DNA primase from KB cells. Evidence for a novel model of primase catalysis by a highly purified primase/polymerase-alpha complex

Molecular choreography of primer synthesis by the eukaryotic Pol α-primase

The eukaryotic polymerase α (Pol α) synthesizes an RNA-DNA hybrid primer of 20-30 nucleotides. Pol α is composed of Pol1, Pol12, Primase 1 (Pri1), and Pri2. Pol1 and Pri1 contain the DNA polymerase and RNA primase activities, respectively. It has been unclear how Pol α hands over an RNA primer from Pri1 to Pol1 for DNA primer extension, and how the primer length is defined. Here we report the cryo-EM analysis of yeast Pol α in the apo, primer initiation, primer elongation, RNA primer hand-off from Pri1 to Pol1, and DNA extension states, revealing a series of very large movements. We reveal a critical point at which Pol1-core moves to take over the 3'-end of the RNA from Pri1. DNA extension is limited by a spiral motion of Pol1-core. Since both Pri1 and Pol1-core are flexibly attached to a stable platform, primer growth produces stress that limits the primer length.

Molecular choreography of primer synthesis by the eukaryotic Pol α-primase

The eukaryotic polymerase α (Pol α) is a dual-function DNA polymerase/primase complex that synthesizes an RNA-DNA hybrid primer of 20-30 nucleotides for DNA replication. Pol α is composed of Pol1, Pol12, Primase 1 (Pri1), and Pri2, with Pol1 and Pri1 containing the DNA polymerase activity and RNA primase activity, respectively, whereas Pol12 and Pri2 serve a structural role. It has been unclear how Pol α hands over an RNA primer made by Pri1 to Pol1 for DNA primer extension, and how the primer length is defined, perhaps due to the difficulty in studying the highly mobile structure. Here we report a comprehensive cryo-EM analysis of the intact 4-subunit yeast Pol α in the apo, primer initiation, primer elongation, RNA primer hand-off from Pri1 to Pol1, and DNA extension states in a 3.5 Å - 5.6 Å resolution range. We found that Pol α is a three-lobed flexible structure. Pri2 functions as a flexible hinge that holds together the catalytic Pol1-core, and the noncatalytic Pol1 CTD that binds to Pol 12 to form a stable platform upon which the other components are organized. In the apo state, Pol1-core is sequestered on the Pol12-Pol1-CTD platform, and Pri1 is mobile perhaps in search of a template. Upon binding a ssDNA template, a large conformation change is induced that enables Pri1 to perform RNA synthesis, and positions Pol1-core to accept the future RNA primed site 50 Å upstream of where Pri1 binds. We reveal in detail the critical point at which Pol1-core takes over the 3'-end of the RNA from Pri1. DNA primer extension appears limited by the spiral motion of Pol1-core while Pri2-CTD stably holds onto the 5' end of the RNA primer. Since both Pri1 and Pol1-core are attached via two linkers to the platform, primer growth will produce stress within this "two-point" attachment that may limit the length of the RNA-DNA hybrid primer. Hence, this study reveals the large and dynamic series of movements that Pol α undergoes to synthesize a primer for DNA replication.

Mechanism for priming DNA synthesis by yeast DNA polymerase α

The DNA Polymerase α (Pol α)/primase complex initiates DNA synthesis in eukaryotic replication. In the complex, Pol α and primase cooperate in the production of RNA-DNA oligonucleotides that prime synthesis of new DNA. Here we report crystal structures of the catalytic core of yeast Pol α in unliganded form, bound to an RNA primer/DNA template and extending an RNA primer with deoxynucleotides. We combine the structural analysis with biochemical and computational data to demonstrate that Pol α specifically recognizes the A-form RNA/DNA helix and that the ensuing synthesis of B-form DNA terminates primer synthesis. The spontaneous release of the completed RNA-DNA primer by the Pol α/primase complex simplifies current models of primer transfer to leading- and lagging strand polymerases. The proposed mechanism of nucleotide polymerization by Pol α might contribute to genomic stability by limiting the amount of inaccurate DNA to be corrected at the start of each Okazaki fragment.

DOI:http://dx.doi.org/10.7554/eLife.00482.001

During mitosis, a cell duplicates its DNA and then divides, ultimately generating two genetically identical daughter cells. In eukaryotes, the process of DNA duplication occurs at multiple sites throughout the genome: at each site, the antiparallel strands of the parental DNA separate and provide a template for DNA polymerase (Pol), the enzyme that synthesizes the two new DNA strands. Duplication of the DNA proceeds in both directions from each site through the polymerization of nucleotides to form new strands of DNA that are complementary to the template strands. However, since DNA polymerases can only polymerize nucleotides in one direction, the 5′ to 3′ direction, synthesis of the so-called leading strand proceeds continuously, whereas the other, lagging strand is synthesized in fragments.

