Completion of mammalian lagging strand DNA replication using purified proteins

An emerging paradigm in epigenetic marking: coordination of transcription and replication

DNA replication and RNA transcription both utilize DNA as a template and therefore need to coordinate their activities. The predominant theory in the field is that in order for the replication fork to proceed, transcription machinery has to be evicted from DNA until replication is complete. If that does not occur, these machineries collide, and these collisions elicit various repair mechanisms which require displacement of one of the enzymes, often RNA polymerase, in order for replication to proceed. This model is also at the heart of the epigenetic bookmarking theory, which implies that displacement of RNA polymerase during replication requires gradual re-building of chromatin structure, which guides recruitment of transcriptional proteins and resumption of transcription. We discuss these theories but also bring to light newer data that suggest that these two processes may not be as detrimental to one another as previously thought. This includes findings suggesting that these processes can occur without fork collapse and that RNA polymerase may only be transiently displaced during DNA replication. We discuss potential mechanisms by which RNA polymerase may be retained at the replication fork and quickly rebind to DNA post-replication. These discoveries are important, not only as new evidence as to how these two processes are able to occur harmoniously but also because they have implications on how transcriptional programs are maintained through DNA replication. To this end, we also discuss the coordination of replication and transcription in light of revising the current epigenetic bookmarking theory of how the active gene status can be transmitted through S phase.

Whole Genome Sequence Analysis of Mutations Accumulated in rad27 Yeast Strains with Defects in the Processing of Okazaki Fragments Indicates Template-Switching Events

Okazaki fragments that are formed during lagging strand DNA synthesis include an initiating primer consisting of both RNA and DNA. The RNA fragment must be removed before the fragments are joined. In Saccharomyces cerevisiae, a key player in this process is the structure-specific flap endonuclease, Rad27p (human homolog FEN1). To obtain a genomic view of the mutational consequence of loss of RAD27, a S. cerevisiae rad27Δ strain was subcultured for 25 generations and sequenced using Illumina paired-end sequencing. Out of the 455 changes observed in 10 colonies isolated the two most common types of events were insertions or deletions (INDELs) in simple sequence repeats (SSRs) and INDELs mediated by short direct repeats. Surprisingly, we also detected a previously neglected class of 21 template-switching events. These events were presumably generated by quasi-palindrome to palindrome correction, as well as palindrome elongation. The formation of these events is best explained by folding back of the stalled nascent strand and resumption of DNA synthesis using the same nascent strand as a template. Evidence of quasi-palindrome to palindrome correction that could be generated by template switching appears also in yeast genome evolution. Out of the 455 events, 55 events appeared in multiple isolates; further analysis indicates that these loci are mutational hotspots. Since Rad27 acts on the lagging strand when the leading strand should not contain any gaps, we propose a mechanism favoring intramolecular strand switching over an intermolecular mechanism. We note that our results open new ways of understanding template switching that occurs during genome instability and evolution.

Okazaki fragment maturation: nucleases take centre stage

Completion of lagging strand DNA synthesis requires processing of up to 50 million Okazaki fragments per cell cycle in mammalian cells. Even in yeast, the Okazaki fragment maturation happens approximately a million times during a single round of DNA replication. Therefore, efficient processing of Okazaki fragments is vital for DNA replication and cell proliferation. During this process, primase-synthesized RNA/DNA primers are removed, and Okazaki fragments are joined into an intact lagging strand DNA. The processing of RNA/DNA primers requires a group of structure-specific nucleases typified by flap endonuclease 1 (FEN1). Here, we summarize the distinct roles of these nucleases in different pathways for removal of RNA/DNA primers. Recent findings reveal that Okazaki fragment maturation is highly coordinated. The dynamic interactions of polymerase δ, FEN1 and DNA ligase I with proliferating cell nuclear antigen allow these enzymes to act sequentially during Okazaki fragment maturation. Such protein-protein interactions may be regulated by post-translational modifications. We also discuss studies using mutant mouse models that suggest two distinct cancer etiological mechanisms arising from defects in different steps of Okazaki fragment maturation. Mutations that affect the efficiency of RNA primer removal may result in accumulation of unligated nicks and DNA double-strand breaks. These DNA strand breaks can cause varying forms of chromosome aberrations, contributing to development of cancer that associates with aneuploidy and gross chromosomal rearrangement. On the other hand, mutations that impair editing out of polymerase α incorporation errors result in cancer displaying a strong mutator phenotype.

Processing of lagging-strand intermediates in vitro by herpes simplex virus type 1 DNA polymerase

The processing of lagging-strand intermediates has not been demonstrated in vitro for herpes simplex virus type 1 (HSV-1). Human flap endonuclease-1 (Fen-1) was examined for its ability to produce ligatable products with model lagging-strand intermediates in the presence of the wild-type or exonuclease-deficient (exo(-)) HSV-1 DNA polymerase (pol). Primer/templates were composed of a minicircle single-stranded DNA template annealed to primers that contained 5' DNA flaps or 5' annealed DNA or RNA sequences. Gapped DNA primer/templates were extended but not significantly strand displaced by the wild-type HSV-1 pol, although significant strand displacement was observed with exo(-) HSV-1 pol. Nevertheless, the incubation of primer/templates containing 5' flaps with either wild-type or exo(-) HSV-1 pol and Fen-1 led to the efficient production of nicks that could be sealed with DNA ligase I. Both polymerases stimulated the nick translation activity of Fen-1 on DNA- or RNA-containing primer/templates, indicating that the activities were coordinated. Further evidence for Fen-1 involvement in HSV-1 DNA synthesis is suggested by the ability of a transiently expressed green fluorescent protein fusion with Fen-1 to accumulate in viral DNA replication compartments in infected cells and by the ability of endogenous Fen-1 to coimmunoprecipitate with an essential viral DNA replication protein in HSV-1-infected cells.

Disruption of the FEN-1/PCNA interaction results in DNA replication defects, pulmonary hypoplasia, pancytopenia, and newborn lethality in mice

The interaction between flap endonuclease 1 (FEN-1) and proliferation cell nuclear antigen (PCNA) is critical for faithful and efficient Okazaki fragment maturation. In a living cell, this interaction is probably important for PCNA to load FEN-1 to the replication fork, to coordinate the sequential functions of FEN-1 and other enzymes, and to stimulate its enzyme activity. The FEN-1/PCNA interaction is mediated by the motif (337)QGRLDDFFK(345) of FEN-1, such that an F343AF344A (FFAA) mutant cannot bind to PCNA but retains its nuclease activities. To determine the physiological roles of the FEN-1/PCNA interaction in a mammalian system, we knocked the FFAA Fen1 mutation into the Fen1 gene locus of mice. FFAA/FFAA mouse embryo fibroblasts underwent DNA replication and division at a slower pace, and FFAA/FFAA mutant embryos displayed significant defects in growth and development, particularly in the lung and blood systems. All newborn FFAA mutant pups died at birth, likely due to pulmonary hypoplasia and pancytopenia. Collectively, our data demonstrate the importance of the FEN-1/PCNA complex in DNA replication and in the embryonic development of mice.

