Mutations in yeast proliferating cell nuclear antigen define distinct sites for interaction with DNA polymerase delta and DNA polymerase epsilon.

The importance of the interdomain connector loop and of the carboxy-terminal domain of Saccharomyces cerevisiae proliferating cell nuclear antigen (PCNA) for functional interaction with DNA polymerases delta (Poldelta) and epsilon (Pol epsilon) was investigated by site-directed mutagenesis. Two alleles, pol30-79 (IL126,128AA) in the interdomain connector loop and pol30-90 (PK252,253AA) near the carboxy terminus, caused growth defects and elevated sensitivity to DNA-damaging agents. These two mutants also had elevated rates of spontaneous mutations. The mutator phenotype of pol30-90 was due to partially defective mismatch repair in the mutant. In vitro, the mutant PCNAs showed defects in DNA synthesis. Interestingly, the pol30-79 mutant PCNA (pcna-79) was most defective in replication with Poldelta, whereas pcna-90 was defective in replication with Pol epsilon. Protein-protein interaction studies showed that pcna-79 and pcna-90 failed to interact with Pol delta and Pol epsilon, respectively. In addition, pcna-90 was defective in interaction with the FEN-1 endo-exonuclease (RTH1 product). A loss of interaction between pcna-79 and the smallest subunit of Poldelta, the POL32 gene product, implicates this interaction in the observed defect with the polymerase. Neither PCNA mutant showed a defect in the interaction with replication factor C or in loading by this complex. Processivity of DNA synthesis by the mutant holoenzyme containing pcna-79 was unaffected on poly(dA) x oligo(dT) but was dramatically reduced on a natural template with secondary structure. A stem-loop structure with a 20-bp stem formed a virtually complete block for the holoenzyme containing pcna-79 but posed only a minor pause site for wild-type holoenzyme, indicating a function of the POL32 gene product in allowing replication past structural blocks.

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.

Functional domains of the 70-kilodalton subunit of human replication protein A.

Human replication protein A (RPA) is a single-stranded DNA-binding protein that is composed of subunits of 70, 32, and 14 kDa. This heterotrimeric complex is required for multiple processes in DNA metabolism including DNA replication, DNA repair, and recombination. Previous studies have suggested that the 616 amino acid, 70-kDa subunit of RPA (RPA 70) is composed of multiple structural/functional domains. We used a series of N-terminal deletions of RPA70 to define the boundaries of these domains and elucidate their functions. Mutant RPA complexes missing residues 1-168 of RPA70 bound ssDNA with high affinity and supported SV40 replication in vitro. In contrast, deletions extending beyond residue 168 showed a decreased affinity for ssDNA and were inactive in SV40 DNA replication. When residues 1-381 were deleted, the resulting truncated RPA70 was unable to bind ssDNA but still formed a stable complex with the 32- and 14-kDa subunits of RPA. Thus, the C-terminal domain of RPA70 is both necessary and sufficient for RPA complex formation. These data indicate that RPA70 is composed of three functional domains: an N-terminal domain that is not required for ssDNA binding or SV40 replication, a central DNA-binding domain, and a C-terminal domain that is essential for subunit interactions. For all mutant complexes examined, both phosphorylation of the 32-kDa subunit of RPA and the ability to support T antigen-dependent, origin-dependent DNA unwinding correlated with ssDNA binding activity.

ATP utilization by yeast replication factor C. I. ATP-mediated interaction with DNA and with proliferating cell nuclear antigen.

Eukaryotic replication factor C is the heteropentameric complex that loads the replication clamp proliferating cell nuclear antigen (PCNA) onto primed DNA. In this study we used a derivative, designated RFC, with a N-terminal truncation of the Rfc1 subunit removing a DNA-binding domain not required for clamp loading. Interactions of yeast RFC with PCNA and DNA were studied by surface plasmon resonance. Binding of RFC to PCNA was stimulated by either adenosine (3-thiotriphosphate) (ATPgammaS) or ATP. RFC bound only to primer-template DNA coated with the single-stranded DNA-binding protein RPA if ATPgammaS was also present. Binding occurred without dissociation of RPA. ATP did not stimulate binding of RFC to DNA, suggesting that hydrolysis of ATP dissociated DNA-bound RFC. However, when RFC and PCNA together were flowed across the DNA chip in the presence of ATP, a signal was observed suggesting loading of PCNA by RFC. With ATPgammaS present instead of ATP, long-lived response signals were observed indicative of loading complexes arrested on the DNA. A primer with a 3' single-stranded extension also allowed loading of PCNA; yet turnover of the reaction intermediates was dramatically slowed down. Filter binding experiments and analysis of proteins bound to DNA-magnetic beads confirmed the conclusions drawn from the surface plasmon resonance studies.

Two modes of FEN1 binding to PCNA regulated by DNA.