The task of duplicating the bulk of the DNA is shared between Pol δ, which is primarily responsible for synthesis of the lagging strand, and Pol ε, which fulfils the same role for the leading strand. However, Pols δ and ε cannot initiate DNA synthesis by themselves; short RNA-DNA chains called primers must also be paired to each template strand. Production of the primers requires the concerted action of two more enzymes: an RNA polymerase known as primase, and another DNA polymerase called Pol α. It is known that completion of the RNA-DNA primer requires Pol α to increase the length of the RNA segment by adding extra nucleotides, but the details of this process are poorly understood.

Perera et al. combined crystallographic, biochemical and computational evidence to describe how Pol α first recognizes and then extends the RNA strand in the primer. They found that Pol α recognizes the particular shape of double helix—an A-form helix—that is formed by the DNA template and the RNA primer. The geometry of this helix prompts the Pol α enzyme to start adding nucleotides to the RNA in the primer. Perera et al. determined that once a full turn of double-helix DNA has been synthesized, Pol α is no longer in direct contact with the A-form helix, which causes the enzyme to disengage and terminate polymerization, leaving behind the now complete RNA-DNA primer.

Perera et al. offer a new paradigm for understanding the initiation of DNA synthesis in eukaryotic replication. Their work suggests that Pol α has the ability to discriminate between different shapes of the primer-template helix, thus providing a mechanistic understanding of primer release. The spontaneous release of the primer offers a simple and elegant way to limit DNA synthesis by Pol α, a polymerase that is prone to error, and to make the RNA-DNA primer directly available for extension by Pol δ and Pol ε.

DOI:http://dx.doi.org/10.7554/eLife.00482.002

Instantiating a vision: creating the new pathology department at Stanford Medical School

This review represents my best effort to recreate and memorialize events that occurred 44 years ago, when I was invited to join the Stanford University faculty to create, essentially de novo, what rapidly became and remains today one of the very best and most admired departments of pathology in the world. That I was able to accomplish this challenging task I attribute to my holding fast to a somewhat inchoate vision of where the science and practice of pathology would go in future decades, a little bit to my gut instincts and innate ability to spot up-and-coming talent, but a lot to circumstances and good fortune in leading me to a small nucleus of wonderful young professionals of outstanding promise who were willing to join me in "betting the house" that, working together, we could pull off this once-in-a-lifetime opportunity--and we did.

Initiation of new DNA strands by the herpes simplex virus-1 primase-helicase complex and either herpes DNA polymerase or human DNA polymerase alpha

A key set of reactions for the initiation of new DNA strands during herpes simplex virus-1 replication consists of the primase-catalyzed synthesis of short RNA primers followed by polymerase-catalyzed DNA synthesis (i.e. primase-coupled polymerase activity). Herpes primase (UL5-UL52-UL8) synthesizes products from 2 to approximately 13 nucleotides long. However, the herpes polymerase (UL30 or UL30-UL42) only elongates those at least 8 nucleotides long. Surprisingly, coupled activity was remarkably inefficient, even considering only those primers at least 8 nucleotides long, and herpes polymerase typically elongated <2% of the primase-synthesized primers. Of those primers elongated, only 4-26% of the primers were passed directly from the primase to the polymerase (UL30-UL42) without dissociating into solution. Comparing RNA primer-templates and DNA primer-templates of identical sequence showed that herpes polymerase greatly preferred to elongate the DNA primer by 650-26,000-fold, thus accounting for the extremely low efficiency with which herpes polymerase elongated primase-synthesized primers. Curiously, one of the DNA polymerases of the host cell, polymerase alpha (p70-p180 or p49-p58-p70-p180 complex), extended herpes primase-synthesized RNA primers much more efficiently than the viral polymerase, raising the possibility that the viral polymerase may not be the only one involved in herpes DNA replication.

A DNA polymerase epsilon inhibitor activates the ribo and deoxyribo modes of primase expression and induces a unique phenomenon of primer accumulation

Carbonyldiphosphonate (COMDP), a selective inhibitor of DNA polymerase (pol) epsilon, strongly stimulates expression of the ribo and deoxyribo modes of primase (Pr) activities of the Pr-DNA pol alpha enzyme complex associated with special cytoplasmic nucleoprotein complexes of chicken leukemic myeloblasts [J. Ríman and A. Sulová, Acta Virol. 41 (1997) 181-214]. Besides stimulation, COMDP uncouples the Pr activities from those of DNA pol alpha, inducing in this way a unique phenomenon of accumulation of primers of basic length. In the presence of dNTPs, the COMDP effect is counteracted by excess of mimosine. The mutually exclusive effects of these agents are discussed.

