Dna2p helicase/nuclease is a tracking protein, like FEN1, for flap cleavage during Okazaki fragment maturation

During cellular DNA replication the lagging strand is generated as discontinuous segments called Okazaki fragments. Each contains an initiator RNA primer that is removed prior to joining of the strands. Primer removal in eukaryotes requires displacement of the primer into a flap that is cleaved off by flap endonuclease 1 (FEN1). FEN1 employs a unique tracking mechanism that requires the recognition of the free 5' terminus and then movement to the base of the flap for cleavage. Abnormally long flaps are coated by replication protein A (RPA), inhibiting FEN1 cleavage. A second nuclease, Dna2p, is needed to cleave an RPA-coated flap producing a short RPA-free flap, favored by FEN1. Here we show that Dna2p is also a tracking protein. Annealed primers or conjugated biotin-streptavidin complex block Dna2p entry and movement. Single-stranded binding protein-coated flaps inhibit Dna2p cleavage. Like FEN1, Dna2p can track over substrates with a non-Watson Crick base, such as a biotin, or a missing base within a chain. Unlike FEN1, Dna2p shows evidence of a "threading-like" mechanism that does not support tracking over a branched substrate. We propose that the two nucleases both track, Dna2p first and then FEN1, to remove initiator RNA via long flap intermediates.     

On the roles of Saccharomyces cerevisiae Dna2p and Flap endonuclease 1 in Okazaki fragment processing

Short DNA segments designated Okazaki fragments are intermediates in eukaryotic DNA replication. Each contains an initiator RNA/DNA primer (iRNA/DNA), which is converted into a 5'-flap and then removed prior to fragment joining. In one model for this process, the flap endonuclease 1 (FEN1) removes the iRNA. In the other, the single-stranded binding protein, replication protein A (RPA), coats the flap, inhibits FEN1, but stimulates cleavage by the Dna2p helicase/nuclease. RPA dissociates from the resultant short flap, allowing FEN1 cleavage. To determine the most likely process, we analyzed cleavage of short and long 5'-flaps. FEN1 cleaves 10-nucleotide fixed or equilibrating flaps in an efficient reaction, insensitive to even high levels of RPA or Dna2p. On 30-nucleotide fixed or equilibrating flaps, RPA partially inhibits FEN1. CTG flaps can form foldback structures and were inhibitory to both nucleases, however, addition of a dT(12) to the 5'-end of a CTG flap allowed Dna2p cleavage. The presence of high Dna2p activity, under reaction conditions favoring helicase activity, substantially stimulated FEN1 cleavage of tailed-foldback flaps and also 30-nucleotide unstructured flaps. Our results suggest Dna2p is not used for processing of most flaps. However, Dna2p has a role in a pathway for processing structured flaps, in which it aids FEN1 using both its nuclease and helicase activities.     

An alternative pathway for Okazaki fragment processing: resolution of fold-back flaps by Pif1 helicase

Two pathways have been proposed for eukaryotic Okazaki fragment RNA primer removal. Results presented here provide evidence for an alternative pathway. Primer extension by DNA polymerase δ (pol δ) displaces the downstream fragment into an RNA-initiated flap. Most flaps are cleaved by flap endonuclease 1 (FEN1) while short, and the remaining nicks joined in the first pathway. A small fraction escapes immediate FEN1 cleavage and is further lengthened by Pif1 helicase. Long flaps are bound by replication protein A (RPA), which inhibits FEN1. In the second pathway, Dna2 nuclease cleaves an RPA-bound flap and displaces RPA, leaving a short flap for FEN1. Pif1 flap lengthening creates a requirement for Dna2. This relationship should not have evolved unless Pif1 had an important role in fragment processing. In this study, biochemical reconstitution experiments were used to gain insight into this role. Pif1 did not promote synthesis through GC-rich sequences, which impede strand displacement. Pif1 was also unable to open fold-back flaps that are immune to cleavage by either FEN1 or Dna2 and cannot be bound by RPA. However, Pif1 working with pol δ readily unwound a full-length Okazaki fragment initiated by a fold-back flap. Additionally, a fold-back in the template slowed pol δ synthesis, so that the fragment could be removed before ligation to the lagging strand. These results suggest an alternative pathway in which Pif1 removes Okazaki fragments initiated by fold-back flaps in vivo.     

