RNA-primed DNA synthesis: specific catalysis by HeLa cell DNA polymerase alpha.

We have analyzed and compared the responses of the three major HeLa cell DNA polymerases (alpha, beta, and gamma) to a HeLa DNA template with short RNA or DNA primers hybridized to it. Only DNA polymerase alpha is able to synthesize DNA covalently bonded to the RNA primer via a 3' yields 5' phosphodiester bond. 32P transfer experiments showed that all combinations of ribo- and deoxyribonucleotides are represented in the RNA-DNA linkages but their distribution is nonrandom. The RNA-DNA linked molecules base-paired to a HeLa DNA template strand represent a possible "natural" in vitro primer-template for DNA polymerases and can be extended by all three DNA polymerases (alpha, beta, and gamma). These findings indicate that DNA polymerases beta and gamma are capable of DNA-primed but not RNA-PRIMED DNA synthesis, while DNA polymerase alpha is capable of both RNA-primed and DAN-primed DNA synthesis.     

Synthesis by the DNA primase of Drosophila melanogaster of a primer with a unique chain length.

The primase associated with the DNA polymerase alpha from embryos of Drosophila melanogaster catalyzes the synthesis of ribo-oligonucleotide primers on single-stranded M13 DNA or polydeoxythymidylate templates, which can be elongated by DNA polymerase action [Conaway, R. C. & Lehman, I. R. (1982) Proc, Natl. Acad. Sci, USA 79, 2523--2527]. The primers synthesized in a coupled primase-DNA polymerase alpha reaction with an M13 DNA template are of a unique size (15 residues); those synthesized with poly(dT) range from 8 to 15 nucleotides. Primer synthesis is initiated at multiple but nonrandom sites. Like the DNA primase of Escherichia coli and the comparable activity in intact nuclei of polyoma-infected mouse cells, the DNA primase of D. melanogaster can substitute deoxynucleotides for ribonucleotides during primer synthesis.     

RNA-Primed DNA Synthesis In Vitro

In vitro DNA synthesis on single-stranded circular DNA can be initiated by RNA primers. RNA chains are covalently extended by DNA polymerase II from KB cells and DNA polymerase I from Micrococcus luteus, but not by an RNA-dependent DNA polymerase from avian myeloblastosis virus. The reaction product consists of DNA chains with a piece of RNA at their 5'-ends, hydrogen bonded to the template DNA. The primer RNA is linked to the product DNA via a 3':5'-phosphodiester bond, and can be specifically removed by ribonuclease H. The possible role of ribonuclease H in RNA-primed DNA synthesis in vivo is discussed.     

DNA primase activity associated with DNA polymerase alpha from Xenopus laevis ovaries.

One of the two forms of DNA polymerase alpha from ovaries of the frog Xenopus laevis catalyzed ribonucleoside triphosphate-dependent DNA synthesis on single-stranded circular fd phage DNA templates. DNA synthesis was dependent on ATP and added template. CTP, GTP, and UTP stimulated DNA synthesis but were not required and could not substitute for ATP. DNA synthesis was not inhibited by alpha-amanitin. Neither poly(dT) nor double-stranded DNA served as template. Analysis of [32P]-dTMP-labeled product by neutral and alkaline agarose gel electrophoresis showed that 0.1- to 1-kilobase DNA fragments (average size of approximately equal to 0.25 kilobase) were synthesized. The fragments were not covalently linked to the template. Either [alpha-32P]NMP, [gamma-32P]ATP, or [gamma-32P]GTP were incorporated also into the product. Analysis of the product after hydrolysis by KOH, alkaline phosphatase, or bacteriophage T4 3' leads to 5' exonuclease showed the presence of a small oligoribonucleotide primer at the 5' end of the newly synthesized DNA. NTP-dependent DNA-synthesizing activity copurified on six columns and cosedimented during glycerol gradient centrifugation with one form of DNA polymerase alpha activity but not with the other form. These results suggest that DNA primase activity is associated with one of the two forms of X. laevis DNA polymerase alpha.     