Imbalanced DNA synthesis induced by cytosine arabinoside and fludarabine in human leukemia cells11Abbreviations: araC, 1-β-d-arabinofuranosylcytosine (cytosine arabinoside); araA, 1-β-d-arabinofuranosyladenine; BrdUrd, 5-bromo-2′-deoxyuridine; FaraA, 1-β-d-arabinofuranosyl-2-fluoroadenine (fludarabine); ic50, concentration that reduces cloning efficiency by 50%; GAPDH, glyceraldehyde-3-phosphate dehydrogenase; PALA, N-(phosphonacetyl)-l-aspartate; and SSC, standard saline citrate

Previous studies have demonstrated that cytosine arabinoside (araC) induces an accumulation of Okazaki fragments, while fludarabine (FaraA) inhibits Okazaki fragment synthesis. We extended these observations in the present study to provide insights into various mechanisms by which these anticancer drugs affect DNA replication and induce genomic instability in human CEM leukemia cells. Neither araC nor FaraA induced a detectable amount of re-replicated DNA in S-phase cells, which indicated that drug-induced alterations in Okazaki fragment synthesis were not accompanied by DNA re-replication. Synthesis on both leading and lagging DNA strands within the c-myc locus was measured in cells incubated with equitoxic concentrations of araC or FaraA. In araC-treated cells, nascent DNA from the lagging strand was enriched about 5-fold compared with the leading strand. In contrast, FaraA did not induce any replication imbalance. AraC- and FaraA induced changes in the frequency of N-(phosphonacetyl)-l-aspartate (PALA) resistance and the extent of CAD gene amplification were monitored as markers of drug-induced genomic instability. At concentrations that reduced cloning efficiency by 50% (IC(50)), araC increased the frequency of PALA resistance about 4-fold, while FaraA did not have a significant effect on the frequency of PALA resistance. Pretreatment with araC also increased the extent of CAD gene amplification. We propose that the imbalanced DNA synthesis induced by araC leads to the accumulation of Okazaki fragments on the lagging arms and single-stranded DNA regions on the leading arms of replication forks. The formation of these abnormal replication structures was associated with the generation of genomic instability.

Arabinofuranosyl nucleotides are not chain-terminators during initiation of new strands of DNA by DNA polymerase alpha-primase

Polymerization of NTPs and arabinofuranosyladenosine triphosphate (araATP) during DNA polymerase alpha catalyzed elongation of primase-synthesized primers was examined. After primase synthesizes a primer, pol alpha normally polymerizes multiple dNTPs onto this primer. In the absence of a required dNTP, however, primers were still elongated by up to 35 nucleotides via polymerization of the corresponding NTP in place of the missing dNTP. During the elongation of exogenously added primer/templates, however, NTPs were not readily polymerized. AraATP was readily incorporated into products during elongation of primase-synthesized primers. Importantly, polymerization of araATP did not result in chain termination; rather, the next correct nucleotide was added such that araATP was simply an alternate substrate. In contrast, polymerization of araATP during elongation of exogenously added primer/templates resulted in strong chain termination. Thus, elongation of primase-synthesized primers by pol alpha-primase is fundamentally different than elongation of exogenously added primer/templates with respect to interactions with dNTP analogs. Furthermore, these data provide a rationale for how araNMPs are efficiently incorporated into internucleotide linkages of DNA in whole cells and suggest that the initiation of new strands of DNA by pol alpha-primase may be a unique target for inhibiting replication.

Highly selective affinity labeling of DNA polymerase alpha-primase from human placenta by reactive analogs of ATP

Highly selective affinity labeling of a DNA-polymerase alpha-primase complex from human placenta by o-formylphenyl esters of ATP, ADP and AMP was performed in a two-step procedure in which a substrate analog attached to the active center was elongated by radioactive ATP. If the covalent attachment is performed in the presence of poly(dT) template, the ATP esters modify selectively the delta subunit of the complex. If poly(dT) is added after the covalent binding of the reagent, both delta and gamma subunits become labeled. With the o-formylphenyl ester of AMP the delta-subunit is modified. The ADP ester modifies both the delta and gamma subunit in the presence and absence of template. It is shown that formylphenyl ester of ATP is not the substrate in the reaction of elongation catalyzed by primase. The data obtained suggest the binding site of initiating substrate to be located in the region of contact of the two subunits of primase. The role of the template in the formation of the active site is discussed.