Flap endonuclease disengages Dna2 helicase/nuclease from Okazaki fragment flaps

Okazaki fragments contain an initiator RNA/DNA primer that must be removed before the fragments are joined. In eukaryotes, the primer region is raised into a flap by the strand displacement activity of DNA polymerase delta. The Dna2 helicase/nuclease and then flap endonuclease 1 (FEN1) are proposed to act sequentially in flap removal. Dna2 and FEN1 both employ a tracking mechanism to enter the flap 5' end and move toward the base for cleavage. In the current model, Dna2 must enter first, but FEN1 makes the final cut at the flap base, raising the issue of how FEN1 passes the Dna2. To address this, nuclease-inactive Dna2 was incubated with a DNA flap substrate and found to bind with high affinity. FEN1 was then added, and surprisingly, there was little inhibition of FEN1 cleavage activity. FEN1 was later shown, by gel shift analysis, to remove the wild type Dna2 from the flap. RNA can be cleaved by FEN1 but not by Dna2. Pre-bound wild type Dna2 was shown to bind an RNA flap but not inhibit subsequent FEN1 cleavage. These results indicate that there is a novel interaction between the two proteins in which FEN1 disengages the Dna2 tracking mechanism. This interaction is consistent with the idea that the two proteins have evolved a special ability to cooperate in Okazaki fragment processing.     

Pif1 helicase directs eukaryotic Okazaki fragments toward the two-nuclease cleavage pathway for primer removal

Eukaryotic Okazaki fragment maturation requires complete removal of the initiating RNA primer before ligation occurs. Polymerase delta (Pol delta) extends the upstream Okazaki fragment and displaces the 5'-end of the downstream primer into a single nucleotide flap, which is removed by FEN1 nuclease cleavage. This process is repeated until all RNA is removed. However, a small fraction of flaps escapes cleavage and grows long enough to be coated with RPA and requires the consecutive action of the Dna2 and FEN1 nucleases for processing. Here we tested whether RPA inhibits FEN1 cleavage of long flaps as proposed. Surprisingly, we determined that RPA binding to long flaps made dynamically by polymerase delta only slightly inhibited FEN1 cleavage, apparently obviating the need for Dna2. Therefore, we asked whether other relevant proteins promote long flap cleavage via the Dna2 pathway. The Pif1 helicase, implicated in Okazaki maturation from genetic studies, improved flap displacement and increased RPA inhibition of long flap cleavage by FEN1. These results suggest that Pif1 accelerates long flap growth, allowing RPA to bind before FEN1 can act, thereby inhibiting FEN1 cleavage. Therefore, Pif1 directs long flaps toward the two-nuclease pathway, requiring Dna2 cleavage for primer removal.     

Reconstituted Okazaki fragment processing indicates two pathways of primer removal

Eukaryotic Okazaki fragments are initiated by an RNA/DNA primer and extended by DNA polymerase delta (pol delta) and the replication clamp proliferating cell nuclear antigen (PCNA). Joining of the fragments by DNA ligase I to generate the continuous double-stranded DNA requires complete removal of the RNA/DNA primer. Pol delta extends the upstream Okazaki fragment and displaces the downstream RNA/DNA primer into a flap removed by nuclease cleavage. One proposed pathway for flap removal involves pol delta displacement of long flaps, coating of those flaps by replication protein A (RPA), and sequential cleavage of the flap by Dna2 nuclease followed by flap endonuclease 1 (FEN1). A second pathway involves reiterative single nucleotide or short oligonucleotide displacement by pol delta and cleavage by FEN1. We measured the length of FEN1 cleavage products on flaps strand-displaced by pol delta in an oligonucleotide system reconstituted with Saccharomyces cerevisiae proteins. Results showed that in the presence of PCNA and FEN1, pol delta displacement synthesis favors formation and cleavage of primarily short flaps, up to eight nucleotides in length; still, a portion of flaps grows to 20-30 nucleotides. The proportion of long flaps can be altered by mutations in the relevant proteins, sequence changes in the DNA, and reaction conditions. These results suggest that FEN1 is sufficient to remove a majority of Okazaki fragment primers. However, some flaps become long and require the two-nuclease pathway. It appears that both pathways, operating in parallel, are required for processing of all flaps.     

