Helicase and nuclease activities of hyperthermophile Pyrococcus horikoshii Dna2 inhibited by substrates with RNA segments at 5'-end

Specificity of end resection pathways for double-strand break regions containing ribonucleotides and base lesions

DNA double-strand break repair by homologous recombination begins with nucleolytic resection of the 5’ DNA strand at the break ends. Long-range resection is catalyzed by EXO1 and BLM-DNA2, which likely have to navigate through ribonucleotides and damaged bases. Here, we show that a short stretch of ribonucleotides at the 5’ terminus stimulates resection by EXO1. Ribonucleotides within a 5’ flap are resistant to cleavage by DNA2, and extended RNA:DNA hybrids inhibit both strand separation by BLM and resection by EXO1. Moreover, 8-oxo-guanine impedes EXO1 but enhances resection by BLM-DNA2, and an apurinic/apyrimidinic site stimulates resection by BLM-DNA2 and DNA strand unwinding by BLM. Accordingly, depletion of OGG1 or APE1 leads to greater dependence of DNA resection on DNA2. Importantly, RNase H2A deficiency impairs resection overall, which we attribute to the accumulation of long RNA:DNA hybrids at DNA ends. Our results help explain why eukaryotic cells possess multiple resection nucleases.

DNA double-strand break repair by homologous recombination initiates with nucleolytic resection of the 5’ DNA strand at the break ends. Here, the authors reveal that the lesion context influences the action and efficiency of the long range resection factors EXO1 and BLM-DNA2.

Genome-wide identification of SF1 and SF2 helicases from archaea

Archaea microorganisms have long been used as model organisms for the study of protein molecular machines. Archaeal proteins are particularly appealing to study since archaea, even though prokaryotic, possess eukaryotic-like cellular processes. Super Family I (SF1) and Super Family II (SF2) helicase families have been studied in many model organisms, little is known about their presence and distribution in archaea. We performed an exhaustive search of homologs of SF1 and SF2 helicase proteins in 95 complete archaeal genomes. In the present study, we identified the complete sets of SF1 and SF2 helicases in archaea. Comparative analysis between archaea, human and the bacteria E. coli SF1 and SF2 helicases, resulted in the identification of seven helicase families conserved among representatives of the domains of life. This analysis suggests that these helicase families are highly conserved throughout evolution. We highlight the conserved motifs of each family and characteristic domains of the detected families. Distribution of SF1/SF2 families show that Ski2-like, Lhr, Sfth and Rad3-like helicases are ubiquitous among archaeal genomes while the other families are specific to certain archaeal groups. We also report the presence of a novel SF2 helicase specific to archaea domain named Archaea Specific Helicase (ASH). Phylogenetic analysis indicated that ASH has evolved in Euryarchaeota and is evolutionary related to the Ski2-like family with specific characteristic domains. Our study provides the first exhaustive analysis of SF1 and SF2 helicases from archaea. It expands the variety of SF1 and SF2 archaeal helicases known to exist to date and provides a starting point for new biochemical and genetic studies needed to validate their biological functions.

Global phylogenomic analysis disentangles the complex evolutionary history of DNA replication in archaea

The archaeal machinery responsible for DNA replication is largely homologous to that of eukaryotes and is clearly distinct from its bacterial counterpart. Moreover, it shows high diversity in the various archaeal lineages, including different sets of components, heterogeneous taxonomic distribution, and a large number of additional copies that are sometimes highly divergent. This has made the evolutionary history of this cellular system particularly challenging to dissect. Here, we have carried out an exhaustive identification of homologs of all major replication components in over 140 complete archaeal genomes. Phylogenomic analysis allowed assigning them to either a conserved and probably essential core of replication components that were mainly vertically inherited, or to a variable and highly divergent shell of extra copies that have likely arisen from integrative elements. This suggests that replication proteins are frequently exchanged between extrachromosomal elements and cellular genomes. Our study allowed clarifying the history that shaped this key cellular process (ancestral components, horizontal gene transfers, and gene losses), providing important evolutionary and functional information. Finally, our precise identification of core components permitted to show that the phylogenetic signal carried by DNA replication is highly consistent with that harbored by two other key informational machineries (translation and transcription), strengthening the existence of a robust organismal tree for the Archaea.