Mechanism of stimulation of human DNA ligase I by the Rad9-rad1-Hus1 checkpoint complex

Accumulating evidence suggests that the Rad9-Rad1-Hus1 (9-1-1) checkpoint complex, known to be a sensor of DNA damage, is also a component of DNA repair systems. Recent results show that 9-1-1 interacts with several base excision repair proteins. It binds the DNA glycosylase MutY homolog, and stimulates DNA polymerase beta, flap endonuclease 1, and DNA ligase I. 9-1-1 resembles proliferating cell nuclear antigen (PCNA), which stimulates some of these same repair enzymes, and is loaded onto DNA in a similar manner. The complex of 9-1-1 with DNA ligase I can be immunoprecipitated from human cells. Moreover, UV irradiation stimulates 9-1-1.ligase I complex formation, suggesting a role for 9-1-1 in DNA repair. Examining the nature of 9-1-1 interaction with DNA ligase I, we show that there is a similar degree of stimulation on ligation substrates with different structures, and that there is specificity for DNA ligase I. 9-1-1 improves the binding of DNA ligase I to nicked double strand DNA. Furthermore, although high concentrations of casein kinase II strongly inhibits DNA ligase I activity, it does not affect the ability of 9-1-1 to stimulate. This suggests that 9-1-1 is also an activator of DNA ligase I during DNA damage. Unlike PCNA, 9-1-1 stimulates DNA ligase I activity to the same extent on both linear and circular substrates, indicating that encirclement is not a requirement for stimulation. These data are consistent with a direct role for 9-1-1 in DNA repair, but possibly employing a different mechanism than PCNA.

Flap endonuclease 1: a central component of DNA metabolism

One strand of cellular DNA is generated as RNA-initiated discontinuous segments called Okazaki fragments that later are joined. The RNA terminated region is displaced into a 5' single-stranded flap, which is removed by the structure-specific flap endonuclease 1 (FEN1), leaving a nick for ligation. Similarly, in long-patch base excision repair, a damaged nucleotide is displaced into a flap and removed by FEN1. FEN1 is a genome stabilization factor that prevents flaps from equilibrating into structures that lead to duplications and deletions. As an endonuclease, FEN1 enters the flap from the 5' end and then tracks to cleave the flap base. Cleavage is oriented by the formation of a double flap. Analyses of FEN1 crystal structures suggest mechanisms for tracking and cleavage. Some flaps can form self-annealed and template bubble structures that interfere with FEN1. FEN1 interacts with other nucleases and helicases that allow it to act efficiently on structured flaps. Genetic and biochemical analyses continue to reveal many roles of FEN1.

Triplet repeat expansion generated by DNA slippage is suppressed by human flap endonuclease 1

Human flap endonuclease 1 (h-FEN1) mutations have dramatic effects on repeat instability. Current models for repeat expansion predict that h-FEN1 protein prevents mutations by removing 5'-flaps generated at ends of Okazaki fragments by strand displacement synthesis. The models propose that hairpin formations within flaps containing repeats enable them to escape h-FEN1 cleavage. Friedreich's ataxia is caused by expansion mutations in a d(GAA)n repeat tract. Single-stranded d(GAA)n repeat tracts, however, do not form stable hairpins until the repeat tracts are quite long. Therefore, to understand how d(GAA)n repeat expansions survive h-FEN1 activity, we determined the effects of h-FEN1 on d(GAA)n repeat expansion during replication of a d(TTC)n repeat template. Replication initiated within the repeat tract generated significant expansion that was suppressed by the addition of h-FEN1 at the start of replication. The ability of h-FEN1 to suppress expansion implies that DNA slippage generates a 5'-flap in the nascent strand independent of strand displacement synthesis by an upstream polymerase. Delaying the addition of h-FEN1 to the replication reaction abolished the ability of h-FEN1 ability to suppress d(GAA)n repeat expansion products of all sizes, including sizes unable to hairpin. Use of model substrates demonstrated that h-FEN1 cleaves d(GAA)n 5'-flaps joined to double-stranded nonrepeat sequences but not those joined to double-stranded repeat tracts. The results provide evidence that, given the opportunity, short d(GAA)n repeat expansion products rearrange from 5'-flaps to stable internal loops inside the repeat tract. Long expansion products are predicted to form hairpinned flaps and internal loops. Once formed, these DNA conformations resist h-FEN1. The biological implications of the results are discussed.

Complementary functions of the Saccharomyces cerevisiae Rad2 family nucleases in Okazaki fragment maturation, mutation avoidance, and chromosome stability

Rad2 family nucleases, identified by sequence similarity within their catalytic domains, function in multiple pathways of DNA metabolism. Three members of the Saccharomyces cerevisiae Rad2 family, Rad2, Rad27, and exonuclease 1 (Exo1), exhibit both 5' exonuclease and flap endonuclease activities. Deletion of RAD27 results in defective Okazaki fragment maturation, DNA repair, and subsequent defects in mutation avoidance and chromosomal stability. However, strains lacking Rad27 are viable. The expression profile of EXO1 during the cell cycle is similar to that of RAD27 and other genes encoding proteins that function in DNA replication and repair, suggesting Exo1 may function as a back up nuclease for Rad27 in DNA replication. We show that overexpression of EXO1 suppresses multiple rad27 null mutation-associated phenotypes derived from DNA replication defects, including temperature sensitivity, Okazaki fragment accumulation, the rate of minichromosome loss, and an elevated mutation frequency. While generally similar findings were observed with RAD2, overexpression of RAD2, but not EXO1, suppressed the MMS sensitivity of the rad27 null mutant cells. This suggests that Rad2 can uniquely complement Rad27 in base excision repair (BER). Furthermore, Rad2 and Exo1 complemented the mutator phenotypes and cell cycle defects of rad27 mutant strains to differing extents, suggesting distinct in vivo nucleic acid substrates.

Modeling of flap endonuclease interactions with DNA substrate

Structure-specific 5' nucleases play an important role in DNA replication and repair uniquely recognizing an overlap flap DNA substrate and processing it into a DNA nick. However, in the absence of a high-resolution structure of the enzyme/DNA complex, the mechanism underlying this recognition and substrate specificity, which is key to the enzyme's function, remains unclear. Here, we propose a three-dimensional model of the structure-specific 5' flap endonuclease from Pyrococcus furiosus in its complex with DNA. The model is based on the known X-ray structure of the enzyme and a variety of biochemical and molecular dynamics (MD) data utilized in the form of distance restraints between the enzyme and the DNA. Contacts between the 5' flap endonuclease and the sugar-phosphate backbone of the overlap flap substrate were identified using enzyme activity assays on substrates with methylphosphonate or 2'-O-methyl substitutions. The enzyme footprint extends two to four base-pairs upstream and eight to nine base-pairs downstream of the cleavage site, thus covering 10-13 base-pairs of duplex DNA. The footprint data are consistent with a model in which the substrate is bound in the DNA-binding groove such that the downstream duplex interacts with the helix-hairpin-helix motif of the enzyme. MD simulations to identify the substrate orientation in this model are consistent with the results of the enzyme activity assays on the methylphosphonate and 2'-O-methyl-modified substrates. To further refine the model, 5' flap endonuclease variants with alanine point substitutions at amino acid residues expected to contact phosphates in the substrate and one deletion mutant were tested in enzyme activity assays on the methylphosphonate-modified substrates. Changes in the enzyme footprint observed for two point mutants, R64A and R94A, and for the deletion mutant in the enzyme's beta(A)/beta(B) region, were interpreted as being the result of specific interactions in the enzyme/DNA complex and were used as distance restraints in MD simulations. The final structure suggests that the substrate's 5' flap interacts with the enzyme's helical arch and that the helix-hairpin-helix motif interacts with the template strand in the downstream duplex eight base-pairs from the cleavage site. This model suggests specific interactions between the 3' end of the upstream oligonucleotide and the enzyme. The proposed structure presents the first detailed description of substrate recognition by structure-specific 5' nucleases.