The Protein Components and Mechanism of Eukaryotic Okazaki Fragment Maturation

ABSTRACT

An initiator RNA (iRNA) is required to prime cellular DNA synthesis. The structure of double-stranded DNA allows the synthesis of one strand to be continuous but the other must be generated discontinuously. Frequent priming of the discontinuous strand results in the formation of many small segments, designated Okazaki fragments. These short pieces need to be processed and joined to form an intact DNA strand. Our knowledge of the mechanism of iRNA removal is still evolving. Early reconstituted systems suggesting that the removal of iRNA requires sequential action of RNase H and flap endonuclease 1 (FEN1) led to the RNase H/FEN1 model. However, genetic analyses implied that Dna2p, an essential helicase/nuclease, is required. Subsequent biochemical studies suggested sequential action of RPA, Dna2p, and FEN1 for iRNA removal, leading to the second model, the Dna2p/RPA/FEN1 model. Studies of strand-displacement synthesis by polymerase δ indicated that in a reconstituted system, FEN1 could act as soon as short flaps are created, giving rise to a third model, the FEN1-only model. Each of the three pathways is supported by different genetic and biochemical results. Properties of the major protein components in this process will be discussed, and the validity of each model as a true representation of Okazaki fragment processing will be critically evaluated in this review.     

Biochemical analyses indicate that binding and cleavage specificities define the ordered processing of human Okazaki fragments by Dna2 and FEN1

In eukaryotic Okazaki fragment processing, the RNA primer is displaced into a single-stranded flap prior to removal. Evidence suggests that some flaps become long before they are cleaved, and that this cleavage involves the sequential action of two nucleases. Strand displacement characteristics of the polymerase show that a short gap precedes the flap during synthesis. Using biochemical techniques, binding and cleavage assays presented here indicate that when the flap is ～ 30 nt long the nuclease Dna2 can bind with high affinity to the flap and downstream double strand and begin cleavage. When the polymerase idles or dissociates the Dna2 can reorient for additional contacts with the upstream primer region, allowing the nuclease to remain stably bound as the flap is further shortened. The DNA can then equilibrate to a double flap that can bind Dna2 and flap endonuclease (FEN1) simultaneously. When Dna2 shortens the flap even more, FEN1 can displace the Dna2 and cleave at the flap base to make a nick for ligation.     

The protein components and mechanism of eukaryotic Okazaki fragment maturation

An initiator RNA (iRNA) is required to prime cellular DNA synthesis. The structure of double-stranded DNA allows the synthesis of one strand to be continuous but the other must be generated discontinuously. Frequent priming of the discontinuous strand results in the formation of many small segments, designated Okazaki fragments. These short pieces need to be processed and joined to form an intact DNA strand. Our knowledge of the mechanism of iRNA removal is still evolving. Early reconstituted systems suggesting that the removal of iRNA requires sequential action of RNase H and flap endonuclease 1 (FEN1) led to the RNase H/FEN1 model. However, genetic analyses implied that Dna2p, an essential helicase/nuclease, is required. Subsequent biochemical studies suggested sequential action of RPA, Dna2p, and FEN1 for iRNA removal, leading to the second model, the Dna2p/RPA/FEN1 model. Studies of strand-displacement synthesis by polymerase delta indicated that in a reconstituted system, FEN1 could act as soon as short flaps are created, giving rise to a third model, the FEN1-only model. Each of the three pathways is supported by different genetic and biochemical results. Properties of the major protein components in this process will be discussed, and the validity of each model as a true representation of Okazaki fragment processing will be critically evaluated in this review.     

