ATP utilization by yeast replication factor C. II. Multiple stepwise ATP binding events are required to load proliferating cell nuclear antigen onto primed DNA.

Binding of adenosine (3-thiotriphosphate) (ATPgammaS), a nonhydrolyzable analog of ATP, to replication factor C with a N-terminal truncation (Delta2-273) of the Rfc1 subunit (RFC) was studied by filter binding. RFC alone bound 1.8 ATPgammaS molecules. However, when either PCNA or primer-template DNA were also present 2.6 or 2.7 ATPgammaS molecules, respectively, were bound. When both PCNA and DNA were present 3.6 ATPgammaS molecules were bound per RFC. Order of addition experiments using surface plasmon resonance indicate that RFC forms an ATP-mediated binary complex with PCNA prior to formation of a ternary DNA.PCNA.RFC complex. An ATP-mediated complex between RFC and DNA was not competent for binding PCNA, and the RFC.DNA complex dissociated with hydrolysis of ATP. Based on these experiments a model is proposed in which: (i) RFC binds two ATPs (RFC.ATP(2)); (ii) this complex binds PCNA (PCNA.RFC.ATP(2)), which goes through a conformational change to reveal a binding site for one additional ATP (PCNA.RFC.ATP(3)); (iii) this complex can bind DNA to yield DNA.PCNA.RFC.ATP(3); (iv) a conformational change in the latter complex reveals a fourth binding site for ATP; and (v) the DNA.PCNA.RFC.ATP(4) complex is finally competent for completion of PCNA loading and release of RFC upon hydrolysis of ATP.     

Replication protein A-directed unloading of PCNA by the Ctf18 cohesion establishment complex

The replication clamp PCNA is loaded around DNA by replication factor C (RFC) and functions in DNA replication and repair. Regulated unloading of PCNA during the progression and termination of DNA replication may require additional factors. Here we show that a Saccharomyces cerevisiae complex required for the establishment of sister chromatid cohesion functions as an efficient unloader of PCNA. Unloading requires ATP hydrolysis. This seven-subunit Ctf18-RFC complex consists of the four small subunits of RFC, together with Ctf18, Dcc1, and Ctf8. Ctf18-RFC was also a weak loader of PCNA onto naked template-primer DNA. However, when the single-stranded DNA template was coated by the yeast single-stranded DNA binding protein replication protein A (RPA) but not by a mutant form of RPA or a heterologous single-stranded DNA binding protein, both binding of Ctf18-RFC to substrate DNA and loading of PCNA were strongly inhibited, and unloading predominated. Neither yeast RFC itself nor two other related clamp loaders, containing either Rad24 or Elg1, catalyzed significant unloading of PCNA. The Dcc1 and Ctf8 subunits of Ctf18-RFC, while required for establishing sister chromatid cohesion in vivo, did not function specifically in PCNA unloading in vitro, thereby separating the functionality of the Ctf18-RFC complex into two distinct paths.     

DNA damage-induced ubiquitylation of RFC2 subunit of replication factor C complex

Many proteins involved in DNA replication and repair undergo post-translational modifications such as phosphorylation and ubiquitylation. Proliferating cell nuclear antigen (PCNA; a homotrimeric protein that encircles double-stranded DNA to function as a sliding clamp for DNA polymerases) is monoubiquitylated by the RAD6-RAD18 complex and further polyubiquitylated by the RAD5-MMS2-UBC13 complex in response to various DNA-damaging agents. PCNA mono- and polyubiquitylation activate an error-prone translesion synthesis pathway and an error-free pathway of damage avoidance, respectively. Here we show that replication factor C (RFC; a heteropentameric protein complex that loads PCNA onto DNA) was also ubiquitylated in a RAD18-dependent manner in cells treated with alkylating agents or H(2)O(2). A mutant form of RFC2 with a D228A substitution (corresponding to a yeast Rfc4 mutation that reduces an interaction with replication protein A (RPA), a single-stranded DNA-binding protein) was heavily ubiquitylated in cells even in the absence of DNA damage. Furthermore RFC2 was ubiquitylated by the RAD6-RAD18 complex in vitro, and its modification was inhibited in the presence of RPA. The inhibitory effect of RPA on RFC2 ubiquitylation was relatively specific because RAD6-RAD18-mediated ubiquitylation of PCNA was RPA-insensitive. Our findings suggest that RPA plays a regulatory role in DNA damage responses via repression of RFC2 ubiquitylation in human cells.     

