absent. DNA-primase-initiated DNA replication on M13 DNA was inhibited by SSB in a concentration-dependent manner. However, with less sites available to begin with RNA priming, more homogeneous products were formed.

Recognition of model DNA replication forks by the SV40 large tumor antigen

The ability of the SV40 large tumor antigen (T antigen), a DNA helicase, to bind to model DNA replication forks was tested. DNA fork molecules were constructed either from two partially complementary oligonucleotides or from a single oligonucleotide able to form a 'panhandle' structure. T antigen specifically recognized the two-strand fork in a reaction dependent on the presence of ATP, dATP, or non-hydrolyzable analogs of ATP. T antigen asymmetrically bound the two-strand fork, protecting from nuclease cleavage a fork-proximal region on only one of the two strands. The asymmetric binding is consistent with the 3'-->5' directionality of the DNA helicase activity of T antigen. An analogous region on the one-strand fork was also bound by T antigen, suggesting that T antigen does not require a free single-stranded end to load onto the fork. Use of chemically modified DNA substrates indicated that T antigen binding to the fork utilized important contacts with the DNA sugar-phosphate backbone.

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.

A complex between replication factor A (SSB) and DNA helicase stimulates DNA synthesis of DNA polymerase alpha on double-stranded DNA

A helicase-like DNA unwinding activity was found in highly purified fractions of the calf thymus single-stranded DNA binding protein (ctSSB), also known as replication protein A (RP-A) or replication factor A (RF-A). This activity depended on the hydrolysis of ATP or dATP, and used CTP with a lower efficiency. ctSSB promoted the homologous DNA polymerase alpha to perform DNA synthesis on double-stranded templates containing replication fork-like structures. The rate and amount of DNA synthesis was found to be dependent on the concentration of ctSSB. At a 10-fold mass excess of ctSSB over double-stranded DNA, products of 200-600 nucleotides in length were obtained. This comprises or even exceeds the length of a eukaryotic Okazaki fragment. The ctSSB-associated DNA helicase activity is most likely a distinct protein rather than an inherent property of SSB, as inferred from titration experiments between SSB and DNA. The association of a helicase with SSB and the stimulatory action of this complex to the DNA polymerase alpha-catalyzed synthesis of double-stranded DNA suggests a cooperative function of the three enzymatic activities in the process of eukaryotic DNA replication.

Characterization of DNA-binding and strand-exchange stimulation properties of y-RPA, a yeast single-strand-DNA-binding protein

Single-stranded DNA binding proteins (SSBs) have been isolated from many organisms, including Escherichia coli, Saccharomyces cerevisiae and humans. Characterization of these proteins suggests they are required for DNA replication and are active in homologous recombination. As an initial step towards understanding the role of the eukaryotic SSBs in DNA replication and recombination, we examined the DNA binding and strand exchange stimulation properties of the S. cerevisiae single-strand binding protein y-RPA (yeast replication protein A). y-RPA was found to bind to single-stranded DNA (ssDNA) as a 115,000 M(r) heterotrimer containing 70,000, 36,000 and 14,000 M(r) subunits. It saturated ssDNA at a stoichiometry of one heterotrimer per 90 to 100 nucleotides and binding occurred with high affinity (K omega greater than 10(9) M-1) and co-operativity (omega = 10,000 to 100,000). Electron microscopic analysis revealed that y-RPA binding was highly co-operative and that the ssDNA present in y-RPA-ssDNA complexes was compacted fourfold, arranged into nucleosome-like structures, and was free of secondary structure. y-RPA was also tested for its ability to stimulate the yeast Sepl and E. coli RecA strand-exchange proteins. In an assay that measures the pairing of circular ssDNA with homologous linear duplex DNA, y-RPA stimulated the strand-exchange activity of Sepl approximately threefold and the activity of RecA protein to the same extent as did E. coli SSB. Maximal stimulation of Sepl occurred at a stoichiometry of one y-RPA heterotrimer per 95 nucleotides of ssDNA. y-RPA stimulated RecA and Sepl mediated strand exchange reactions in a manner similar to that observed for the stimulation of RecA by E. coli SSB; in both of these reactions, y-RPA inhibited the aggregation of ssDNA and promoted the co-aggregation of single-stranded and double-stranded linear DNA. These results demonstrate that the E. coli and yeast SSBs display similar DNA-binding properties and support a model in which y-RPA functions as an E. coli SSB-like protein in yeast.

DNA unwinding activity of replication protein A

Replication protein A (RP-A) is a heterotrimeric complex conserved in eukaryotic cells. It binds to single-stranded DNA and is essential for initiation and elongation of DNA replication. In this communication we give evidence that this protein can unwind DNA independent of magnesium and ATP, two essential cofactors for bona fide DNA helicase activity. RP-A can unwind up to at least 350 basepairs and appears to be required in stoichiometric amounts. The reaction is extremely sensitive to NaCl and MgCl2. This activity of RF-A is suggestive for a possible unwinding function in initiation of DNA replication in eukaryotes.

Strand-specific recognition of a synthetic DNA replication fork by the SV40 large tumor antigen

The mechanism by which DNA helicases unwind DNA was tested; an "unwinding complex" between the SV40 large tumor antigen (T antigen) and a DNA molecule designed to resemble a replication fork was probed. In an adenosine triphosphate (ATP)-dependent reaction, T antigen quantitatively recognized this synthetic replication fork and bound the DNA primarily as a hexamer. The T antigen bound only one of the two strands at the fork, an asymmetric interaction consistent with the 3'----5' directionality of the DNA helicase activity of T antigen. Binding to chemically modified DNA substrates indicated that the DNA helicase recognized the DNA primarily through the sugar-phosphate backbone. Ethylation of six top strand phosphates at the junction of single-stranded and double-stranded DNA inhibited the DNA helicase activity of T antigen. Neither a 3' single-stranded end on the DNA substrate nor ATP hydrolysis was required for T antigen to bind the replication fork. These data suggest that T antigen can directly bind the replication fork through recognition of a fork-specific structure.

HeLa cell single-stranded DNA-binding protein increases the accuracy of DNA synthesis by DNA polymerase alpha in vitro

To determine whether cellular replication factors can influence the fidelity of DNA replication, the effect of HeLa cell single-stranded DNA-binding protein (SSB) on the accuracy of DNA replication by HeLa cell DNA polymerase alpha has been examined. An in vitro gap-filling assay, in which the single-stranded gap contains the supF target gene, was used to measure mutagenesis. Addition of SSB to the in vitro DNA synthesis reaction increased the accuracy of DNA polymerase alpha by 2- to 8-fold. Analysis of the products of DNA synthesis indicated that SSB reduces pausing by the polymerase at specific sites in the single-stranded supF template. Sequence analysis of the types of errors resulting from synthesis in the absence or presence of SSB reveals that, while the errors are primarily base substitutions under both conditions, SSB reduces the number of errors found at 3 hotspots in the supF gene. Thus, a cellular replication factor (SSB) can influence the fidelity of a mammalian DNA polymerase in vitro, suggesting that the high accuracy of cellular DNA replication may be determined in part by the interaction between replication factors, DNA polymerase and the DNA template in the replication complex.