Components of the Secondary Pathway Stimulate the Primary Pathway of Eukaryotic Okazaki Fragment Processing

Reconstitution of eukaryotic Okazaki fragment processing implicates both one- and two-nuclease pathways for processing flap intermediates. In most cases, FEN1 (flap endonuclease 1) is able to efficiently cleave short flaps as they form. However, flaps escaping cleavage bind replication protein A (RPA) inhibiting FEN1. The flaps must then be cleaved by Dna2 nuclease/helicase before FEN1 can act. Pif1 helicase aids creation of long flaps. The pathways were considered connected only in that the products of Dna2 cleavage are substrates for FEN1. However, results presented here show that Dna2, Pif1, and RPA, the unique proteins of the two-nuclease pathway from Saccharomyces cerevisiae, all stimulate FEN1 acting in the one-nuclease pathway. Stimulation is observed on RNA flaps representing the initial displacement and on short DNA flaps, subsequently displaced. Neither the RNA nor the short DNA flaps can bind the two-nuclease pathway proteins. Instead, direct interactions between FEN1 and the two-nuclease pathway proteins have been detected. These results suggest that the proteins are either part of a complex or interact successively with FEN1 because the level of stimulation would be similar either way. Proteins bound to FEN1 could be tethered to the flap base by the interaction of FEN1 with PCNA, potentially improving their availability when flaps become long. These findings also support a model in which cleavage by FEN1 alone is the preferred pathway, with the first opportunity to complete cleavage, and is stimulated by components of the backup pathway.     

Interaction and stimulation of human FEN-1 nuclease activities by heterogeneous nuclear ribonucleoprotein A1 in alpha-segment processing during Okazaki fragment maturation

High-fidelity DNA replication depends on both accurate incorporation of nucleotides in the newly synthesized strand and the maturation of Okazaki fragments. In eukaryotic cells, the latter is accomplished by a series of coordinated actions of a set of structure-specific nucleases, which, with the assistance of accessory proteins, recognize branched RNA/DNA configurations. In the current model of Okazaki fragment maturation, displacement of a 27-nucleotide or longer flap is envisioned to attract replication protein A (RPA), which inhibits flap endonuclease-1 (FEN-1) but stimulates Dna2 nuclease for cleavage. Dna2 cleavage generates a short flap of 5-7 nucleotides, which resists binding by RPA and further cleavage by Dna2. FEN-1 then removes the remaining flap to produce a suitable substrate for ligation. However, FEN-1 is not efficient in cleaving the short flap, and we therefore set out to identify cellular factors that might regulate FEN-1 activity. Through co-immunoprecipitation experiments, we have isolated heterogeneous nuclear ribonucleoprotein A1 (hnRNP A1), which forms a direct complex with FEN-1 and stimulates its enzymatic activities. The stimulation by hnRNP A1 is most dramatic using DNA substrates with short flaps. With longer flap substrates the hnRNP A1 effect is more modest and is suppressed by the addition of RPA. A model is provided to explain the possible in vivo role of this interaction and activity in Okazaki fragment maturation.     

Pif1 Helicase Lengthens Some Okazaki Fragment Flaps Necessitating Dna2 Nuclease/Helicase Action in the Two-nuclease Processing Pathway

