Intact DNA polymerase α/primase from mouse cells

A model for dynamics of primer extension by eukaryotic DNA primase

A mathematical model is proposed for processive primer extension by eukaryotic DNA primase. The model uses available experimental data to predict rate constants for the dynamic behavior of primase activity as a function of NTP concentration. The model also predicts some data such as the binding affinities of the primase for the DNA template and for the RNA primer.

Flexible tethering of primase and DNA Pol α in the eukaryotic primosome

The Pol α/primase complex or primosome is the primase/polymerase complex that initiates nucleic acid synthesis during eukaryotic replication. Within the primosome, the primase synthesizes short RNA primers that undergo limited extension by Pol α. The resulting RNA–DNA primers are utilized by Pol δ and Pol ε for processive elongation on the lagging and leading strands, respectively. Despite its importance, the mechanism of RNA–DNA primer synthesis remains poorly understood. Here, we describe a structural model of the yeast primosome based on electron microscopy and functional studies. The 3D architecture of the primosome reveals an asymmetric, dumbbell-shaped particle. The catalytic centers of primase and Pol α reside in separate lobes of high relative mobility. The flexible tethering of the primosome lobes increases the efficiency of primer transfer between primase and Pol α. The physical organization of the primosome suggests that a concerted mechanism of primer hand-off between primase and Pol α would involve coordinated movements of the primosome lobes. The first three-dimensional map of the eukaryotic primosome at 25 Å resolution provides an essential structural template for understanding initiation of eukaryotic replication.

A DNA polymerase-{alpha}{middle dot}primase cofactor with homology to replication protein A-32 regulates DNA replication in mammalian cells

alpha-Accessory factor (AAF) stimulates the activity of DNA polymerase-alpha.primase, the only enzyme known to initiate DNA replication in eukaryotic cells ( Goulian, M., Heard, C. J., and Grimm, S. L. (1990) J. Biol. Chem. 265, 13221-13230 ). We purified the AAF heterodimer composed of 44- and 132-kDa subunits from cultured cells and identified full-length cDNA clones using amino acid sequences from internal peptides. AAF-132 demonstrated no homologies to known proteins; AAF-44, however, is evolutionarily related to the 32-kDa subunit of replication protein A (RPA-32) and contains an oligonucleotide/oligosaccharide-binding (OB) fold domain similar to the OB fold domains of RPA involved in single-stranded DNA binding. Epitope-tagged versions of AAF-44 and -132 formed a complex in intact cells, and purified recombinant AAF-44 bound to single-stranded DNA and stimulated DNA primase activity only in the presence of AAF-132. Mutations in conserved residues within the OB fold of AAF-44 reduced DNA binding activity of the AAF-44.AAF-132 complex. Immunofluorescence staining of AAF-44 and AAF-132 in S phase-enriched HeLa cells demonstrated punctate nuclear staining, and AAF co-localized with proliferating cell nuclear antigen, a marker for replication foci containing DNA polymerase-alpha.primase and RPA. Small interfering RNA-mediated depletion of AAF-44 in tumor cell lines inhibited [methyl-(3)H]thymidine uptake into DNA but did not affect cell viability. We conclude that AAF shares structural and functional similarities with RPA-32 and regulates DNA replication, consistent with its ability to increase polymerase-alpha.primase template affinity and stimulate both DNA primase and polymerase-alpha activities in vitro.

DNA polymerase beta can incorporate ribonucleotides during DNA synthesis of undamaged and CPD-damaged DNA

Overexpression of the error-prone DNA polymerase beta (Pol beta) has been found to increase spontaneous mutagenesis by competing with the replicative polymerases during DNA replication. Here, we investigate an additional mechanism potentially used by Pol beta to enhance genetic instability via its ability to incorporate ribonucleotides into DNA. By using an in vitro primer extension assay, we show that purified human and calf thymus Pol beta can synthesize up to 8-mer long RNA. Moreover, Pol beta can efficiently incorporate rCTP opposite G in the absence of dCTP and, to a lesser extent, rATP opposite T in the absence of dATP and rGTP opposite C in the absence of dGTP. Recently, Pol beta was shown to catalyze in vitro translesion replication of a thymine cyclobutane pyrimidine dimer (CPD). Here, we investigate if ribonucleotides could be incorporated opposite the CPD damage and modulate the efficiency of the bypass process. We find that all four rNTPs can be incorporated opposite the CPD lesion, and that this process affects translesion synthesis. We discuss how incorporation of ribonucleotides into DNA may contribute to the high frequency of mutagenesis observed in Pol beta up-regulating cells.