Okazaki fragment maturation in yeast. I. Distribution of functions between FEN1 AND DNA2

In the presence of proliferating cell nuclear antigen, yeast DNA polymerase delta (Pol delta) replicated DNA at a rate of 40-60 nt/s. When downstream double-stranded DNA was encountered, Pol delta paused, but most replication complexes proceeded to carry out strand-displacement synthesis at a rate of 1.5 nt/s. In the presence of the flap endonuclease FEN1 (Rad27), the complex carried out nick translation (1.7 nt/s). The Dna2 nuclease/helicase alone did not efficiently promote nick translation, nor did it affect nick translation with FEN1. Maturation in the presence of DNA ligase was studied with various downstream primers. Downstream DNA primers, RNA primers, and small 5'-flaps were efficiently matured by Pol delta and FEN1, and Dna2 did not stimulate maturation. However, maturation of long 5'-flaps to which replication protein A can bind required both DNA2 and FEN1. The maturation kinetics were optimal with a slight molar excess over DNA of Pol delta, FEN1, and proliferating cell nuclear antigen. A large molar excess of DNA ligase substantially enhanced the rate of maturation and shortened the nick-translation patch (nucleotides excised past the RNA/DNA junction before ligation) to 4-6 nt from 8-12 nt with equimolar ligase. These results suggest that FEN1, but not DNA ligase, is a stable component of the maturation complex.

A model for the involvement of Okazaki fragments maturation in the expansion of short tandem repeats

We propose a model for the expansion of short tandem repeats (ESTR), a phenomenon which has been found to occur in human DNA and is associated with a dozen of neuromuscular diseases. The model is based mainly on theoretical considerations and recovers experimental data from the literature; it also finds support in preliminary results obtained by us in multiprimed polymerase chain reactions designed to assess the effects of a downstream primer on the fidelity of the elongation of an upstream one. The model links the occurrence of the ESTR to a defective maturation of the Okazaki fragments (OF), and in particular to an improper processing of their 3' termini. This may occur when the last OF approaches the 5' terminus of the previous one in a susceptible region of the template. It is postulated here that when a growing OF has progressed past the priming region and its main portion has been synthesized, upon approaching its conclusion, the final elongation may take place in a region of the template where certain triplets are repeated: in that case a series of aberrations on the elongation mechanism may occur. These aberrations could involve (a) the displacement of the 5' terminus of the penultimate, properly matured OF, enacted by the incoming 3' terminus of the last OF, (b) the switch of the latter to the displaced strand of the former as template, (c) the fold-back on itself of the growing 3' terminus of the last OF, (d) its assumption of an unusual structure because of the repetition, and (e) some impairment of its removal by structure-specific exo-endonuclease(s). Derangements of this last part of the process may trigger the ESTR.

Identification of rad27 mutations that confer differential defects in mutation avoidance, repeat tract instability, and flap cleavage

In eukaryotes, the nuclease activity of Rad27p (Fen1p) is thought to play a critical role in lagging-strand DNA replication by removing ribonucleotides present at the 5' ends of Okazaki fragments. Genetic analysis of Saccharomyces cerevisiae also has identified a role for Rad27p in mutation avoidance. rad27Delta mutants display both a repeat tract instability phenotype and a high rate of forward mutations to canavanine resistance that result primarily from duplications of DNA sequences that are flanked by direct repeats. These observations suggested that Rad27p activities in DNA replication and repair could be altered by mutagenesis and specifically assayed. To test this idea, we analyzed two rad27 alleles, rad27-G67S and rad27-G240D, that were identified in a screen for mutants that displayed repeat tract instability and mutator phenotypes. In chromosome stability assays, rad27-G67S strains displayed a higher frequency of repeat tract instabilities relative to CAN1 duplication events; in contrast, the rad27-G240D strains displayed the opposite phenotype. In biochemical assays, rad27-G67Sp displayed a weak exonuclease activity but significant single- and double-flap endonuclease activities. In contrast, rad27-G240Dp displayed a significant double-flap endonuclease activity but was devoid of exonuclease activity and showed only a weak single-flap endonuclease activity. Based on these observations, we hypothesize that the rad27-G67S mutant phenotypes resulted largely from specific defects in nuclease function that are important for degrading bubble intermediates, which can lead to DNA slippage events. The rad27-G240D mutant phenotypes were more difficult to reconcile to a specific biochemical defect, suggesting a structural role for Rad27p in DNA replication and repair. Since the mutants provide the means to relate nuclease functions in vitro to genetic characteristics in vivo, they are valuable tools for further analyses of the diverse biological roles of Rad27p.

Links between replication and recombination in Saccharomyces cerevisiae: a hypersensitive requirement for homologous recombination in the absence of Rad27 activity

The RAD27 gene of Saccharomyces cerevisiae encodes a 5'-3' flap exo/endonuclease, which plays an important role during DNA replication for Okazaki fragment maturation. Genetic studies have shown that RAD27 is not essential for growth, although rad27 Delta mutants are temperature sensitive. Moreover, they exhibit increased sensitivity to alkylating agents, enhanced spontaneous recombination, and repetitive DNA instability. The conditional lethality conferred by the rad27 Delta mutation indicates that other nuclease(s) can compensate for the absence of Rad27. Indeed, biochemical and genetical analyses indicate that Okazaki fragment processing can be assured by other enzymatic activities or by alternative pathways such as homologous recombination. Here we present the results of a screen that makes use of a synthetic lethality assay to identify functions required for the survival of rad27 Delta strains. Altogether, we confirm that all genes of the Rad52 recombinational repair pathway are required for the survival of rad27 Delta strains at both permissive (23 degrees C) and semipermissive (30 degrees C) temperatures for growth. We also find that several point mutations that confer weaker phenotypes in mitotic than in meiotic cells (rad50S, mre11s) and additional gene deletions (com1/sae2, srs2) exhibit synthetic lethality with rad27 Delta and that rad59 Delta exhibits synergistic effects with rad27 Delta. This and previous studies indicate that homologous recombination is the primary, but not only, pathway that functions to bypass the replication defects that arise in the absence of the Rad27 protein.