We have developed a system to reconstitute all of the proposed steps of Okazaki fragment processing using purified yeast proteins and model substrates. DNA polymerase δ was shown to extend an upstream fragment to displace a downstream fragment into a flap. In most cases, the flap was removed by flap endonuclease 1 (FEN1), in a reaction required to remove initiator RNA in vivo. The nick left after flap removal could be sealed by DNA ligase I to complete fragment joining. An alternative pathway involving FEN1 and the nuclease/helicase Dna2 has been proposed for flaps that become long enough to bind replication protein A (RPA). RPA binding can inhibit FEN1, but Dna2 can shorten RPA-bound flaps so that RPA dissociates. Recent reconstitution results indicated that Pif1 helicase, a known component of fragment processing, accelerated flap displacement, allowing the inhibitory action of RPA. In results presented here, Pif1 promoted DNA polymerase δ to displace strands that achieve a length to bind RPA, but also to be Dna2 substrates. Significantly, RPA binding to long flaps inhibited the formation of the final ligation products in the reconstituted system without Dna2. However, Dna2 reversed that inhibition to restore efficient ligation. These results suggest that the two-nuclease pathway is employed in cells to process long flap intermediates promoted by Pif1.Eukaryotic cellular DNA is replicated semi-conservatively in the 5′ to 3′ direction. A leading strand is synthesized by DNA polymerase ϵ in a continuous manner in the direction of opening of the replication fork (1, 2). A lagging strand is synthesized by DNA polymerase δ (pol δ)³ in the opposite direction in a discontinuous manner, producing segments called Okazaki fragments (3). These stretches of ∼150 nucleotides (nt) must be joined together to create the continuous daughter strand. DNA polymerase α/primase (pol α) initiates each fragment by synthesizing an RNA/DNA primer consisting of ∼1-nt of RNA and ∼10–20 nt of DNA (4). The sliding clamp proliferating cell nuclear antigen (PCNA) is loaded on the DNA by replication factor C (RFC). pol δ then complexes with PCNA and extends the primer. When pol δ reaches the 5′-end of the downstream Okazaki fragment, it displaces the end into a flap while continuing synthesis, a process known as strand displacement (5, 6). These flap intermediates are cleaved by nucleases to produce a nick for DNA ligase I (LigI) to seal, completing the DNA strand.In one proposed mechanism for flap processing, the only required nuclease is flap endonuclease 1 (FEN1). pol δ displaces relatively short flaps, which are cleaved by FEN1 as they are created, leaving a nick for LigI (7–9). FEN1 binds at the 5′-end of the flap and tracks down the flap cleaving only at the base (5, 10, 11). Because pol δ favors the displacement of RNA-DNA hybrids over DNA-DNA hybrids, strand displacement generally is limited to that of the initiator RNA of an Okazaki fragment (12). In addition, the tightly coordinated action of pol δ and FEN1 also tends to keep flaps short. However, biochemical reconstitution studies demonstrate that some flaps can become long (13, 14). Once these flaps reach ∼30 nt, they can be bound by the eukaryotic single strand binding protein replication protein A (RPA) (15). Binding by RPA to a flap substrate inhibits cleavage by FEN1 (16). The RPA-bound flap would then require another mechanism for proper processing.This second mechanism is proposed to utilize Dna2 (16) in addition to FEN1. Dna2 is both a 5′-3′ helicase and an endonuclease (17, 18). Like FEN1, Dna2 recognizes 5′-flap structures, binding at the 5′-end of the flap and tracking downward toward the base (19, 20). Unlike FEN1, Dna2 cleaves the flap multiple times but not all the way to the base, such that a short flap remains (20). RPA binding to a flap has been shown to stimulate Dna2 cleavage (16). Therefore, if a flap becomes long enough to bind RPA, Dna2 binds and cleaves it to a length of 5–10 nucleotides from which RPA dissociates (21). FEN1 can then enter the flap, displace the Dna2, and then cleave at the base to make the nick for ligation (16, 18, 22). The need for this mechanism may be one reason why DNA2 is an essential gene in Saccharomyces cerevisiae (23, 24). It has been proposed that, in the absence of Dna2, flaps that become long enough to bind RPA cannot be properly processed, leading to genomic instability and cell death (23).In reconstitution of Okazaki fragment processing with purified proteins, even though some flaps became long enough to bind RPA, FEN1 was very effective at cleaving essentially all of the generated flaps (13, 14). Evidently, FEN1 could engage the flaps before binding of RPA. However, these reconstitution assays did not include the 5′-3′ helicase Pif1 (25, 26). Pif1 is involved in telomeric and mitochondrial DNA maintenance (26) and was first implicated in Okazaki fragment processing from genetic studies in S. cerevisiae. Deletion of PIF1 rescued the lethality of dna2Δ, although the double mutant was still temperature-sensitive (27). The authors of this report proposed that Pif1 creates a need for Dna2 by promoting longer flaps. Further supporting this conclusion, deletion of POL32, which encodes the subunit of pol δ that interacts with PCNA, rescued the temperature sensitivity of the dna2Δpif1Δ double mutant (12, 27). Importantly, pol δ exhibited reduced strand displacement activity when POL32 was deleted (12, 28, 29). The combination of pif1Δ and pol32Δ is believed to create a situation in which virtually no long flaps are formed, eliminating the requirement for Dna2 flap cleavage (27).We recently performed reconstitution assays showing that Pif1 can assist in the creation of long flaps. Inclusion of Pif1, in the absence of RPA, increased the proportion of flaps that lengthened to ∼28–32 nt before FEN1 cleavage (14). With the addition of RPA, the appearance of these long flap cleavage products was suppressed. Evidently, Pif1 promoted such rapid flap lengthening that RPA bound some flaps before FEN1 and inhibited cleavage. The RPA-bound flaps would presumably require cleavage by Dna2 for proper processing.Only a small fraction of flaps became long with Pif1. However, there are hundreds of thousands of Okazaki fragments processed per replication cycle (30). Therefore, thousands of flaps are expected to be lengthened by Pif1 in vivo, a number significant enough that improper processing of such flaps could lead to cell death.Our goal here was to determine whether Pif1 can influence the flow of Okazaki fragments through the two proposed pathways. We first questioned whether Pif1 stimulates strand displacement synthesis by pol δ. Next, we asked whether Pif1 lengthens short flaps so that Dna2 can bind and cleave. Finally, we used a complete reconstitution system to determine whether Pif1 promotes creation of RPA-bound flaps that require cleavage by both Dna2 and FEN1 before they can be ligated. Our results suggest that Pif1 promotes the two-nuclease pathway, and reveal the mechanisms involved.     