A Single Subunit from Avian Myeloblastosis Virus with Both RNA-Directed DNA Polymerase and Ribonuclease H Activity

Two structurally distinct forms of RNA-directed DNA polymerase from avian myeloblastosis virus were resolved by chromatography on phosphocellulose and purified. In addition to RNA-directed DNA polymerase activity, both enzymes had ribonuclease H (RNase H) activity, which degraded the RNA moiety of RNA.DNA hybrids. As determined by sodium dodecyl sulfate-polyacrylamide disc-gel electrophoresis, one form had two subunits, alpha (alpha) and beta (beta), with molecular weights of 65,000 and 105,000, respectively. The other had a single subunit, alpha, with a molecular weight of 65,000. The sedimentation coefficients of alphabeta and alpha, determined by glycerol gradient centrifugation in 0.35 M KCl, were 7.8 S and 5.2 S, respectively. Both enzymes had similar antigenic determinants and could not be distinguished by a differential response to several different RNA and DNA templates. We suggest that alpha, which contains both RNA-directed DNA polymerase and RNase H activity, is derived by dissociation of alphabeta; the function of the beta subunit is unknown.     

A DNA primase activity associated with DNA polymerase alpha from Drosophila melanogaster embryos.

Preparations of DNA polymerase alpha from early embryos of Drosophila melanogaster catalyze the ATP-dependent synthesis of DNA with single-stranded M13 DNA or poly(dT) templates. In the case of M13 DNA, GTP, but not UTP or CTP, can replace ATP. The reaction is completely dependent on added template and is not inhibited by alpha-amanitin. Alkaline hydrolysis of the product synthesized in the presence of [alpha-32P]dATP and poly(dT) generates 32P-labeled 3'(2') adenylate, showing that a covalent ribo-deoxynucleotide linkage is formed. Furthermore, incorporation of ribonucleotides occurs at the 5' end of the newly synthesized polynucleotide chain. These findings are consistent with the hypothesis that a ribo-oligonucleotide primer is synthesized by primase action and subsequently elongated by DNA polymerase. Under the appropriate conditions, DNA polymerase I from Escherichia coli can elongate primers formed by primase in the presence of ATP and poly(dT). Primase activity copurifies with DNA polymerase alpha and may be part of the multisubunit polymerase molecule.     

DNA polymerase beta bypasses in vitro a single d(GpG)-cisplatin adduct placed on codon 13 of the HRAS gene.

We have examined the capacity of calf thymus DNA polymerases alpha, beta, delta, and epsilon to perform in vitro translesion synthesis on a substrate containing a single d(GpG)-cisplatin adduct placed on codon 13 of the human HRAS gene. We found that DNA synthesis catalyzed by DNA polymerases alpha, delta, and epsilon was blocked at the base preceding the lesion. Addition of proliferating cell nuclear antigen to DNA polymerase delta and replication protein A to DNA polymerase alpha did not restore their capacity to elongate past the adduct. On the other hand, DNA polymerase beta efficiently bypassed the cisplatin adduct. Furthermore, we observed that DNA polymerase beta was the only polymerase capable of primer extension of a 3'-OH located opposite the base preceding the lesion. Likewise, DNA polymerase beta was able to elongate the arrested replication products of the other three DNA polymerases, thus showing its capacity to successfully compete with polymerases alpha, delta, and epsilon in the stalled replication complex. Our data suggest (i) a possible mechanism enabling DNA polymerase beta to bypass a d(GpG)-cisplatin adduct in vitro and (ii) a role for this enzyme in processing DNA damage in vivo.     

Functional roles of DNA polymerases beta and gamma.

The physiological functions of DNA polymerases (deoxynucleosidetriphosphate:DNA deoxynucleotidyltransferase, EC 2.7.7.7) beta and gamma were investigated by using neuronal nuclei and synaptosomes isolated from rat brain. UV irradiation of neuronal nuclei from 60-day-old rats resulted in a 7- to 10-fold stimulation of DNA repair synthesis attributable to DNA polymerase beta which, at this developmental stage, is virtually the only DNA polymerase present in the nuclei. No repair synthesis could be elicited by treating the nuclei with N-methyl-N-nitrosourea, but this way probably due to the inability of brain tissues to excise alkylated bases from DNA. The role of DNA polymerase gamma was studied in synaptosomes by using a system mimicking in vivo mitochondrial DNA synthesis. By showing that, under these conditions, DNA replication occurs in mitochondria, and exploiting the fact that DNA polymerase gama is the only DNA polymerase present in mitochondria, evidence was obtained for a role of DNA polymerase gamma in mitochondrial DNA replication. Based on these results and on the wealth of literature on DNA polymerase alpha, we conclude that DNA polymerase alpha is mainly responsible for DNA replication in nuclei, DNA polymerase beta is involved in nuclear DNA repair, and DNA polymerase gamma is the mitochondrial replicating enzyme. However, minor roles for DNA polymerase alpha in DNA repair or for DNA polymerase beta in DNA replication cannot be excluded.     