The FEN1 nuclease functions during Okazaki fragment maturation in the eukaryotic cell. Like many other proliferating cell nuclear antigen (PCNA)-binding proteins, FEN1 interacts with the interdomain connector loop (IDCL) of PCNA, and PCNA greatly stimulates FEN1 activity. A yeast IDCL mutant pcna-79 (IL126,128AA) failed to interact with FEN-1, but, surprisingly, pcna-79 was still very active in stimulating FEN1 activity. In contrast, a C-terminal mutant pcna-90 (PK252,253AA) showed wild-type binding to FEN1 in solution, but poorly stimulated FEN1 activity. When PCNA was loaded onto a DNA substrate coupled to magnetic beads, it stabilized retention of FEN1 on the DNA. In this DNA-dependent binding assay, pcna-79 also stabilized retention of FEN1, but pcna-90 was inactive. Therefore, in the absence of DNA, FEN1 interacts with PCNA mainly through the IDCL. However, when PCNA encircles the DNA, the C-terminal domain of PCNA rather than its IDCL is important for binding FEN1. An FF-->GA mutation in the PCNA-interaction domain of FEN1 severely decreased both modes of interaction with PCNA and resulted in replication and repair defects in vivo.

Overproduction in Escherichia coli and characterization of yeast replication factor C lacking the ligase homology domain.

Eukaryotic replication factor C (RF-C) is a heteropentameric complex that is required to load the replication clamp proliferating cell nuclear antigen onto primed DNA. Saccharomyces cerevisiae RF-C is encoded by the genes RFC1-RFC5. The RFC1 gene was cloned under control of the strong inducible bacteriophage T7 promoter, yet induction did not yield detectable Rfc1p. However, a truncated form of RFC1 deleted for the coding region for amino acids 3-273, rfc1-DeltaN, did allow overproduction. The other four RFC genes were cloned into the latter plasmid to yield a single plasmid that overproduced RF-C to moderate levels. Overproduction of the complex was further enhanced when the Escherichia coli argU gene encoding the rare arginine tRNA was also overproduced. The enzyme thus produced in E. coli was purified to homogeneity through three column steps, including a proliferating cell nuclear antigen affinity column. This enzyme, as well as the enzyme purified from yeast, is prone to aggregation and inactivation, and therefore, light scattering was used to determine conditions stabilizing the enzyme and preventing aggregation. Broad-range carrier ampholytes at about 0.05% were found to be most effective. In some assays, the Rfc1-DeltaN containing RF-C from E. coli showed an increased activity compared with the full-length enzyme from yeast, likely because the latter enzyme exhibits significant nonspecific binding to single-stranded DNA. Replacement of RFC1 by rfc1-DeltaN in yeast shows essentially no phenotype with regard to DNA replication, damage susceptibility, telomere length maintenance, and intrachromosomal recombination.

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.

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.

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 interactions with DNA. 1. Functions of the DNA-binding and zinc-finger domains of the 70-kDa subunit.

Human replication protein A (RPA) is a multiple subunit single-stranded DNA-binding protein that is required for multiple processes in cellular DNA metabolism. This complex, composed of subunits of 70, 32, and 14 kDa, binds to single-stranded DNA (ssDNA) with high affinity and participates in multiple protein-protein interactions. The 70-kDa subunit of RPA is known to be composed of multiple domains: an N-terminal domain that participates in protein interactions, a central DNA-binding domain (composed of two copies of a ssDNA-binding motif), a putative (C-X2-C-X13-C-X2-C) zinc finger, and a C-terminal intersubunit interaction domain. A series of mutant forms of RPA were used to elucidate the roles of these domains in RPA function. The central DNA-binding domain was necessary and sufficient for interactions with ssDNA; however, adjacent sequences, including the zinc-finger domain and part of the N-terminal domain, were needed for optimal ssDNA-binding activity. The role of aromatic residues in RPA-DNA interactions was examined. Mutation of any one of the four aromatic residues shown to interact with ssDNA had minimal effects on RPA activity, indicating that individually these residues are not critical for RPA activity. Mutation of the zinc-finger domain altered the structure of the RPA complex, reduced ssDNA-binding activity, and eliminated activity in DNA replication.

Replication protein A interactions with DNA. III. Molecular basis of recognition of damaged DNA.

Human replication protein A (RPA) is a heterotrimeric single-stranded DNA-binding protein (subunits of 70, 32, and 14 kDa) that is required for cellular DNA metabolism. RPA has been reported to interact specifically with damaged double-stranded DNA and to participate in multiple steps of nucleotide excision repair (NER) including the damage recognition step. We have examined the mechanism of RPA binding to both single-stranded and double-stranded DNA (ssDNA and dsDNA, respectively) containing damage. We show that the affinity of RPA for damaged dsDNA correlated with disruption of the double helix by the damaged bases and required RPAs ssDNA-binding activity. We conclude that RPA is recognizing single-stranded character caused by the damaged nucleotides. We also show that RPA binds specifically to damaged ssDNA. The specificity of binding varies with the type of damage with RPA having up to a 60-fold preference for a pyrimidine(6-4)pyrimidone photoproduct. We show that this specific binding was absolutely dependent on the zinc-finger domain in the C-terminus of the 70-kDa subunit. The affinity of RPA for damaged ssDNA was 5 orders of magnitude higher than that of the damage recognition protein XPA (xeroderma pigmentosum group A protein). These findings suggest that RPA probably binds to both damaged and undamaged strands in the NER excision complex. RPA binding may be important for efficient excision of damaged DNA in NER.