The Saccharomyces cerevisiae Dna2 can function as a sole nuclease in the processing of Okazaki fragments in DNA replication

During DNA replication, synthesis of the lagging strand occurs in stretches termed Okazaki fragments. Before adjacent fragments are ligated, any flaps resulting from the displacement of the 5′ DNA end of the Okazaki fragment must be cleaved. Previously, Dna2 was implicated to function upstream of flap endonuclease 1 (Fen1 or Rad27) in the processing of long flaps bound by the replication protein A (RPA). Here we show that Dna2 efficiently cleaves long DNA flaps exactly at or directly adjacent to the base. A fraction of the flaps cleaved by Dna2 can be immediately ligated. When coupled with DNA replication, the flap processing activity of Dna2 leads to a nearly complete Okazaki fragment maturation at sub-nanomolar Dna2 concentrations. Our results indicate that a subsequent nucleolytic activity of Fen1 is not required in most cases. In contrast Dna2 is completely incapable to cleave short flaps. We show that also Dna2, like Fen1, interacts with proliferating cell nuclear antigen (PCNA). We propose a model where Dna2 alone is responsible for cleaving of RPA-bound long flaps, while Fen1 or exonuclease 1 (Exo1) cleave short flaps. Our results argue that Dna2 can function in a separate, rather than in a Fen1-dependent pathway.     

Acetylation of Dna2 Endonuclease/Helicase and Flap Endonuclease 1 by p300 Promotes DNA Stability by Creating Long Flap Intermediates

Flap endonuclease 1 (FEN1) and Dna2 endonuclease/helicase (Dna2) sequentially coordinate their nuclease activities for efficient resolution of flap structures that are created during the maturation of Okazaki fragments and repair of DNA damage. Acetylation of FEN1 by p300 inhibits its endonuclease activity, impairing flap cleavage, a seemingly undesirable effect. We now show that p300 also acetylates Dna2, stimulating its 5′–3′ endonuclease, the 5′–3′ helicase, and DNA-dependent ATPase activities. Furthermore, acetylated Dna2 binds its DNA substrates with higher affinity. Differential regulation of the activities of the two endonucleases by p300 indicates a mechanism in which the acetylase promotes formation of longer flaps in the cell at the same time as ensuring correct processing. Intentional formation of longer flaps mediated by p300 in an active chromatin environment would increase the resynthesis patch size, providing increased opportunity for incorrect nucleotide removal during DNA replication and damaged nucleotide removal during DNA repair. For example, altering the ratio between short and long flap Okazaki fragment processing would be a mechanism for better correction of the error-prone synthesis catalyzed by DNA polymerase α.     