Structural studies of DNA end detection and resection in homologous recombination

DNA double-strand breaks are repaired by two major pathways, homologous recombination or nonhomologous end joining. The commitment to one or the other pathway proceeds via different steps of resection of the DNA ends, which is controlled and executed by a set of DNA double-strand break sensors, endo- and exonucleases, helicases, and DNA damage response factors. The molecular choreography of the underlying protein machinery is beginning to emerge. In this review, we discuss the early steps of genetic recombination and double-strand break sensing with an emphasis on structural and molecular studies.

Coordination of multiple enzyme activities by a single PCNA in archaeal Okazaki fragment maturation

In vitro reconstitution of Okazaki fragment processing shows that DNA polymerase, flap endonuclease and DNA ligase need to simultaneously bind to the same PCNA-sliding clamp molecule during DNA lagging strand replication.

Chromosomal DNA replication requires one daughter strand—the lagging strand—to be synthesised as a series of discontinuous, RNA-primed Okazaki fragments, which must subsequently be matured into a single covalent DNA strand. Here, we describe the reconstitution of Okazaki fragment maturation in vitro using proteins derived from the archaeon Sulfolobus solfataricus. Six proteins are necessary and sufficient for coupled DNA synthesis, RNA primer removal and DNA ligation. PolB1, Fen1 and Lig1 provide the required catalytic activities, with coordination of their activities dependent upon the DNA sliding clamp, proliferating cell nuclear antigen (PCNA). S. solfataricus PCNA is a heterotrimer, with each subunit having a distinct specificity for binding PolB1, Fen1 or Lig1. Our data demonstrate that the most efficient coupling of activities occurs when a single PCNA ring organises PolB1, Fen1 and Lig1 into a complex.

The role of the DNA sliding clamp in Okazaki fragment maturation in archaea and eukaryotes

Efficient processing of Okazaki fragments generated during discontinuous lagging-strand DNA replication is critical for the maintenance of genome integrity. In eukaryotes, a number of enzymes co-ordinate to ensure the removal of initiating primers from the 5′-end of each fragment and the generation of a covalently linked daughter strand. Studies in eukaryotic systems have revealed that the co-ordination of DNA polymerase δ and FEN-1 (Flap Endonuclease 1) is sufficient to remove the majority of primers. Other pathways such as that involving Dna2 also operate under certain conditions, although, notably, Dna2 is not universally conserved between eukaryotes and archaea, unlike the other core factors. In addition to the catalytic components, the DNA sliding clamp, PCNA (proliferating-cell nuclear antigen), plays a pivotal role in binding and co-ordinating these enzymes at sites of lagging-strand replication. Structural studies in eukaryotic and archaeal systems have revealed that PCNA-binding proteins can adopt different conformations when binding PCNA. This conformational malleability may be key to the co-ordination of these enzymes' activities.

Dna2 on the road to Okazaki fragment processing and genome stability in eukaryotes

DNA replication is a primary mechanism for maintaining genome integrity, but it serves this purpose best by cooperating with other proteins involved in DNA repair and recombination. Unlike leading strand synthesis, lagging strand synthesis has a greater risk of faulty replication for several reasons: First, a significant part of DNA is synthesized by polymerase alpha, which lacks a proofreading function. Second, a great number of Okazaki fragments are synthesized, processed and ligated per cell division. Third, the principal mechanism of Okazaki fragment processing is via generation of flaps, which have the potential to form a variety of structures in their sequence context. Finally, many proteins for the lagging strand interact with factors involved in repair and recombination. Thus, lagging strand DNA synthesis could be the best example of a converging place of both replication and repair proteins. To achieve the risky task with extraordinary fidelity, Okazaki fragment processing may depend on multiple layers of redundant, but connected pathways. An essential Dna2 endonuclease/helicase plays a pivotal role in processing common structural intermediates that occur during diverse DNA metabolisms (e.g. lagging strand synthesis and telomere maintenance). Many roles of Dna2 suggest that the preemptive removal of long or structured flaps ultimately contributes to genome maintenance in eukaryotes. In this review, we describe the function of Dna2 in Okazaki fragment processing, and discuss its role in the maintenance of genome integrity with an emphasis on its functional interactions with other factors required for genome maintenance.