ATP binding and hydrolysis-driven rate-determining events in the RFC-catalyzed PCNA clamp loading reaction

The multi-subunit replication factor C (RFC) complex loads circular proliferating cell nuclear antigen (PCNA) clamps onto DNA where they serve as mobile tethers for polymerases and coordinate the functions of many other DNA metabolic proteins. The clamp loading reaction is complex, involving multiple components (RFC, PCNA, DNA, and ATP) and events (minimally: PCNA opening/closing, DNA binding/release, and ATP binding/hydrolysis) that yield a topologically linked clamp·DNA product in less than a second. Here, we report pre-steady-state measurements of several steps in the reaction catalyzed by Saccharomyces cerevisiae RFC and present a comprehensive kinetic model based on global analysis of the data. Highlights of the reaction mechanism are that ATP binding to RFC initiates slow activation of the clamp loader, enabling it to open PCNA (at ~2 s(-1)) and bind primer-template DNA (ptDNA). Rapid binding of ptDNA leads to formation of the RFC·ATP·PCNA(open)·ptDNA complex, which catalyzes a burst of ATP hydrolysis. Another slow step in the reaction follows ATP hydrolysis and is associated with PCNA closure around ptDNA (8 s(-1)). Dissociation of PCNA·ptDNA from RFC leads to catalytic turnover. We propose that these early and late rate-determining events are intramolecular conformational changes in RFC and PCNA that control clamp opening and closure, and that ATP binding and hydrolysis switch RFC between conformations with high and low affinities, respectively, for open PCNA and ptDNA, and thus bookend the clamp loading reaction.     

A central swivel point in the RFC clamp loader controls PCNA opening and loading on DNA

Replication factor C (RFC) is a five-subunit complex that loads proliferating cell nuclear antigen (PCNA) clamps onto primer-template DNA (ptDNA) during replication. RFC subunits belong to the AAA(+) superfamily, and their ATPase activity drives interactions between the clamp loader, the clamp, and the ptDNA, leading to topologically linked PCNA·ptDNA. We report the kinetics of transient events in Saccharomyces cerevisiae RFC-catalyzed PCNA loading, including ATP-induced RFC activation, PCNA opening, ptDNA binding, ATP hydrolysis, PCNA closing, and PCNA·ptDNA release. This detailed perspective enables assessment of individual RFC-A, RFC-B, RFC-C, RFC-D, and RFC-E subunit functions in the reaction mechanism. Functions have been ascribed to RFC subunits previously based on a steady-state analysis of 'arginine-finger' ATPase mutants; however, pre-steady-state analysis provides a different view. The central subunit RFC-C serves as a critical swivel point in the clamp loader. ATP binding to this subunit initiates RFC activation, and the clamp loader adopts a spiral conformation that stabilizes PCNA in a corresponding open spiral. The importance of RFC subunit response to ATP binding decreases as RFC-C>RFC-D>RFC-B, with RFC-A being unnecessary. RFC-C-dependent activation of RFC also enables ptDNA binding, leading to the formation of the RFC·ATP·PCNA(open)·ptDNA complex. Subsequent ATP hydrolysis leads to complex dissociation, with RFC-D activity contributing the most to rapid ptDNA release. The pivotal role of the RFC-B/C/D subunit ATPase core in clamp loading is consistent with the similar central location of all three ATPase active subunits of the Escherichia coli clamp loader.     

Identification of replication factor C from Saccharomyces cerevisiae: a component of the leading-strand DNA replication complex.

A number of proteins have been isolated from human cells on the basis of their ability to support DNA replication in vitro of the simian virus 40 (SV40) origin of DNA replication. One such protein, replication factor C (RFC), functions with the proliferating cell nuclear antigen (PCNA), replication protein A (RPA), and DNA polymerase delta to synthesize the leading strand at a replication fork. To determine whether these proteins perform similar roles during replication of DNA from origins in cellular chromosomes, we have begun to characterize functionally homologous proteins from the yeast Saccharomyces cerevisiae. RFC from S. cerevisiae was purified by its ability to stimulate yeast DNA polymerase delta on a primed single-stranded DNA template in the presence of yeast PCNA and RPA. Like its human-cell counterpart, RFC from S. cerevisiae (scRFC) has an associated DNA-activated ATPase activity as well as a primer-template, structure-specific DNA binding activity. By analogy with the phage T4 and SV40 DNA replication in vitro systems, the yeast RFC, PCNA, RPA, and DNA polymerase delta activities function together as a leading-strand DNA replication complex. Now that RFC from S. cerevisiae has been purified, all seven cellular factors previously shown to be required for SV40 DNA replication in vitro have been identified in S. cerevisiae.     