Use of Modified Flap Structures for Study of Base Excision Repair Proteins

To investigate interactions between proteins participating in the long-patch pathway of base excision repair (BER), DNA duplexes with flap strand containing modifications in sugar phosphate backbone within the flap-forming oligonucleotides were designed. When the flap-forming oligonucleotide consisted of two sequences bridged by a decanediol linker located in the flap strand near the branch point, the efficiency and position of cleavage by flap endonuclease 1 (FEN1) differed from those for natural flap. The cleavage rate of chimeric structure by FEN1 was lower than that of a normal substrate. When we introduced the second modification in the flap-forming oligonucleotide, the cleavage rate decreased significantly. To estimate efficiency of recognition and processing of the chimeric structures by BER proteins, we studied the rate of DNA synthesis by DNA polymerase beta (Pol beta) and the rate of nucleotide excision at the 3'-end of the initiating primer by apurinic/apyrimidinic endonuclease 1 (APE1) compared with those for the natural DNA duplexes. Efficiency of strand-displacement DNA synthesis catalyzed by Pol beta was shown to be higher for flap structures containing non-nucleotide linkers. The chimeric structures were processed by the 3'-exonuclease activity of APE1 with efficiency lower than that for a normal flap structure. Thus, DNA duplexes with modifications in sugar phosphate backbone can be used to mimic intermediates of the long-patch pathway of BER in reconstituted systems containing FEN1. Based on chimeric and natural oligonucleotides, photoreactive DNA structures were designed. The photoreactive dCMP moiety was introduced into the 3'-end of DNA primer via the activity of Pol beta. The photoreactive DNA duplexes--3'-recessed DNA, nicked DNA, and flap structures containing natural and chimeric oligonucleotides--were used for photoaffinity labeling of BER proteins.     

Mechanisms by which Bloom protein can disrupt recombination intermediates of Okazaki fragment maturation

Bloom syndrome is a familial genetic disorder associated with sunlight sensitivity and a high predisposition to cancers. The mutated gene, Bloom protein (BLM), encodes a DNA helicase that functions in genome maintenance via roles in recombination repair and resolution of recombination structures. We designed substrates representing illegitimate recombination intermediates formed when a displaced DNA flap generated during maturation of Okazaki fragments escapes cleavage by flap endonuclease-1 and anneals to a complementary ectopic DNA site. Results show that displaced, replication protein A (RPA)-coated flaps could readily bind and ligate at the complementary site to initiate recombination. RPA also displayed a strand-annealing activity that hastens the rate of recombination intermediate formation. BLM helicase activity could directly disrupt annealing at the ectopic site and promote flap endonuclease-1 cleavage. Additionally, BLM has its own strand-annealing and strand-exchange activities. RPA inhibited the BLM strand-annealing activity, thereby promoting helicase activity and complex dissolution. BLM strand exchange could readily dissociate invading flaps, e.g. in a D-loop, if the exchange step did not involve annealing of RPA-coated strands. Use of ATP to activate the helicase function did not aid flap displacement by exchange, suggesting that this is a helicase-independent mechanism of complex dissociation. When RPA could bind, it displayed its own strand-exchange activity. We interpret these results to explain how BLM is well equipped to deal with alternative recombination intermediate structures.     

Mechanism whereby proliferating cell nuclear antigen stimulates flap endonuclease 1

Human flap endonuclease 1 (FEN1), an essential DNA replication protein, cleaves substrates with unannealed 5'-tails. FEN1 apparently tracks along the flap from the 5'-end to the cleavage site. Proliferating cell nuclear antigen (PCNA) stimulates FEN1 cleavage 5-50-fold. To determine whether tracking, binding, or cleavage is enhanced by PCNA, we tested a variety of flap substrates. Similar levels of PCNA stimulation occur on both a cleavage-sensitive nicked substrate and a less sensitive gapped substrate. PCNA stimulates FEN1 irrespective of the flap length. Stimulation occurs on a pseudo-Y substrate that exhibits upstream primer-independent cleavage. A pseudo-Y substrate with a sequence requiring an upstream primer for cleavage was not activated by PCNA, suggesting that PCNA does not compensate for substrate features that inhibit cleavage. A biotin.streptavidin conjugation at the 5'-end of a flap structure prevents FEN1 loading. The addition of PCNA does not restore FEN1 activity. These results indicate that PCNA does not direct FEN1 to the cleavage site from solution. Kinetic analyses reveal that PCNA can lower the K(m) for FEN1 by 11-12-fold. Overall, our results indicate that after FEN1 tracks to the cleavage site, PCNA enhances FEN1 binding stability, allowing for greater cleavage efficiency.