Eukaryotic DNA primase appears to act as oligomer in DNA-polymerase-alpha--primase complex

Human placenta and calf thymus DNA-polymerase-alpha-primases were analyzed using native gradient-polyacrylamide-gel electrophoresis followed by overlay assays of polymerase and primase activities. The human enzyme contained three catalytically active native forms of 330, 440 and 560 kDa and the bovine enzyme five forms of 330, 440, 500, 590 and 660 kDa. Of the various DNA polymerase forms, only the largest (560 kDa for human DNA polymerase and 590 kDa and 660 kDa for bovine DNA polymerase) contained primase activity. Titration of human DNA-polymerase-alpha-primase with DNA-polymerase-free primase caused the conversion of the 440-kDa to the 560-kDa form. The data favour the idea that primase binds to DNA polymerase alpha as an oligomer of 3 primases/polymerase core. In addition, the ability of primase to utilize oligoriboadenylates containing (prA)n or pp(prA)n was investigated. The primase elongated pp(prA)2-7 up to nanoadenylates or decaadenylates, but did not add 9 or 10 mononucleotides to a preexistent primer. In contrast to pp(prA)n less than 10, (prA)n less than 10 were rather poor primers for the primase. Both pp(prA)8,9 and (prA)n greater than 10 were elongated by primase, producing characteristic multimeric oligonucleotides. The possible connection of the structure of the DNA-polymerase-alpha-primase complex with the catalytical properties of primase is discussed.

Eukaryotic DNA primase. Abortive synthesis of oligoadenylates

Calf thymus DNA polymerase alpha-primase, human placenta DNA polymerase alpha-primase and human placenta DNA primase synthesized oligoriboadenylates of a preferred length of 2-10 nucleotides and multimeric oligoribonucleotides of a modal length of about 10 monomers on a poly(dT) template. The dimer and trimer were the prevalent products of the polymerization reaction. However, only the oligonucleotides from heptamers to decamers were elongated efficiently by DNA polymerase alpha.

A novel primase-free form of murine DNA polymerase alpha induced by infection with minute virus of mice

Two species of DNA polymerase alpha free of primase activity were identified in extracts of Ehrlich mouse cells that had been infected with minute virus of mice. Primase-free forms of DNA polymerase alpha eluted with 150 and 180 mM NaCl during ion-exchange chromatography on DEAE-cellulose columns, exhibited sedimentation coefficients of 11 S and 8.2 S, respectively, and were inhibited by aphidicolin, N2-(p-n-butylphenyl)-9-(2-deoxy-beta-D-ribofuranosyl)guanine 5'-triphosphate, and 2-(p-n-butylanilino)-9-(2-deoxy-beta-D-ribofuranosyl)adenine 5'-triphosphate. The ratio of primase-free DNA polymerase alpha to the DNA polymerase alpha-primase complex increased from 1.5 to greater than 100 during the course of infection, and free primase was produced during the MVM replicative cycle.

A model of chromatin-dependent DNA replication sequences based on the decondensation units hypothesis

A model of chromatin-dependent DNA replication sequences was developed on the previously reported "decondensation units" hypothesis and its kinetic properties were examined by way of calculating various numerical indices using a Monte Carlo procedure. The model has much in common with the previous one but a fundamental difference is that the unit is assumed to consist of linearly arranged H-, D-, A- and S-zones each containing genes of different functional categories which are called H-, D-, A- and S-genes, respectively. The units are decondensed by the action of D-factors, i.e. decondensation factors, from H-zone to the end of S-zone and the genes in decondensed regions release signals to produce housekeeping enzymes, D-factors, A-factors and S-factors. These products are stored and at the same time degraded. A-factors activate replication origins in the decondensed regions and S-factors induce DNA synthesis at the activated origins. Replicated DNA is recondensed and gene activities are shut down in the recondensed chromatin. The factors are produced under the control of chromosome cycle and in turn affect chromosomes. Thus, dual control mechanism operates as Mazia and Prescott have argued. Biochemical and cytogenetic basis of this model was reviewed briefly and some results of simulation presented which include DNA synthesis rate vs. DNA content relationships. An outstanding characteristic of the model is the constancy of cellular state in A-subphase located in the late G1.