Replication factor C is a more effective proliferating cell nuclear antigen (PCNA) opener than the checkpoint clamp loader, Rad24-RFC

Clamp loaders from all domains of life load clamps onto DNA. The clamp tethers DNA polymerases to DNA to increase the processivity of synthesis as well as the efficiency of replication. Here, we investigated proliferating cell nuclear antigen (PCNA) binding and opening by the Saccharomyces cerevisiae clamp loader, replication factor C (RFC), and the DNA damage checkpoint clamp loader, Rad24-RFC, using two separate fluorescence intensity-based assays. Analysis of PCNA opening by RFC revealed a two-step reaction in which RFC binds PCNA before opening PCNA rather than capturing clamps that have transiently and spontaneously opened in solution. The affinity of RFC for PCNA is about an order of magnitude lower in the absence of ATP than in its presence. The affinity of Rad24-RFC for PCNA in the presence of ATP is about an order magnitude weaker than that of RFC for PCNA, similar to the RFC-PCNA interaction in the absence of ATP. Importantly, fewer open clamp loader-clamp complexes are formed when PCNA is bound by Rad24-RFC than when bound by RFC.     

Mismatch Repair proteins are recruited to replicating DNA through interaction with Proliferating Cell Nuclear Antigen (PCNA)

Mismatch Repair (MMR) is closely linked to DNA replication; however, other than the role of the replicative sliding clamp (PCNA) in various MMR functions, the linkage between DNA replication and MMR has been difficult to investigate. Here we use an in vitro DNA replication system based on simian virus 40, to investigate MMR recruitment to replicating DNA. Both DNA replication and MMR proteins are recruited to replicating DNA in an origin-dependent fashion. Primer synthesis is required for recruitment of both PCNA and MMR proteins, but not for recruitment of the single-stranded DNA-binding protein (RPA). Blocking PCNA recruitment to replicating DNA with a p21-based polypeptide blocks PCNA and MMR, but not RPA recruitment. Once PCNA and subsequent proteins required for replication are loaded onto DNA, addition of p21 leaves PCNA on the replicating DNA, but actively displaces MMR proteins. These findings indicate that the MMR machinery is recruited to replicating DNA through its interaction with PCNA, and suggests that this occurs via binding of the MMR proteins to the multi-protein interaction sites on PCNA. These studies demonstrate the utility of this system for further investigation of the role of DNA replication in MMR.     

Requirement for ATP by the DNA damage checkpoint clamp loader

The DNA damage clamp loader replication factor C (RFC-Rad24) consists of the Rad24 protein and the four small Rfc2-5 subunits of RFC. This complex loads the heterotrimeric DNA damage clamp consisting of Rad17, Mec3, and Ddc1 (Rad17/3/1) onto partial duplex DNA in an ATP-dependent manner. Interactions between the clamp loader and the clamp have been proposed to mirror those of the replication clamp loader RFC and the sliding clamp proliferating cell nuclear antigen (PCNA). In that system, three ATP molecules bound to the Rfc2, Rfc3, and Rfc4 subunits are necessary and sufficient for efficient loading of PCNA, whereas ATP binding to Rfc1 is not required. In contrast, in this study, we show that mutant RFC-Rad24 with a rad24-K115E mutation in the ATP-binding domain of Rad24 shows defects in the ATPase of the complex and is defective for interaction with Rad17/3/1 and for loading of the checkpoint clamp. A similar defect was measured with a mutant RFC-Rad24 clamp loader carrying a rfc4K55R ATP-binding mutation, whereas the rfc4K55E clamp loader showed partial loading activity, in agreement with genetic studies of these mutants. These studies show that ATP utilization by the checkpoint clamp/clamp loader system is effectively different from that by the structurally analogous replication system.     

ATP utilization by yeast replication factor C. III. The ATP-binding domains of Rfc2, Rfc3, and Rfc4 are essential for DNA recognition and clamp loading.