A thermostable dolichol phosphoryl mannose synthase responsible for glycoconjugate synthesis of the hyperthermophilic archaeon Pyrococcus horikoshii

Dolichol phosphoryl mannose synthase (DPM synthase) is an essential enzyme in the synthesis of N- and O-linked glycoproteins and the glycosylphosphatidyl-inositol anchor. An open reading frame, PH0051, from the hyperthermophilic archaeon Pyrococcus horikoshii encodes a DPM synthase ortholog, PH0051p. A full-length version of PH0051p was produced using an E. coli in vitro translation system and its thermostable activity was confirmed with a DPM synthesis assay, although the in vitro productivity was not sufficient for further characterization. Then, a yeast expression vector coding for the N-terminal catalytic domain of PH0051p was constructed. The N-terminal domain, named DPM(1-237), was successfully expressed, and turned out to be a membrane-bound form in Saccharomyces cerevisiae cells, even without its hydrophobic C-terminal domain. The membrane-bound DPM(1-237) was solubilized with a detergent and purified to homogeneity. The purified DPM(1-237) showed thermostability at up to 75 degrees C and an optimum temperature of 60 degrees C. The truncated mutant DPM(1-237) required Mg(2+) and Mn(2+) ions as cofactors the same as eukaryotic DPM synthases. By site-directed mutagenesis, Asp(89) and Asp(91) located at the most conserved motif, DXD, were confirmed as the catalytic residues, the latter probably bound to a cofactor, Mg(2+). DPM(1-237) was able to utilize both acceptor lipids, dolichol phosphate and the prokaryotic carrier lipid C(55)-undecaprenyl phosphate, with Km values of 1.17 and 0.59 microM, respectively. The DPM synthase PH0051p seems to be a key component of the pathway supplying various lipid-linked phosphate sugars, since P. horikoshii could synthesize glycoproteins as well as the membrane-associated PH0051p in vivo.

Enzymatic properties of the Caenorhabditis elegans Dna2 endonuclease/helicase and a species-specific interaction between RPA and Dna2

In both budding and fission yeasts, a null mutation of the DNA2 gene is lethal. In contrast, a null mutation of Caenorhabditis elegans dna2⁺ causes a delayed lethality, allowing survival of some mutant C.elegans adults to F2 generation. In order to understand reasons for this difference in requirement of Dna2 between these organisms, we examined the enzymatic properties of the recombinant C.elegans Dna2 (CeDna2) and its interaction with replication-protein A (RPA) from various sources. Like budding yeast Dna2, CeDna2 possesses DNA-dependent ATPase, helicase and endonuclease activities. The specific activities of both ATPase and endonuclease activities of the CeDna2 were considerably higher than the yeast Dna2 (∼10- and 20-fold, respectively). CeDna2 endonuclease efficiently degraded a short 5′ single-stranded DNA tail (<10 nt) that was hardly cleaved by ScDna2. Both endonuclease and helicase activities of CeDna2 were stimulated by CeRPA, but not by human or yeast RPA, demonstrating a species-specific interaction between Dna2 and RPA. These and other enzymatic properties of CeDna2 described in this paper may shed light on the observation that C.elegans is less stringently dependent on Dna2 for its viability than Saccharomyces cerevisiae. We propose that flaps generated by DNA polymerase δ-mediated displacement DNA synthesis are mostly short in C.elegans eukaryotes, and hence less dependent on Dna2 for viability.

Complete genome sequence of the hyperthermophilic archaeon Thermococcus kodakaraensis KOD1 and comparison with Pyrococcus genomes

The genus Thermococcus, comprised of sulfur-reducing hyperthermophilic archaea, belongs to the order Thermococcales in Euryarchaeota along with the closely related genus Pyrococcus. The members of Thermococcus are ubiquitously present in natural high-temperature environments, and are therefore considered to play a major role in the ecology and metabolic activity of microbial consortia within hot-water ecosystems. To obtain insight into this important genus, we have determined and annotated the complete 2,088,737-base genome of Thermococcus kodakaraensis strain KOD1, followed by a comparison with the three complete genomes of Pyrococcus spp. A total of 2306 coding DNA sequences (CDSs) have been identified, among which half (1165 CDSs) are annotatable, whereas the functions of 41% (936 CDSs) cannot be predicted from the primary structures. The genome contains seven genes for probable transposases and four virus-related regions. Several proteins within these genetic elements show high similarities to those in Pyrococcus spp., implying the natural occurrence of horizontal gene transfer of such mobile elements among the order Thermococcales. Comparative genomics clarified that 1204 proteins, including those for information processing and basic metabolisms, are shared among T. kodakaraensis and the three Pyrococcus spp. On the other hand, among the set of 689 proteins unique to T. kodakaraensis, there are several intriguing proteins that might be responsible for the specific trait of the genus Thermococcus, such as proteins involved in additional pyruvate oxidation, nucleotide metabolisms, unique or additional metal ion transporters, improved stress response system, and a distinct restriction system.