RNA-directed DNA synthesis by the DNA polymerase of Rous sarcoma virus: structural and functional identification of 4S primer RNA in uninfected cells.

The RNA-directed DNA polymerase of Rous sarcoma virus requires a 4S RNA molecule as primer for the initiation of DNA synthesis on the viral 70S RNA genome. We have now functionally identified primer activity in uninfected cells on the basis of the capacity of cellular 4S RNA to actively participate in the initiation of DNA synthesis by the RNA-directed DNA polymerase of Rous sarcoma virus in vitro. This was accomplished by reconstitution experiments in which 4S RNA from uninfected avian cells was tested for its ability to restore template activity to the viral RNA genome from which all primer had been removed. Similar reconstitution experiments were employed to demonstrate a primer activity in the 4S RNA population of duck, mouse, and human cells. Primer activity appears to be absent in lower eukaryotic or prokaryotic cells. Unambiguous identification of the Rous sarcoma virus primer molecule in uninfected cells was accomplished by directly purifying a 4S RNA molecule from the bulk of host cell transfer RNA and establishing structural similarities between this cellular 4S RNA species and the Rous sarcoma virus primer by two-dimensional paper electrophoresis of oligonucleotides obtained from a T1 ribonuclease digest of the RNA species. We conclude that the Rous sarcoma virus DNA polymerase can utilize a host cell molecule as primer for the initiation of RNA-directed DNA synthesis in vitro.     

Comparative Properties of RNA and DNA Templates for the DNA Polymerase of Rous Sarcoma Virus

Several natural RNAs were compared with respect to their template activities for the DNA polymerase of Rous Sarcoma Virus during a 2-hr incubation period. 60-70S viral RNA was found to be a 5- to 10-fold better template than heat-dissociated Rous viral RNA, influenza virus RNA, tobacco mosaic virus RNA, or ribosomal RNA. Denatured salmon DNA is a little better, and poly(dAT) is 2-4 times better as a template for the enzyme than is 60-70S Rous viral RNA. The 60-70S RNAs of different strains of avian tumor viruses have very similar template activities for a given avian tumor virus DNA polymerase. Oligo(dT) or oligo(dC) were found to enhance the template activity of heat-dissociated Rous viral RNA 20- to 30-fold, and that of other natural RNAs tested one- to several-fold. DNA syntheses of 1-24% were obtained during a 2-hour incubation of the enzyme with the above RNA templates. The results suggest that the enzyme prefers partially doublestranded or hybrid regions of RNAs for optimal DNA synthesis, but certain regions of single-stranded RNA can also serve as templates.Poly(dAT) competes with viral RNA for purified DNA polymerase during DNA synthesis, as would be expected if RNA- and DNA-dependent DNA synthesis was performed by at least one common active site of the same enzyme.     

Accessory proteins for DNA polymerase alpha activity with single-strand DNA templates

Three forms of DNA polymerase alpha [DNA nucleotidyltransferase (DNA-directed), EC 2.7.7.7] were partially purified from the combined nuclear extract and postmicrosomal supernatant solution of synchronized HeLa cells. These enzymes, designated DNA polymerases alpha 1, alpha 2, and alpha 3, on the basis of their order of elution from DEAE-Bio-Gel, differ in their abilities to utilize single-strand DNA templates. DNA polymerase alpha 2 has equal catalytic activities with activated and single-strand DNAs as template-primers. DNA polymerase alpha 1 has only partial catalytic activity with single-strand DNA templates, and DNA polymerase alpha 3 is essentially inactive with this template. Successive steps of hydrophobic affinity chromatography and phosphocellulose chromatography of DNA polymerase alpha 2 resolved the polymerase alpha activity and two protein factors (C1 and C2) that are required for its catalytic activity with a DNA template-primer that contains extended single-strand regions. In the absence of the factors, DNA polymerase alpha activity is measurable with activated but not single-strand DNA templates. In the presence of the C1 and C2 factors DNA polymerase alpha activity with single-strand DNA templates is restored to about 75% of the catalytic activity of DNA polymerase alpha 2 with this template.     