DNA ligase I and proliferating cell nuclear antigen form a functional complex

DNA ligase I is responsible for joining Okazaki fragments during DNA replication. An additional proposed role for DNA ligase I is sealing nicks generated during excision repair. Previous studies have shown that there is a physical interaction between DNA ligase I and proliferating cell nuclear antigen (PCNA), another important component of DNA replication and repair. The results shown here indicate that human PCNA enhances the reaction rate of human DNA ligase I up to 5-fold. The stimulation is specific to DNA ligase I because T4 DNA ligase is not affected. Electrophoretic mobility shift assays indicate that PCNA improves the binding of DNA ligase I to the ligation site. Increasing the DNA ligase I concentration leads to a reduction in PCNA stimulation, consistent with PCNA-directed improvement of DNA ligase I binding to its DNA substrate. Two experiments show that PCNA is required to encircle duplex DNA to enhance DNA ligase I activity. Biotin-streptavidin conjugations at the ends of a linear substrate inhibit PCNA stimulation. PCNA cannot enhance ligation on a circular substrate without the addition of replication factor C, which is the protein responsible for loading PCNA onto duplex DNA. These results show that PCNA is responsible for the stable association of DNA ligase I to nicked duplex DNA.

Bacteriophage T4 RNase H removes both RNA primers and adjacent DNA from the 5' end of lagging strand fragments

Bacteriophage T4 RNase H belongs to a family of prokaryotic and eukaryotic nucleases that remove RNA primers from lagging strand fragments during DNA replication. Each enzyme has a flap endonuclease activity, cutting at or near the junction between single- and double-stranded DNA, and a 5'- to 3'-exonuclease, degrading both RNA.DNA and DNA.DNA duplexes. On model substrates for lagging strand synthesis, T4 RNase H functions as an exonuclease removing short oligonucleotides, rather than as an endonuclease removing longer flaps created by the advancing polymerase. The combined length of the DNA oligonucleotides released from each fragment ranges from 3 to 30 nucleotides, which corresponds to one round of processive degradation by T4 RNase H with 32 single-stranded DNA-binding protein present. Approximately 30 nucleotides are removed from each fragment during coupled leading and lagging strand synthesis with the complete T4 replication system. We conclude that the presence of 32 protein on the single-stranded DNA between lagging strand fragments guarantees that the nuclease will degrade processively, removing adjacent DNA as well as the RNA primers, and that the difference in the relative rates of synthesis and hydrolysis ensures that there is usually only a single round of degradation during each lagging strand cycle.

RNA template-dependent 5' nuclease activity of Thermus aquaticus and Thermus thermophilus DNA polymerases

DNA replication and repair require a specific mechanism to join the 3'- and 5'-ends of two strands to maintain DNA continuity. In order to understand the details of this process, we studied the activity of the 5' nucleases with substrates containing an RNA template strand. By comparing the eubacterial and archaeal 5' nucleases, we show that the polymerase domain of the eubacterial enzymes is critical for the activity of the 5' nuclease domain on RNA containing substrates. Analysis of the activity of chimeric enzymes between the DNA polymerases from Thermus aquaticus (TaqPol) and Thermus thermophilus (TthPol) reveals two regions, in the "thumb" and in the "palm" subdomains, critical for RNA-dependent 5' nuclease activity. There are two critical amino acids in those regions that are responsible for the high activity of TthPol on RNA containing substrates. Mutating glycine 418 and glutamic acid 507 of TaqPol to lysine and glutamine, respectively, increases its RNA-dependent 5' nuclease activity 4-10-fold. Furthermore, the RNA-dependent DNA polymerase activity is controlled by a completely different region of TaqPol and TthPol, and mutations in this region do not affect the 5' nuclease activity. The results presented here suggest a novel substrate binding mode of the eubacterial DNA polymerase enzymes, called a 5' nuclease mode, that is distinct from the polymerizing and editing modes described previously. The application of the enzymes with improved RNA-dependent 5' nuclease activity for RNA detection using the invasive signal amplification assay is discussed.

Replication protein A (RPA) binding to duplex cisplatin-damaged DNA is mediated through the generation of single-stranded DNA

Replication protein A (RPA) is a heterotrimeric protein composed of 70-, 34-, and 14-kDa subunits that has been shown to be required for DNA replication, repair, and homologous recombination. We have previously shown preferential binding of recombinant human RPA (rhRPA) to duplex cisplatin-damaged DNA compared with the control undamaged DNA (Patrick, S. M., and Turchi, J. J. (1998) Biochemistry 37, 8808-8815). Here we assess the binding of rhRPA to DNA containing site-specific cisplatin-DNA adducts. rhRPA is shown to bind 1.5-2-fold better to a duplex 30-base pair substrate containing a single 1,3d(GpXpG) compared with a 1,2d(GpG) cisplatin-DNA intrastrand adduct, consistent with the difference in thermal stability of DNA containing each adduct. Consistent with these data, a 21-base pair DNA substrate containing a centrally located single interstrand cisplatin cross-link resulted in less binding than to the undamaged control DNA. A series of experiments measuring rhRPA binding and concurrent DNA denaturation revealed that rhRPA binds duplex cisplatin-damaged DNA via the generation of single-stranded DNA. Single-strand DNA binding experiments show that rhRPA binds 3-4-fold better to an undamaged 24-base DNA compared with the same substrate containing a single 1,2d(GpG) cisplatin-DNA adduct. These data are consistent with a low affinity interaction of rhRPA with duplex-damaged DNA followed by the generation of single-stranded DNA and then high affinity binding to the undamaged DNA strand.

Cleavage of substrates with mismatched nucleotides by Flap endonuclease-1. Implications for mammalian Okazaki fragment processing

Flap endonuclease-1 (FEN1) is proposed to participate in removal of the initiator RNA of mammalian Okazaki fragments by two pathways. In one pathway, RNase HI removes most of the RNA, leaving a single ribonucleotide adjacent to the DNA. FEN1 removes this ribonucleotide exonucleolytically. In the other pathway, FEN1 removes the entire primer endonucleolytically after displacement of the 5'-end region of the Okazaki fragment. Cleavage would occur beyond the RNA, a short distance into the DNA. The initiator RNA and an adjacent short region of DNA are synthesized by DNA polymerase alpha/primase. Because the fidelity of DNA polymerase alpha is lower than that of the DNA polymerases that complete DNA extension, mismatches occur relatively frequently near the 5'-ends of Okazaki fragments. We have examined the ability of FEN1 to repair such errors. Results show that mismatched bases up to 15 nucleotides from the 5'-end of an annealed DNA strand change the pattern of FEN1 cleavage. Instead of removing terminal nucleotides sequentially, FEN1 appears to cleave a portion of the mismatched strand endonucleolytically. We propose that a mismatch destabilizes the helical structure over a nearby area. This allows FEN1 to cleave more efficiently, facilitating removal of the mismatch. If mismatches were not introduced during synthesis of the Okazaki fragment, helical disruption would not occur, nor would unnecessary degradation of the 5'-end of the fragment.