A Novel Thermostable Membrane Protease Forming an Operon with a Stomatin Homolog from the Hyperthermophilic Archaebacterium Pyrococcus horikoshii

Membrane-bound proteases play several important roles in protein quality control and regulation. In the genome of the hyperthermophilic archaebacterium Pyrococcus horikoshii, the open reading frames PH1510 and PH1511 are homologous to the genes nfed (nodulation formation efficiency D) and stomatin, respectively, and probably form an operon. The nfed proteins are putative membrane proteins, and the N-terminal region shows homology to ClpP-type serine proteases. Stomatin is one of the major integral membrane proteins of human erythrocytes, and its absence is associated with the hemolytic anemia known as hereditary stomatocytosis. Thus, the N-terminal region of PH1510 (1510-N, residues 16-236) was expressed and purified. From activity staining and SDS-PAGE analysis using fluorescein isothiocyanate-casein, 1510-N was identified as a thermostable endo-type protease. From site-directed mutagenesis, the conserved Ser-97 and Lys-138 are involved in proteolysis and, therefore, PH1510 is probably a serine protease with a catalytic Ser-Lys dyad. The sites of cleavage by 1510-N are rich in hydrophobic residues. The site P1 (position -1 relative to the cleavage site) is mainly leucine. P4 and P4' are mainly hydrophobic residues. Interestingly, the 1510-N protease cleaves the C-terminal hydrophobic region of PH1511. From this result and the probability of an operon, PH1510 probably functions in cooperation with PH1511. It is hypothesized that the cleavage of the stomatin-homolog PH1511 by the PH1510 protease causes an ion channel to open.

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.

Distinct domain functions regulating de novo DNA synthesis of thermostable DNA primase from hyperthermophile Pyrococcus horikoshii

DNA primases are essential components of the DNA replication apparatus in every organism. Reported here are the biochemical characteristics of a thermostable DNA primase from the thermophilic archaeon Pyrococcus horikoshii, which formed the oligomeric unit L(1)S(1) and synthesized long DNA primers 10 times more effectively than RNA primers. The N-terminal (25KL) and C-terminal halves (20KL) of the large subunit (L) play distinct roles in regulating de novo DNA synthesis of the small catalytic subunit (S). The 25KL domain has a dual function. One function is to depress the large affinity of the intrasubunit domain 20KL for the template DNA until complex (L(1)S(1) unit) formation. The other function is to tether the L subunit tightly to the S subunit, probably to promote effective interaction between the intrasubunit domain 20KL and the active center of the S subunit. The 20KL domain is a central factor to enhance the de novo DNA synthesis activity of the catalytic S subunit since the total affinity of the L(1)S(1) unit is mainly derived from the affinity of 20KL, which is elevated more than 10 times by the heterodimer formation, presumably due to the cancellation of the inhibitory activity of 25KL through tight binding to the S subunit.

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.

Bimodal interaction between replication-protein A and Dna2 is critical for Dna2 function both in vivo and in vitro

We have previously shown that replication- protein A (RPA), the heterotrimeric single-stranded DNA binding protein of eukaryotes, plays a role in Okazaki fragment processing by acting as a molecular switch between the two endonucleases, Dna2 and Fen1, to ensure the complete removal of primer RNAs in Saccharomyces cerevisiae. The stimulation of Dna2 endonuclease activity by RPA requires direct protein-protein interaction. In this report we have analyzed genetically and biochemically the interaction of Dna2 with RPA. RFA1, the gene encoding the large subunit of RPA, displayed allele-specific interactions with DNA2 that included synthetic lethality and intergenic complementation. In addition, we identified physical and functional interactions between these proteins and found that RPA binds Dna2 predominantly through its large subunit, Rpa1. Consistent with the mapping of synthetic lethal mutations, robust interaction localizes to the C-termini of these proteins. Moreover, the N-terminal domains of Dna2 and Rpa1 appear to be important for a functional interaction because the N-terminal domain of RPA1 was required to maximally stimulate Dna2 endonuclease activity. We propose that a bimodal interaction of Dna2 with Rpa1 is important for Dna2 function both in vivo and in vitro. The relevance of each interaction with respect to the function of the Dna2 endonuclease activity is discussed.