The p58 subunit of human DNA primase is important for primer initiation, elongation, and counting

The p58 subunit of human DNA primase contains a region, M288-K344, that is homologous to part of the 8 kDa domain of DNA polymerase beta. Since regions of a protein that are highly conserved evolutionarily often play important catalytic functions, we examined the effects of mutating this region of the p58 subunit on primase activity. Deleting M288-L313 of the p58 subunit results in a protein that binds to the primase p49 subunit but cannot support primer synthesis on any template when assays only contain Mg(2+) as the divalent metal. Including Mn(2+), a metal that stimulates initiation of primer synthesis, in the assays now allows the enzyme to synthesize primers at a rate only moderately lower than that of the wild-type enzyme on templates consisting solely of deoxycytidylates. While the enzyme is active under these conditions, it has lost the ability to synthesize primers of defined length (i.e., count). Alanine scanning mutagenesis of charged residues in this region revealed three amino acids, R302, R306, and K314, that play important roles in both primer initiation and translocation. Conversion of these residues to alanine interfered with initiation and significantly decreased the processivity of primase. Together, these studies indicate that this "pol beta-like" region of p58 is important for three distinct aspects of primer synthesis:; initiation, translocation, and counting. The implications of these results with respect to the biological role of the p58 subunit and the mechanism of primer synthesis are discussed.

DNA primases

DNA primases are enzymes whose continual activity is required at the DNA replication fork. They catalyze the synthesis of short RNA molecules used as primers for DNA polymerases. Primers are synthesized from ribonucleoside triphosphates and are four to fifteen nucleotides long. Most DNA primases can be divided into two classes. The first class contains bacterial and bacteriophage enzymes found associated with replicative DNA helicases. These prokaryotic primases contain three distinct domains: an amino terminal domain with a zinc ribbon motif involved in binding template DNA, a middle RNA polymerase domain, and a carboxyl-terminal region that either is itself a DNA helicase or interacts with a DNA helicase. The second major primase class comprises heterodimeric eukaryotic primases that form a complex with DNA polymerase alpha and its accessory B subunit. The small eukaryotic primase subunit contains the active site for RNA synthesis, and its activity correlates with DNA replication during the cell cycle.

Eukaryotic DNA primase

Eukaryotic DNA primase initiates the synthesis of all new DNA strands by synthesizing short RNA oligomers on single-stranded DNA. Additionally, primase helps couple replication and repair and is critical for telomere maintenance and, therefore, chromosome stability. In light of the many aspects of DNA metabolism in which primase is involved, understanding the unique features of the mechanism of this enzyme and how it interacts with other proteins will greatly advance our knowledge of DNA replication and repair.

An accessory protein of DNA polymerase alpha declines in function with increasing age

Isoforms of DNA polymerase alpha (pol alpha/primase; pol alpha) were isolated from the livers of C57BL/6 mice either 3 months old (young) or 13 months old (mature). The 13-month-old mice were from two groups, one in which food was available ad libitum (AL), and one in which calories had been restricted to 60% of the AL intake (CR). The polymerases from young vs. mature and CR vs. AL mice differed in total and specific pol alpha activity, with the highest values exhibited by enzymes from 3-month-old mice. A more active isoform of pol alpha was typically isolated from CR animals than from AL animals. Differences in charge were used to chromatographically separate pol alpha into elution peaks exhibiting differing degrees of enzyme activity. DNA pol alpha isolated from tissues of mature mice exhibited a decline in activity which was not associated with decreased recoverable levels of pol alpha protein, but with a decline in the tendency of pol alpha to co-purify with an accessory protein, alpha AP, that binds double-stranded DNA (dsDNA). Low activity pol alpha isoforms which did not co-purify with alpha AP were stimulated by interaction with exogenous alpha AP. Pol alpha isoforms which co-purified with the dsDNA-binding accessory protein exhibited higher specific activity and less enhancement of activity upon interaction with exogenous alpha AP. Calorie restricted animals exhibited a pol alpha isoform that was more like pol alpha from younger animals in that it typically copurified with alpha AP, the DNA-binding accessory protein.