Structural changes measured by X-ray scattering from human flap endonuclease-1 complexed with Mg2+ and flap DNA substrate

Human flap endonuclease-1 (FEN-1) is a member of the structure-specific endonuclease family and is essential in DNA replication and repair. FEN-1 has specific endonuclease activity for repairing nicked double-stranded DNA substrates that have the 5'-end of the nick expanded into a single-stranded tail, and it is involved in processing Okazaki fragments during DNA replication. Magnesium is a cofactor required for nuclease activity. We used small-angle x-ray scattering to obtain global structural information pertinent to nuclease activity from FEN-1, the D181A mutant, the wild-type FEN-1. 34-mer DNA flap complex, and the D181A.34-mer DNA flap complex. The D181A mutant, which has Asp-181 replaced by Ala, selectively binds to the flap structure, but has lost its cleaving activity. Asp-181 is thought to be involved in Mg2+ binding at the active site (Shen, B., Nolan, J. P., Sklar, L. A., and Park, M. S. (1996) J. Biol. Chem. 271, 9173-9176). Our data indicate that FEN-1 and the D181A mutant each have a radius of gyration of approximately 26 A, and the effect of Mg2+ on the scattering from the proteins alone is insignificant. The 34-mer DNA fragment was constructed such that it readily forms a 5'-flap structure. The formation of the flap conformation of the DNA substrate was evident by both the extrapolated Io scattering and radius of gyration and was supported by NMR spectrum and nuclease assays. In the absence of magnesium, the FEN-1.34-mer DNA flap complex has an Rg value of approximately 34 A, whereas the D181A.34-mer DNA flap complex self-associates, suggesting that a significant protein conformational change occurs by addition of the flap DNA substrate and that Asp-181 is crucial for proper binding of the protein to the DNA substrate. A time course change in the scattering profiles arising from magnesium activation of the FEN-1.34-mer DNA flap complex is consistent with the protein completely releasing the DNA substrate after cleavage.

Characterization of FEN-1 from Xenopus laevis. cDNA cloning and role in DNA metabolism

cDNAs for the Xenopus laevis homologue of the endo/exonuclease FEN-1 (DNase IV) have been cloned using a polymerase chain reaction strategy. Products were obtained from two nonallelic Xenopus genes (xFEN-1a and xFEN-1b) that differ from each other by 4.5% in amino acid sequence. Both are 80% identical to mammalian FEN-1 proteins and 55% identical to the yeast homologues. When expressed in Escherichia coli, the Xenopus enzymes showed flap endonuclease activity, a unique feature of this class of nucleases. In addition, expression from the Xenopus cDNAs complemented the temperature and methyl methanesulfonate sensitivity of a yeast rad27 deletion, which eliminates the endogenous FEN-1 gene product. Antiserum raised against xFEN-1 was used to show that the protein accumulates during the middle and late stages of oogenesis, in parallel with other DNA metabolic activities, and that it is localized to the oocyte nucleus. Flap endonuclease activity was demonstrated in oocyte nuclear extracts, and this was inhibited by the anti-xFEN-1 antiserum. The antiserum did not inhibit the major oocyte 5' --> 3' exonuclease activity. DNA synthesis in oocyte extracts was blocked by the antiserum, and the nature of this inhibition suggests that xFEN-1 may be part of a large complex of replication factors. Chromatographic evidence was obtained for the existence of a complex that forms during DNA synthesis and includes proliferating cell nuclear antigen in addition to xFEN-1. These observations support a critical role for xFEN-1 in DNA replication, but indicate that another enzyme must be responsible for the exonuclease function required for homologous recombination in Xenopus oocytes.

Processing of an HIV replication intermediate by the human DNA replication enzyme FEN1

The role of human FEN1 (flap endonuclease-1), an RTH1 (RAD two homolog-1) class nuclease, in the replication of human immunodeficiency virus (HIV) type 1 has been examined using model substrates. FEN1 is able to endonucleolytically cleave a primer annealed to a template, but with a 5'-unannealed tail. The HIV (+)-strand is synthesized as two discontinuous segments, with the upstream segment displacing the downstream segment to form a central (+)-strand overlap. Given a substrate with the exact HIV nucleotide sequence, FEN1 was able to remove the overlap. After extension of the upstream primer with DNA polymerase epsilon, human DNA ligase I was able to complete the continuous double strand as would occur for an integrated provirus. FEN1 may represent a target for new therapeutic interventions.

Replication protein A stimulates long patch DNA base excision repair

Two pathways for completion of DNA base excision repair (BER) have recently emerged. In one, called short patch BER, only the damaged nucleotide is replaced, whereas in the second, known as long patch BER, the monobasic lesion is removed along with additional downstream nucleotides. Flap endonuclease 1, which preferentially cleaves unannealed 5'-flap structures in DNA, has been shown to play a crucial role in the long patch mode of repair. This nuclease will efficiently release 5'-terminal abasic lesions as part of an intact oligonucleotide when cleavage is combined with strand displacement synthesis. Further gap filling and ligation complete repair. We reconstituted the final steps of long patch base excision repair in vitro using calf DNA polymerase epsilon to provide strand displacement synthesis, human flap endonuclease 1, and human DNA ligase I. Replication protein A is an important constituent of the DNA replication machinery. It also has been shown to interact with an early component of base excision repair: uracil glycosylase. Here we show that human replication protein A greatly stimulates long patch base excision repair.

The DNA replication fork in eukaryotic cells

Replication of the two template strands at eukaryotic cell DNA replication forks is a highly coordinated process that ensures accurate and efficient genome duplication. Biochemical studies, principally of plasmid DNAs containing the Simian Virus 40 origin of DNA replication, and yeast genetic studies have uncovered the fundamental mechanisms of replication fork progression. At least two different DNA polymerases, a single-stranded DNA-binding protein, a clamp-loading complex, and a polymerase clamp combine to replicate DNA. Okazaki fragment synthesis involves a DNA polymerase-switching mechanism, and maturation occurs by the recruitment of specific nucleases, a helicase, and a ligase. The process of DNA replication is also coupled to cell-cycle progression and to DNA repair to maintain genome integrity.

Structure of the DNA repair and replication endonuclease and exonuclease FEN-1: coupling DNA and PCNA binding to FEN-1 activity

Flap endonuclease (FEN-1) removes 5' overhanging flaps in DNA repair and processes the 5' ends of Okazaki fragments in lagging strand DNA synthesis. The crystal structure of Pyrococcus furiosus FEN-1, active-site metal ions, and mutational information indicate interactions for the single- and double-stranded portions of the flap DNA substrate and identify an unusual DNA-binding motif. The enzyme's active-site structure suggests that DNA binding induces FEN-1 to clamp onto the cleavage junction to form the productive complex. The conserved FEN-1 C terminus binds proliferating cell nuclear antigen (PCNA) and positions FEN-1 to act primarily as an exonuclease in DNA replication, in contrast to its endonuclease activity in DNA repair. FEN-1 mutations altering PCNA binding should reduce activity during replication, likely causing DNA repeat expansions as seen in some cancers and genetic diseases.