The conserved lysine in the Walker A motif of the ATP-binding domain encoded by the yeast RFC1, RFC2, RFC3, and RFC4 genes was mutated to glutamic acid. Complexes of replication factor C with a N-terminal truncation (Delta2-273) of the Rfc1 subunit (RFC) containing a single mutant subunit were overproduced in Escherichia coli for biochemical analysis. All of the mutant RFC complexes were capable of interacting with PCNA. Complexes containing a rfc1-K359E mutation were similar to wild type in replication activity and ATPase activity; however, the mutant complex showed increased susceptibility to proteolysis. In contrast, complexes containing either a rfc2-K71E mutation or a rfc3-K59E mutation were severely impaired in ATPase and clamp loading activity. In addition to their defects in ATP hydrolysis, these complexes were defective for DNA binding. A mutant complex containing the rfc4-K55E mutation performed as well as a wild type complex in clamp loading, but only at very high ATP concentrations. Mutant RFC complexes containing rfc2-K71R or rfc3-K59R, carrying a conservative lysine --> arginine mutation, had much milder clamp loading defects that could be partially (rfc2-K71R) or completely (rfc3-K59R) suppressed at high ATP concentrations.     

Replication protein A directs loading of the DNA damage checkpoint clamp to 5'-DNA junctions

The heterotrimeric checkpoint clamp comprises the Saccharomyces cerevisiae Rad17, Mec3, and Ddc1 subunits (Rad17/3/1, the 9-1-1 complex in humans). This DNA damage response factor is loaded onto DNA by the Rad24-RFC (replication factor C-like complex with Rad24) clamp loader and ATP. Although Rad24-RFC alone does not bind to naked partial double-stranded DNA, coating of the single strand with single-stranded DNA-binding protein RPA (replication protein A) causes binding of Rad24-RFC via interactions with RPA. However, RPA-mediated binding is abrogated when the DNA is coated with RPA containing a rpa1-K45E (rfa1-t11) mutation. These properties allowed us to determine the role of RPA in clamp-loading specificity. The Rad17/3/1 clamp is loaded with comparable efficiency onto naked primer/template DNA with either a 3'-junction or a 5'-junction. Remarkably, when the DNA was coated with RPA, loading of Rad17/3/1 at 3'-junctions was completely inhibited, thereby providing specificity to loading at 5'-junctions. However, Rad17/3/1 loaded at 5'-junctions can slide across double-stranded DNA to nearby 3'-junctions and thereby affect the activity of proteins that act at 3'-termini. These studies show a unique specificity of the checkpoint loader for 5'-junctions of RPA-coated DNA. The implications of this specificity for checkpoint function are discussed.     

A function for the psi subunit in loading the Escherichia coli DNA polymerase sliding clamp

Crystal structures of an Escherichia coli clamp loader have provided insight into the mechanism by which this molecular machine assembles ring-shaped sliding clamps onto DNA. The contributions made to the clamp loading reaction by two subunits, chi and psi, which are not present in the crystal structures, were determined by measuring the activities of three forms of the clamp loader, gamma(3)deltadelta', gamma(3)deltadelta'psi, and gamma(3)deltadelta'psichi. The psi subunit is important for stabilizing an ATP-induced conformational state with high affinity for DNA, whereas the chi subunit does not contribute directly to clamp loading in our assays lacking single-stranded DNA-binding protein. The psi subunit also increases the affinity of the clamp loader for the clamp in assays in which ATPgammaS is substituted for ATP. Interestingly, the affinity of the gamma(3)deltadelta' complex for beta is no greater in the presence than in the absence of ATPgammaS. A role for psi in stabilizing or promoting ATP- and ATPgammaS-induced conformational changes may explain why large conformational differences were not seen in gamma(3)deltadelta' structures with and without bound ATPgammaS. The beta clamp partially compensates for the activity of psi when this subunit is not present and possibly serves as a scaffold on which the clamp loader adopts the appropriate conformation for DNA binding and clamp loading. Results from our work and others suggest that the psi subunit may introduce a temporal order to the clamp loading reaction in which clamp binding precedes DNA binding.     

The replication factor C clamp loader requires arginine finger sensors to drive DNA binding and proliferating cell nuclear antigen loading