Proofreading by the epsilon subunit of Escherichia coli DNA polymerase III increases the fidelity of calf thymus DNA polymerase alpha.

Addition of the 3'----5' proofreading exonuclease, epsilon subunit of Escherichia coli DNA polymerase III, to DNA polymerase alpha from calf thymus has been studied. Alone, calf thymus DNA polymerase alpha terminates in vitro DNA synthesis upon insertion of noncomplementary nucleotides. Upon addition of the epsilon subunit, DNA polymerase alpha elongates the newly synthesized DNA as a result of hydrolysis of the 3'-terminal mispair. The fidelity of DNA polymerase alpha in vitro is increased 7-fold by addition of the exonuclease. The functional interaction between DNA polymerase alpha and the epsilon subunit is independent of any detectable physical association. This suggests that a mechanism for proofreading could exist in mammalian cells involving sequential catalysis by DNA polymerase alpha excision of errors by a separate 3'----5' exonuclease, and further elongation onto correctly base-paired 3' termini by DNA polymerase alpha.     

A DNA polymerase alpha pause site is a hot spot for nucleotide misinsertion.

In this study we examined whether the arrest of DNA polymerase alpha (pol alpha)-catalyzed DNA synthesis at template pause sites entails terminal nucleotide misincorporation. An approach was developed to identify the 3'-terminal nucleotide in nascent DNA chains that accumulate at pause sites. A radioactive 5'-end-labeled primer was annealed to a bacteriophage M13mp2 single-stranded DNA template and elongated by pol alpha. Individual DNA chains that were accumulated at pause sites were resolved by sequencing gel electrophoresis, isolated, and purified. These DNA chains were elongated by pol alpha by using four annealed synthetic DNA templates, each of which contained a different nucleotide at the position opposite the 3' terminus of the arrested chain. Owing to the high preference of pol alpha for matched-over-mismatched primer termini, only those templates that contain a nucleotide that is complementary to the 3' terminus of the isolated pause-site chain are copied. Electrophoresis of product DNA showed the extent of copying of each template and thus identified the 3'-terminal nucleotide of the pause-site chains. We found that product DNA chains terminate with a noncomplementary 3'-terminal nucleotide opposite pause sites within the sequence 3'-d(AAAA)-5' at positions 6272-6269 of the M13mp2 genome. pol alpha catalyzed misincorporation of dG or dA into the 3' terminus of nascent chains opposite two of the M13mp2 template dA residues. A similar analysis of a different pause site did not reveal significant misincorporation opposite template dC. These results suggest that some but not all sites at which pol alpha pauses may constitute loci of mutagenesis.     

Primer Requirement and Template Specificity of the DNA Polymerase of RNA Tumor Viruses

Polyribonucleotides will act as efficient templates for the DNA polymerases found in the virions of avian myeloblastosis virus and mouse leukemia virus if a short complementary oligodeoxyribonucleotide primer is added. Synthesis of the complementary polydeoxyribonucleotide continues until an amount of polymer equal to the amount of initial template has been produced. The two viruses show slightly different specificities toward the four homoribopolymers. Polydeoxyribonucleotides are generally much poorer templates than the homologous polyribonucleotides, in most cases yielding no detectable synthesis. The DNA polymerase of RNA tumor viruses, therefore, have the same requirements for activity as do other DNA polymerases, except that they prefer polyribonucleotides over polydeoxyribonucleotides as templates.     

A Possible Role for RNA Polymerase in the Initiation of M13 DNA Synthesis

The conversion of single-stranded DNA of bacteriophage M13 to the double-stranded replicative form in Escherichia coli is blocked by rifampicin, an antibiotic that specifically inhibits the host-cell RNA polymerase. Chloramphenicol, an inhibitor of protein synthesis, does not block this conversion. The next stage in phage DNA replication, multiplication of the doublestranded forms, is also inhibited by rifampicin; chloramphenicol, although inhibitory, has a much smaller effect. An E. coli mutant whose RNA polymerase is resistant to rifampicin action does not show inhibition of M13 DNA replication by rifampicin. These findings indicate that a specific rifampicin-RNA polymerase interaction is responsible for blocking new DNA synthesis. It now seems plausible that RNA polymerase has some direct role in the initiation of DNA replication, perhaps by forming a primer RNA that serves for covalent attachment of the deoxyribonucleotide that starts the new DNA chain.