Human replication protein A preferentially binds cisplatin-damaged duplex DNA in vitro

Fractionation of human cell extracts by cisplatin-DNA affinity chromatography was employed to identify proteins capable of binding cisplatin-damaged DNA. A specific protein-DNA complex, termed DRP-3, was identified in an electrophoretic mobility shift assay (EMSA) using a cisplatin-damaged DNA probe. Using this assay we purified DRP-3 and the final fraction contained proteins of 70, 53, 46, 32, and 14 kDa. On the basis of subunit molecular weights, antibody reactivity, and DNA binding activities, DRP-3 was identified as human replication protein A (hRPA). Therefore, we assessed the binding of recombinant human RPA (rhRPA) to duplex cisplatin-damaged DNA in vitro. Global treatment of a highly purified completely duplex 44-bp DNA with cisplatin resulted in a 10-20-fold increase in rhRPA binding compared to the undamaged control. The stability of the RPA-DNA complexes was assessed, and NaCl and MgCl2 concentrations that completely inhibited rhRPA binding to undamaged DNA had only a minimal effect on binding to duplex platinated DNA. We assessed rhRPA binding to a duplex DNA containing a single site-specific 1,2-d(GpG) cisplatin adduct, and the results revealed a 4-6-fold increase in binding to this DNA substrate compared to an undamaged control DNA of identical sequence. These results are consistent with RPA being involved in the initial recognition of cisplatin-damaged DNA, possibly mediating DNA repair events. Therefore, we assessed how another cisplatin DNA binding protein, HMG-1, affected the ability of rhRPA to bind damaged DNA. Competition binding assays show minimal dissociation of either protein from cisplatin-damaged DNA during the course of the reaction. Simultaneous addition experiments revealed that HMG-1 binding to cisplatin-damaged DNA was minimally affected by rhRPA, while HMG-1 inhibited the damaged-DNA binding activity of rhRPA. These data are consistent with HMG-1 blocking DNA repair and possibly having the capability to enhance the cytotoxic efficacy of the drug cisplatin.

Destabilization of yeast micro- and minisatellite DNA sequences by mutations affecting a nuclease involved in Okazaki fragment processing (rad27) and DNA polymerase delta (pol3-t)

We examined the effects of mutations in the Saccharomyces cerevisiae RAD27 (encoding a nuclease involved in the processing of Okazaki fragments) and POL3 (encoding DNA polymerase delta) genes on the stability of a minisatellite sequence (20-bp repeats) and microsatellites (1- to 8-bp repeat units). Both the rad27 and pol3-t mutations destabilized both classes of repeats, although the types of tract alterations observed in the two mutant strains were different. The tract alterations observed in rad27 strains were primarily additions, and those observed in pol3-t strains were primarily deletions. Measurements of the rates of repetitive tract alterations in strains with both rad27 and pol3-t indicated that the stimulation of microsatellite instability by rad27 was reduced by the effects of the pol3-t mutation. We also found that rad27 and pol3-01 (an allele carrying a mutation in the "proofreading" exonuclease domain of DNA polymerase delta) mutations were synthetically lethal.

Expansions of CAG repeat tracts are frequent in a yeast mutant defective in Okazaki fragment maturation

To understand the causes of CAG repeat tract changes that occur in the passage of human disease alleles, we are studying the effect of replication and repair mutations on CAG repeat tracts embedded in a yeast chromosome. In this report, we examine the effect of a mutation in the RTH1/RAD27 gene encoding a deoxyribonuclease needed for removal of excess nucleotides at the 5'-end of Okazaki fragments. Deletion of the RTH1/RAD27 gene has two effects on CAG tracts. First, the rth1/rad27 mutation destabilizes CAG tracts. Second, although most tract length changes in wild-type yeast cells are tract contractions, approximately half of the changes that occur as a result of the rth1/rad27 mutation are expansions of one or more repeat units. These results support the hypothesis that tract expansions that occur during passage of human disease alleles bearing expanded CAG tracts result from excess DNA synthesis on the lagging strand of replication.

Creation and removal of embedded ribonucleotides in chromosomal DNA during mammalian Okazaki fragment processing

Mammalian RNase HI has been shown to specifically cleave the initiator RNA of Okazaki fragments at the RNA-DNA junction, leaving a single ribonucleotide attached to the 5'-end of the downstream DNA segment. This monoribonucleotide can then be removed by the mammalian 5'- to 3'-exo-/endonuclease, a RAD2 homolog-1 (RTH-1) class nuclease, also known as flap endonuclease-1 (FEN-1). Although FEN-1/RTH-1 nuclease often requires an upstream primer for efficient activity, the presence of an upstream primer is usually inhibitory or neutral for removal of this 5'-monoribonucleotide. Using model Okazaki fragment substrates, we found that DNA ligase I can seal a 5'-monoribonucleotide into DNA. When both ligase and FEN-1/RTH-1 were present simultaneously, some of the 5'-monoribonucleotides were ligated into DNA, while others were released. Thus, a 5'-monoribonucleotide, particularly one that is made resistant to FEN-1/RTH-1-directed cleavage by extension of an inhibitory upstream primer, can be ligated into the chromosome, despite the presence of FEN-1/RTH-1 nuclease. DNA ligase I was able to seal different monoribonucleotides into the DNA for all substrates tested, with an efficiency of 1-13% that of ligating DNA. These embedded monoribonucleotides can be removed by the combined action of RNase HI, cutting on the 5'-side, and FEN-1/RTH-1 nuclease, cleaving on the 3'-side. After FEN-1/RTH-1 action and extension by polymerization, DNA ligase I can join the entirely DNA strands to complete repair.

Synthesis of the mammalian telomere lagging strand in vitro

Using a synthetic telomere DNA template and whole cell extracts, we have identified proteins capable of synthesizing the telomere complementary strand. Synthesis of the complementary strand required a DNA template consisting of 10 repeats of the human telomeric sequence d(TTAGGG) and deoxy- and ribonucleosidetriphosphates and was inhibited by neutralizing antibodies to DNA polymerase alpha. No evidence for RNA-independent synthesis of the lagging strand was observed, suggesting that a stable DNA secondary structure capable of priming the lagging strand is unlikely. Purified DNA polymerase alpha/primase was capable of catalyzing synthesis of the lagging strand with the same requirements as those observed in crude cell extracts. A ladder of products was observed with an interval of six bases, suggesting a unique RNA priming site and site-specific pausing or dissociation of polymerase alpha on the d(TTAGGG)10 template. Removal of the RNA primers was observed upon the addition of purified RNase HI. By varying the input rNTP, the RNA priming site was determined to be opposite the 3' thymidine nucleotide generating a five-base RNA primer with the sequence 5'-AACCC. The addition of UTP did not increase the efficiency of priming and extension, suggesting that the five-base RNA primer is sufficient for extension with dNTPs by DNA polymerase alpha. This represents the first experimental evidence for RNA priming and DNA extension as the mechanism of mammalian telomeric lagging strand replication.