Expression, purification, and characterization of DNA polymerases involved in papovavirus replication

In recent years, work from a large number of laboratories has greatly expanded our knowledge of the biochemical characteristics and the genetic structure of the DNA polymerases used during papovavirus DNA replication. The development of in vitro DNA replication systems for both SV40 and polyoma virus has been paramount in facilitating the development of the current models describing how DNA polymerase alpha and delta function to replicate the genomes of these two viruses. Our studies have demonstrated that the proteins recognized to be essential for both in vitro SV40 and polyoma viral origin-dependent DNA synthesis can be isolated from cells as an intact complex. We have shown that the human cell MRC closely resembles the murine cell MRC, in both its protein composition and its fractionation and chromatographic profile. In addition, our data regarding both the human and the murine MRC support the dipolymerase model proposed from in vitro DNA replication studies using reconstituted assay systems. In addition, analysis of the nucleotide sequence of the genes encoding DNA polymerase alpha and delta has revealed that the amino acids encoded by several regions of these two genes have been rigorously maintained across evolutionary lines. This information has permitted the identification of protein domains which mediate the complex series of protein-protein interactions that direct the DNA polymerases to the cell nucleus, specify complete or partial exonuclease active sites, and participate in the interaction of each DNA polymerase with the DNA template. Expression studies examining each of the genes encoding DNA polymerase alpha and delta clearly indicate that both DNA polymerases are cell cycle regulated and undergo a dramatic induction in their expression when quiescent cells are stimulated to enter the cell cycle. This is in contrast to the two- to three-fold upregulation in the level of expression of these two genes when cycling cells cross the G1/S boundary. In addition, both proteins are phosphorylated in a cell cycle-dependent manner, and phosphorylation appears to be mediated through the action of a cdc2-dependent protein kinase. Despite all of this new information, much remains to be learned about how papovavirus DNA replication is regulated and how these two DNA polymerases act in vivo to faithfully copy the viral genomes. Studies have yet to be performed which identify all of the cellular factors which potentially mediate papovavirus DNA replication. The reconstituted replication systems have yielded a minimum number of proteins which are required to replicate SV40 and polyoma viral genomes in vitro. However, further studies are needed to identify additional factors which may participate in each step of the initiation, elongation, and termination phases of viral genome replication. As an example, models describing the potential role of cellular helicases, which are components of the MRC isolated from murine and human cells, have yet to be described. It is also conceivable that there are a number of other proteins which serve to attach the MRC to the nuclear matrix, stimulate viral DNA replication, and potentially regulate various aspects of the activity of the MRC throughout viral DNA replication. We are currently working toward characterizing the biochemical composition of the MRC from both murine and human cells. Our goals are to identify all of the structural components of the MRC and to define the role of these components in regulating papovavirus and cellular DNA replication. We have also begun studies to visualize the spatial organization of these protein components within the MRC, examine the regulatory processes controlling the activity of the various components of the MRC, and then develop this information into a coherent picture of the higher order structure of the MRC within the cell nucleus. We believe that this information will enable us to develop an accurate view of the detailed processes mediating both pa

DNA replication in vitro by recombinant DNA-polymerase-alpha-primase

DNA-polymerase-alpha--primase complex contains four subunits, p180, p68, p58, and p48, and comprises a minimum of two enzymic functions. We have cloned cDNAs encoding subunits of DNA-polymerase-alpha--primase from human and mouse. Sequence comparisons showed high amino acid conservation among the mammalian proteins. We have over-expressed the single polypeptides and co-expressed various subunit complexes using baculovirus vectors, purified the proteins and investigated their biochemical properties. The purified mouse p48 subunit (Mp48) alone had primase activity. Purification of co-expressed Mp48 and Mp58 subunits yielded stable DNA primase of high specific activity. Co-expression of all four subunits yielded large quantities of tetrameric DNA-polymerase-alpha--primase. The p180, p58 and p48 polypeptides were also co-expressed and immunoaffinity purified as a trimeric enzyme complex. The tetrameric and trimeric DNA-polymerase-alpha--primase complexes showed both DNA primase and DNA polymerase activities. The tetrameric recombinant DNA-polymerase-alpha--primase synthesized double-stranded M13 DNA and replicated polyoma viral DNA in vitro efficiently.