Replication factor C (RFC) is an AAA+ heteropentamer that couples the energy of ATP binding and hydrolysis to the loading of the DNA polymerase processivity clamp, proliferating cell nuclear antigen (PCNA), onto DNA. RFC consists of five subunits in a spiral arrangement (RFC-A, -B, -C, -D, and -E, corresponding to subunits RFC1, RFC4, RFC3, RFC2, and RFC5, respectively). The RFC subunits are AAA+ family proteins and the complex contains four ATP sites (sites A, B, C, and D) located at subunit interfaces. In each ATP site, an arginine residue from one subunit is located near the gamma-phosphate of ATP bound in the adjacent subunit. These arginines act as "arginine fingers" that can potentially perform two functions: sensing that ATP is bound and catalyzing ATP hydrolysis. In this study, the arginine fingers in RFC were mutated to examine the steps in the PCNA loading mechanism that occur after RFC binds ATP. This report finds that the ATP sites of RFC function in distinct steps during loading of PCNA onto DNA. ATP binding to RFC powers recruitment and opening of PCNA and activates a gamma-phosphate sensor in ATP site C that promotes DNA association. ATP hydrolysis in site D is uniquely stimulated by PCNA, and we propose that this event is coupled to PCNA closure around DNA, which starts an ordered hydrolysis around the ring. PCNA closure severs contact to RFC subunits D and E (RFC2 and RFC5), and the gamma-phosphate sensor of ATP site C is switched off, resulting in low affinity of RFC for DNA and ejection of RFC from the site of PCNA loading.     

Cyclin-Dependent Kinase Inhibitor p21 Modulates the DNA Primer-Template Recognition Complex

The p21 protein, a cyclin-dependent kinase (CDK) inhibitor, is capable of binding to both cyclin-CDK and the proliferating cell nuclear antigen (PCNA). Through its binding to PCNA, p21 can regulate the function of PCNA differentially in replication and repair. To gain an understanding of the precise mechanism by which p21 affects PCNA function, we have designed a new assay for replication factor C (RFC)-catalyzed loading of PCNA onto DNA, a method that utilizes a primer-template DNA attached to agarose beads via biotin-streptavidin. Using this assay, we showed that RFC remains transiently associated with PCNA on the DNA after the loading reaction. Addition of p21 did not inhibit RFC-dependent PCNA loading; rather, p21 formed a stable complex with PCNA on the DNA. In contrast, the formation of a p21-PCNA complex on the DNA resulted in the displacement of RFC from the DNA. The nonhydrolyzable analogs of ATP, adenosine-5′-O-(3-thiotriphosphate) (ATPγS) and adenyl-imidodiphosphate, each stabilized the primer recognition complex containing RFC and PCNA in the absence of p21. RFC in the ATPγS-activated complex was no longer displaced from the DNA by p21. We propose that p21 stimulates the dissociation of the RFC from the PCNA-DNA complex in a process that requires ATP hydrolysis and then inhibits subsequent PCNA-dependent events in DNA replication. The data suggest that the conformation of RFC in the primer recognition complex might change on hydrolysis of ATP. We also suggest that the p21-PCNA complex that remains attached to DNA might function to tether cyclin-CDK complexes to specific regions of the genome.     

Coupled ATP and DNA binding of adeno-associated virus Rep40 helicase

Adeno-associated virus 2 Rep40 helicase is involved in packaging single-stranded genomic DNA into virions. ATPase activity was stimulated 5-10-fold by DNA, depending upon assay conditions. The concentration dependence of Rep40 ATPase activity in the absence and presence of DNA indicates that the monomer is inactive and that the active enzyme is at least a dimer. Binding to oligonucleotides, examined by fluorescence anisotropy, was positively cooperative and required ATP or ATPgammaS; ADP and AMPPCP did not promote binding. The cooperativity and the nucleotide requirement were also demonstrated by surface plasmon resonance. Although the Rep40 behaves as a monomer in solution, it binds to DNA as an oligomer. The requirement of a nucleotide for DNA binding and the stimulation of ATPase activity by DNA indicate that the two processes are linked. Glutaraldehyde cross-linking generated a species that migrates as a trimer on sodium dodecyl sulfate (SDS) gel electrophoresis; ATPS promoted the formation of this species and higher order oligomers. The predominant cross-linked species was a trimer in the absence of ATPgammaS, regardless of whether duplex or single-stranded DNA was present. In the presence of duplex or single-stranded DNA and ATPgammaS, glutaraldehyde cross-linking generated a species that behaved as a dimer on SDS gel elctrophoresis. Sucrose-gradient velocity sedimentation of Rep40 gave an S20,w of 3 in the absence of ligands or in the presence of a 26 bp duplex DNA. The S20,w was 3.5 in the presence of ATPgammaS and 7 and 7.6 in the presence of DNA and ATPgammaS.     

Multiple competition reactions for RPA order the assembly of the DNA polymerase delta holoenzyme.