The FEN-1 family of structure-specific nucleases in eukaryotic DNA replication, recombination and repair

Unlike the most well-characterized prokaryotic polymerase, E. coli DNA pol l, none of the eukaryotic polymerases have their own 5' to 3' exonuclease domain for nick translation and Okazaki fragment processing. In eukaryotes, FEN-1 is an endo- and exonuclease that carries out this function independently of the polymerase molecules. Only seven nucleases have been cloned from multicellular eukaryotic cells. Among these, FEN-1 is intriguing because it has complex structural preferences; specifically, it cleaves at branched DNA structures. The cloning of FEN-1 permitted establishment of the first eukaryotic nuclease family, predicting that S. cerevisiae RAD2 (S. pombe Rad13) and its mammalian homolog, XPG, would have similar structural specificity. The FEN-1 nuclease family includes several similar enzymes encoded by bacteriophages. The crystal structures of two enzymes in the FEN-1 nuclease family have been solved and they provide a structural basis for the interesting steric requirements of FEN-1 substrates. Because of their unique structural specificities, FEN-1 and its family members have important roles in DNA replication, repair and, potentially, recombination. Recently, FEN-1 was found to specifically associate with PCNA, explaining some aspects of FEN-1 function during DNA replication and potentially in DNA repair.

A novel mutation avoidance mechanism dependent on S. cerevisiae RAD27 is distinct from DNA mismatch repair

Mutations in the S. cerevisiae RAD27 (also called RTH1 or YKL510) gene result in a strong mutator phenotype. In this study we show that the majority of the resulting mutations have a structure in which sequences ranging from 5-108 bp flanked by direct repeats of 3-12 bp are duplicated. Such mutations have not been previously detected at high frequency in the mutation spectra of mutator strains. Epistasis analysis indicates that RAD27 does not play a major role in MSH2-dependent mismatch repair. Mutations in RAD27 cause increased rates of mitotic crossing over and are lethal in combination with mutations in RAD51 and RAD52. These observations suggest that the majority of replication errors that accumulate in rad27 strains are processed by double-strand break repair, while a smaller percentage are processed by a mutagenic repair pathway. The duplication mutations seen in rad27 mutants occur both in human tumors and as germline mutations in inherited human diseases.

Mechanism of tracking and cleavage of adduct-damaged DNA substrates by the mammalian 5'- to 3'-exonuclease/endonuclease RAD2 homologue 1 or flap endonuclease 1

The mammalian 5'- to 3'-exonuclease/endonuclease, called RAD2 homologue 1 or flap endonuclease 1, has a unique cleavage activity, dependent on specific substrate structure. On a primer-template, in which the primer has an unannealed 5'-tail, endonucleolytic cleavage near the annealing point releases the tail intact. Entering at the 5'-end, the nuclease tracks along the entire tail to the point of cleavage. Genetic analyses suggest that this nuclease removes DNA adducts in vivo (Sommers, C. H., Miller, E. J., Dujon, B., Prakash, S., and Prakash, L. (1995) J. Biol. Chem. 270, 4193-4196). Micrococcal nuclease footprinting shows that after tracking the nuclease protects a region of the tail 25 nucleotides long, adjacent to the cleavage site. Substrates with adducts at specific locations were used to assess the mechanism of RAD2 homologue 1 nuclease tracking and its ability to cleave modified DNA. Either a conventional cis-diamminedichloroplatinum (II) (CDDP) or a bulky CDDP derivative was placed within or beyond the region protected by the nuclease. The nuclease cleaved the tail of both substrates. In contrast, a CDDP adduct just adjacent to the expected cleavage point was inhibitory. A CDDP adduct at the very 5'-end of the tail was also cleaved. The nuclease could remove tails containing adducts on the sugar-phosphate backbone. Apparently, the nuclease is designed to slide over various types of damage on single stranded DNA and then cut past the damaged site.

Calf RTH-1 nuclease can remove the initiator RNAs of Okazaki fragments by endonuclease activity

In eukaryotes, the endonucleolytic activity of the calf RTH-1 class 5'- to 3'-exo/endonuclease can function without RNase H1 to remove initiator RNA from Okazaki fragments. Cleavage requires that the RNA be displaced to form an unannealed single-stranded 5'-tail or flap structure. On substrates with RNA-initiated primers, DNA oligomers that competed with the RNA for template binding simulated strand displacement synthesis from an upstream Okazaki fragment. This allowed cutting of displaced RNA segments by RTH-1 nuclease. Requirements for the reaction also were examined on substrates in which the tail was unannealed because it was intentionally mispaired. On both types of substrate, the nuclease slides over the RNA region from the 5'-end and cleaves at the beginning of the annealed region, irrespective of whether ribo- or deoxyribonucleotides are at the cleavage site. Presence of a triphosphate or a 7-methyl 3'G5'ppp5' G cap structure at the 5'-end of the RNA does not affect cleavage. The previously reported stimulation of the nuclease by an upstream primer was not always observed, suggesting that not every site in the downstream Okazaki fragment is equally susceptible to cleavage during displacement synthesis in vivo. The biological role of the endonuclease activity of RTH-1 nuclease in Okazaki fragment processing is discussed.

Role of calf RTH-1 nuclease in removal of 5'-ribonucleotides during Okazaki fragment processing

The role of the exonucleolytic activity of the calf 5' to 3' exo/endonuclease, a RAD2 homolog 1 (RTH-1) class nuclease, in lagging-strand DNA replication has been examined using model Okazaki fragment substrates. These substrates exemplify the situation in Okazaki fragment processing which occurs after the initiator RNA primer is cleaved off, and released intact, by calf RNase HI, leaving a single ribonucleotide at the 5' end of the RNA-DNA junction. This final RNA is then removed by the calf RTH-1 nuclease [Turchi et al. (1994) Proc. Natl. Acad. Sci. U.S.A. 91, 9803-9807]. The cleavage specificity of calf RTH-1 nuclease for different junction ribonucleotides was compared. These were removed without the usual requirement of calf RTH-1 for an immediately adjacent upstream primer. In most cases, the presence of an upstream DNA or RNA primer, separated from the monoribonucleotide-DNA segment by either a nick or a gap, reduced the efficiency of removal of the monoribonucleotide compared to the removal seen with no upstream primer. Substrates in which the monoribonucleotide-DNA segment had been replaced by an oligomer of the same sequence but consisting entirely of DNA also exhibited upstream primer inhibition. Results with various sequences indicated that the upstream primer is generally inhibitory for ribonucleotide removal but is sometimes neutral. For deoxynucleotide removal it could be stimulatory, neutral, or inhibitory. Possible reasons for the unexpected lack of upstream primer dependence have been explored. The ratio of RNase HI to RTH-1 was also shown to be critical for both enzymes to work together efficiently. These results suggest that regions of upstream primer inhibition within the genome may play a role in determining the mechanism by which mammalian Okazaki fragments are processed.