Aphidicolin-resistant Chinese hamster ovary cells possess altered DNA polymerases of the alpha-family

DNA polymerases alpha, delta and epsilon were partially purified and characterized from a wild type Chinese hamster ovary (CHO) cell line and from two aphidicolin-resistant mutant CHO cell lines (BR5 and BR5-20a). The main characteristics of the wild type and mutant DNA polymerases were compared in order to reveal differences in the properties of these enzymes responsible for the aphidicolin resistance of the mutant cell lines. Pol alpha's of the mutant cells show: (1) in vitro aphidicolin-resistance, (2) 1.5-3-fold lower specific activity than that of the wild type, (3) resistance to cytosine and adenosine arabinofuranoside 5'-triphosphate (araCTP and araATP), (4) altered resistance to carbonyldiphosphonate (COMDP) and to alkylphenyl nucleotide analogs (butylphenyl-dGTP and butylanilino-dATP), and (5) lower activity on poly(dA)/oligo(dT) template-primers. These changes in the biochemical properties of this enzyme may result from a mutation in pol alpha gene. Pol epsilon and delta of the mutant cells did not differ from the wild type enzymes with respect to aphidicolin resistance. However, the specific activities of these mutant enzymes were much higher (1.5 to 8-fold for pol epsilon and 4 to 20-fold for pol delta) in comparison to that of the wild type enzymes. Also in comparison to the wild type enzymes, the mutant pol epsilon showed changes in the template-primer preference; whereas the mutant pol delta was found to have altered sensitivity to other inhibitors. These results indicate that pol epsilon and pol delta are also altered as a secondary effect of mutation in the aphidicolin-resistant cells. It is suggested that these altered properties of the DNA pols of the alpha family are responsible for the in vivo aphidicolin resistance of the mutant cells.

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 replication

The past decade has witnessed an exciting evolution in our understanding of eukaryotic DNA replication at the molecular level. Progress has been particularly rapid within the last few years due to the convergence of research on a variety of cell types, from yeast to human, encompassing disciplines ranging from clinical immunology to the molecular biology of viruses. New eukaryotic DNA replicases and accessory proteins have been purified and characterized, and some have been cloned and sequenced. In vitro systems for the replication of viral DNA have been developed, allowing the identification and purification of several mammalian replication proteins. In this review we focus on DNA polymerases alpha and delta and the polymerase accessory proteins, their physical and functional properties, as well as their roles in eukaryotic DNA replication.

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.

Discrimination between mammalian RNases H-1 and H-2

The two principal RNases H in mammalian cells, H-1 and H-2, differ in their responses to sale, divalent metal, and sulfhydryl inhibition. Specific reaction conditions that provide unambiguous discrimination between RNases H-1 and H-2 with only two assays are described. The assays were used for identification in a new purification procedure for RNases H-1 and H-2.

Three cytoplasmic DNA polymerases that utilize poly(rA).oligo(dT)

Three DNA polymerases that use poly(rA).oligo(dT) were partially purified from cytoplasmic extracts of cultured mouse cells (after removal of mitochondria), and characterized. One is similar to, and may be the same as, the mitochondrial DNA polymerase gamma. The other two enzymes, one 7.5 S and the other 3.6 S, share some properties with DNA polymerases beta and gamma, e.g. their responses to certain inhibitors; however, they are not clearly identified with any previously well-characterized mammalian DNA polymerases. It is also demonstrated that the response of DNA polymerase gamma to N-ethylmaleimide is template dependent, and that DNA polymerase alpha has an authentic (albeit small) activity with poly(rA).oligo(dT).

Peptide mapping of the four subunits of the mouse DNA polymerase alpha-primase complex

We report a simple, two-step method (phosphocellulose and immunoaffinity column chromatographies) for purification of the mouse DNA polymerase alpha-primase complex. The advantages of this method over other procedures are its simplicity and rapidity, with little loss by proteolysis. Sedimentation analysis in a glycerol density gradient of the immunoaffinity-purified fraction revealed that four polypeptides with molecular weights of 180,000, 68,000, 54,000 and 46,000 in the enzyme fraction form a physical complex. Peptide mapping by reversed phase-high performance liquid chromatography demonstrated unequivocally that these four polypeptides constituting the complex are different entities.