Fidelity of HIV-1 reverse transcriptase

The human immunodeficiency virus type 1 (HIV-1) shows extensive genetic variation and undergoes rapid evolution. The fidelity of purified HIV-1 reverse transcriptase was measured during DNA polymerization in vitro by means of three different assays. Reverse transcriptase from HIV-1 introduced base-substitution errors in DNA from the bacteriophage phi X174 amber3 at estimated frequencies of 1/2000 to 1/4000. Analyses of misincorporation rates opposite a single template adenine residue showed that HIV-1 reverse transcriptase catalyzed nucleotide mismatches with a specificity of A:C much greater than A:G greater than A:A. The high error rate of HIV-1 reverse transcriptase in vitro translates to approximately five to ten errors per HIV-1 genome per round of replication in vivo. This high error rate suggests that misincorporation by HIV-1 reverse transcriptase is, at least in part, responsible for the hypermutability of the AIDS virus. The specificity of misincorporation may provide a basis for the systematic construction of antiviral nucleosides.

An Okazaki piece of simian virus 40 may be synthesized by ligation of shorter precursor chains

It is generally accepted that an aphidicolin-sensitive DNA polymerase elongates the eucaryotic RNA primer (iRNA) into a mature Okazaki piece reaching ca. 200 nucleotides. Yet, as shown here, nascent DNA chains below 40 nucleotides accumulated in simian virus 40 (SV40) DNA replicating in isolated nuclei in the presence of aphidicolin. These products resembled precursors of longer Okazaki pieces synthesized in the absence of aphidicolin (termed here DNA primers) in size distribution, lagging-replication-fork polarity, and content of iRNA. Within the isolated SV40 replicative intermediate, DNA primers could be extended in a reaction catalyzed by the Escherichia coli DNA polymerase I large fragment. This increased their length by an average of 21 deoxyribonucleotide residues, indicating that single-stranded gaps of corresponding length existed 3' to the DNA primers. Incubation with T4 DNA ligase converted most of the extended DNA primers into products resembling long Okazaki pieces. These data led us to propose that the synthesis of an SV40 Okazaki piece could be itself discontinuous and could comprise the following steps: (i) iRNA synthesis by DNA primase, (ii) iRNA extension into a DNA primer by an aphidicolin-resistant activity associated with DNA primase-DNA polymerase alpha, (iii) removal of iRNA moieties between adjacent DNA primers, (iv) "gap filling" between DNA primers by the aphidicolin-sensitive DNA polymerase alpha, and (v) ligation of DNA primer units onto a growing Okazaki piece. Eventually, a mature Okazaki piece is ligated onto a longer nascent DNA chain.

Eucaryotic primase

Eucaryotic primase, an enzyme that initiates de novo DNA replication, is tightly associated with polymerase alpha or yeast DNA polymerase I. It is probably a heterodimer of 5.6 +/- 0.1 S. The enzyme synthesizes oligoribonucleotides of about eight residues which are always initiated with a purine. In vitro the polymerase-primase complex initiates synthesis and pauses at preferred sites on natural single-stranded templates. The relative concentrations of ATP and GTP present in the reaction medium modulate the frequency of site recognition. Primase is strongly ATP-dependent in the presence of single-stranded DNA and of poly(dT). It also synthesizes oligo(rG) in the presence of poly(dC) very efficiently.

Probing DNA polymerase alpha with monoclonal antibodies

DNA polymerase alpha was purified from human KB cells by immunoaffinity chromatography. Enzyme activity was inhibited by three different monoclonal antibodies (SJK-132, SJK-211, SJK-287). Kinetic analysis showed that each antibody neutralized polymerase activity by a different mechanism. SJK-132 was competitive with DNA indicating it interacts with the DNA binding domain of the polymerase. SJK-287 showed a biphasic response to dCTP suggesting two dCTP binding sites exist on polymerase alpha. SJK-211 was non-competitive with DNA, dCTP and dATP.

Monoclonal antibody specific for chicken DNA polymerase alpha associated with DNA primase

Four monoclonal antibodies against chicken DNA polymerase alpha were obtained from mouse hybridomas (see ref. 1). Two of them, 4-2D and 4-8H, recognized different epitopes of the DNA polymerase alpha-DNA primase complex as determined by a competitive enzyme-linked immunosorbent assay. Antibody 4-8H partially (about 30%) neutralized the combined activity of primase-DNA polymerase alpha as well as the DNA polymerase alpha activity. In contrast, antibody 4-2D did not neutralize DNA polymerase alpha activity, but neutralized the primase-DNA polymerase alpha activity extensively (up to 80%). Furthermore, although an immunoaffinity column made with 4-8H antibody retained virtually all of the DNA polymerase alpha with and without associated primase, a column made with 4-2D antibody did not bind DNA polymerase alpha without the primase, but retained the enzyme associated with the primase. These results indicate that 4-8H monoclonal antibody is specific for DNA polymerase alpha and 4-2D monoclonal antibody is specific for the primase or a special structure present in the primase-DNA polymerase alpha complex.