Cisplatin-DNA binding specificity of calf high-mobility group 1 protein

We have identified a series of proteins with an affinity for cisplatin -damaged DNA using damaged DNA affinity chromatography. We have purified one of these proteins to homogeneity on the basis of a mobility shift assay detecting binding to cisplatin-damaged DNA. The protein was identified as high-mobility group 1 protein (HMG-1) by N-terminal protein sequence analysis. Analysis of a variety of DNA structures revealed that fully duplex DNAs were the best substrates for HMG-1 binding, while partial duplexes were less avidly bound. The decreased levels of binding are attributed to the length of the duplex region of the DNA substrates. A 3-fold increase in binding was observed when a cisplatin-damaged DNA substrate containing a single break in the phosphodiester backbone was joined by DNA ligase. The strict DNA size dependence of binding was also assessed, and a 10-fold increase in binding was observed when the length of the DNA duplex was increased from 44 to 180 base pairs (bp) at the same level of cisplatin damage. HMG-1 binding also was correlated with the degree of cisplatin-DNA damage, suggesting a higher affinity for DNA containing multiple cisplatin adducts. Nuclease degradation of the cisplatin-damaged DNA demonstrated that at the lowest levels of cisplatin damage all of the substrates contained at least one cisplatin adduct. The potential role of HMG-1 in the repair of cisplatin-DNA adducts is discussed.

Calf 5' to 3' exo/endonuclease must slide from a 5' end of the substrate to perform structure-specific cleavage

Calf 5' to 3' exo/endonuclease, the counterpart of the human FEN-1 and yeast RTH-1 nucleases, performs structure-specific cleavage of both RNA and DNA and is implicated in Okazaki fragment processing and DNA repair. The substrate for endonuclease activity is a primer annealed to a template but with a 5' unannealed tail. The results presented here demonstrate that the nuclease must enter the 5' end of the unannealed tail and then slide to the region of hybridization where the cleavage occurs. The presence of bound protein or a primer at any point on the single-stranded tail prevents cleavage. However, biotinylation of a nucleotide at the 5' end or internal to the tail does not prevent cleavage. The sliding process is bidirectional. If the nuclease slides onto the tail, later binding of a primer to the tail traps the nuclease between the primer binding site and the cleavage site, preventing the nuclease from departing from the 5' end. A model for 5' entry, sliding, and cleavage is presented. The possible role of this unusual mechanism in Okazaki fragment processing, DNA repair, and protection of the replication fork from inappropriate endonucleolytic cleavage is presented.

Structure-specific nuclease activity in yeast nucleotide excision repair protein Rad2

Saccharomyces cerevisiae Rad2 protein functions in the incision step of the nucleotide excision repair of DNA damaged by ultraviolet light. Rad2 was previously shown to act endonucleolytically on circular single-stranded M13 DNA and also to have a 5'-->3' exonuclease activity (Habraken, Y., Sung, P., Prakash, L., and Prakash, S. (1993) Nature 366, 365-368; Habraken, Y., Sung, P., Prakash, L., and Prakash, S. (1994) J. Biol. Chem. 269, 31342-31345). Using two different branched DNA structures, pseudo Y and flap, we have determined that Rad2 specifically cleaves the 5'-overhanging single strand in these DNAs. Rad2 nuclease is more active on the flap structure than on the pseudo Y structure. Rad2 also acts on a bubble structure that contains an unpaired region of 14 nucleotides, but with a lower efficiency than on the pseudo Y or flap structure. The incision points occur at and around the single strand-duplex junction in the three classes of DNA structures.

Lagging strand DNA synthesis at the eukaryotic replication fork involves binding and stimulation of FEN-1 by proliferating cell nuclear antigen

The 5'-->3'-exonuclease domain of Escherichia coli DNA polymerase I is required for the completion of lagging strand DNA synthesis, and yet this domain is not present in any of the eukaryotic DNA polymerases. Recently, the gene encoding the functional and evolutionary equivalent of this 5'-->3'-exonuclease domain has been identified. It is called FEN-1 in mouse and human cells and RTH1 in Saccharomyces cerevisiae. This 42-kDa enzyme is required for Okazaki fragment processing. Here we report that FEN-1 physically interacts with proliferating cell nuclear antigen (PCNA), the processivity factor for DNA polymerases delta and epsilon. Through protein-protein interactions, PCNA focuses FEN-1 on branched DNA substrates (flap structures) and on nicked DNA substrates, thereby stimulating its activity 10-50-fold but only if PCNA can functionally assemble as a toroidal trimer around the DNA. This interaction is important in the physical orchestration of lagging strand synthesis and may have implications for how PCNA stimulates other members of the FEN-1 nuclease family in a broad range of DNA metabolic transactions.

Requirement of the yeast RTH1 5' to 3' exonuclease for the stability of simple repetitive DNA

Simple repetitive DNA sequences are unstable in human colorectal cancers and a variety of other cancers. Mutations in the DNA mismatch repair genes MSH2, MLH1, and PMS1 result in elevated rates of spontaneous mutation and cause a marked increase in the instability of simple repeats. Compared with the wild type, a null mutation in the yeast RTH1 gene, which encodes a 5' to 3' exonuclease, was shown to increase the rate of instability of simple repetitive DNA by as much as 280 times and to increase the spontaneous mutation rate by 30 times. Epistasis analyses were consistent with the hypothesis that this RTH1-encoded nuclease has a role in the MSH2-MLH-1-PMS1 mismatch repair pathway.

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.

Conditional lethality of null mutations in RTH1 that encodes the yeast counterpart of a mammalian 5'- to 3'-exonuclease required for lagging strand DNA synthesis in reconstituted systems

A 5'- to 3'-exonuclease of about 45 kDa has been purified from various mammalian sources and shown to be required for the completion of lagging strand synthesis in reconstituted DNA replication systems. RTH1 encodes the yeast Saccharomyces cerevisiae counterpart of the mammalian enzyme. To determine the in vivo biological role of RTH1-encoded 5'- to 3'-exonuclease, we have examined the effects of an rth1 delta mutation on various cellular processes. rth1 delta mutants grow poorly at 30 degrees C, and a cessation in growth occurs upon transfer of the mutant to 37 degrees C. At the restrictive temperature, the rth1 delta mutant exhibits a terminal cell cycle morphology similar to that of mutants defective in DNA replication, and levels of spontaneous mitotic recombination are elevated in the rth1 delta mutant even at the permissive temperature. The rth1 delta mutation does not affect UV or gamma-ray sensitivity but enhances sensitivity to the alkylating agent methyl methanesulfonate. The role of RTH1 in DNA replication and in repair of alkylation damage is discussed.

Sequence of human FEN-1, a structure-specific endonuclease, and chromosomal localization of the gene (FEN1) in mouse and human

We recently purified and cloned the gene for a DNA structure-specific endonuclease, FEN-1, from murine cells. The murine protein recognizes 5' DNA flap structures that have been proposed in DNA replication, repair, and recombination. Here, we report the sequence of the human FEN1 gene. The translated sequence is identical to peptide sequence obtained from maturation factor-1, which is 1 of the 10 essential proteins for cell-free DNA replication. The human protein has the same structure-specific DNA endonuclease activity as the murine protein. Two human chromosomal hybridization signals, 11q12 and 1p22.2, were observed by FISH analysis using human genomic clones homologous to the mouse Fen-1 gene. The localization on human 11q12 was confirmed using radiation-reduced hybrids. The mouse Fen-1 gene is assigned to chromosome 19 based on somatic cell hybrids. The significance of these FEN1 gene localizations in human and mouse is discussed.