Processive extension of DNA in eukaryotes requires three factors to coordinate their actions. First, DNA polymerase alpha-primase synthesizes the primed site. Then replication factor C loads a proliferating cell nuclear antigen (PCNA) clamp onto the primer. Following this, DNA polymerase delta assembles with PCNA for processive extension. This report shows that these proteins each bind the primed site tightly and trade places in a highly coordinated fashion such that the primer terminus is never left free of protein. Replication protein A (RPA), the single-stranded DNA-binding protein, forms a common touchpoint for each of these proteins and they compete with one another for it. Thus these protein exchanges are driven by competition-based protein switches in which two proteins vie for contact with RPA.     

Interaction of tyrosine 65 of RecA protein with the first and second DNA strands

We investigated the structure of the active RecA-DNA complex by analyzing the environment of tyrosine residue 65, which is on the DNA-binding surface of the protein. We prepared a modified RecA protein in which the tyrosine residue was replaced by tryptophan, a natural fluorescent reporter, and measured the change in its fluorescence upon binding of DNA and cofactor. The fluorescence of the inserted tryptophan 65 (Trp65) was centered at 345 nm, indicating a partly exposed residue. Binding cofactor, adenosine 5'-O-3-thiotriphosphate (ATPgammaS), alone at a low salt concentration did not change the fluorescence of Trp65, confirming that the residue is not close to the nucleotide. In contrast, the binding of single-stranded DNA quenched the fluorescence of Trp65 in both the presence and absence of ATPgammaS. Trp65 fluorescence was also quenched upon binding a second DNA strand. The fluorescence change depended upon the presence and absence of ATPgammaS, reflecting the difference in the DNA binding. These results indicate that residue 65 is close to both the first and second DNA strands. The degree of quenching depended upon the base composition of DNA, suggesting that the residue 65 interacts with the DNA bases. Binding of DNA with ATPgammaS as well as binding of ATPgammaS alone at high salt concentration shifted the fluorescence emission peak from 345 to 330 nm, indicating a change from a polar to a non-polar environment. Therefore, the environment change around residue 65 would also be linked to a change in conformation and thus the activation of the protein.     

Sulfolobus Replication Factor C Stimulates the Activity of DNA Polymerase B1

Replication factor C (RFC) is known to function in loading proliferating cell nuclear antigen (PCNA) onto primed DNA, allowing PCNA to tether DNA polymerase for highly processive DNA synthesis in eukaryotic and archaeal replication. In this report, we show that an RFC complex from the hyperthermophilic archaea of the genus Sulfolobus physically interacts with DNA polymerase B1 (PolB1) and enhances both the polymerase and 3′-5′ exonuclease activities of PolB1 in an ATP-independent manner. Stimulation of the PolB1 activity by RFC is independent of the ability of RFC to bind DNA but is consistent with the ability of RFC to facilitate DNA binding by PolB1 through protein-protein interaction. These results suggest that Sulfolobus RFC may play a role in recruiting DNA polymerase for efficient primer extension, in addition to clamp loading, during DNA replication.     

Purification of host cell enzymes involved in adeno-associated virus DNA replication

Adeno-associated virus (AAV) replicates its DNA by a modified rolling-circle mechanism that exclusively uses leading strand displacement synthesis. To identify the enzymes directly involved in AAV DNA replication, we fractionated adenovirus-infected crude extracts and tested them in an in vitro replication system that required the presence of the AAV-encoded Rep protein and the AAV origins of DNA replication, thus faithfully reproducing in vivo viral DNA replication. Fractions that contained replication factor C (RFC) and proliferating cell nuclear antigen (PCNA) were found to be essential for reconstituting AAV DNA replication. These could be replaced by purified PCNA and RFC to retain full activity. We also found that fractions containing polymerase delta, but not polymerase epsilon or alpha, were capable of replicating AAV DNA in vitro. This was confirmed when highly purified polymerase delta complex purified from baculovirus expression clones was used. Curiously, as the components of the DNA replication system were purified, neither the cellular single-stranded DNA binding protein (RPA) nor the adenovirus-encoded DNA binding protein was found to be essential for DNA replication; both only modestly stimulated DNA synthesis on an AAV template. Also, in addition to polymerase delta, RFC, and PCNA, an as yet unidentified factor(s) is required for AAV DNA replication, which appeared to be enriched in adenovirus-infected cells. Finally, the absence of any apparent cellular DNA helicase requirement led us to develop an artificial AAV replication system in which polymerase delta, RFC, and PCNA were replaced with T4 DNA polymerase and gp32 protein. This system was capable of supporting AAV DNA replication, demonstrating that under some conditions the Rep helicase activity can function to unwind duplex DNA during strand displacement synthesis.