DNA polymerase alpha cofactors C1C2 function as primer recognition proteins

Biochemical properties of the stimulatory activity of DNA polymerase alpha by the hyper-phosphorylated retinoblastoma protein

Previously, my colleagues and I have reported that the immunopurified hyper-phosphorylated retinoblastoma protein (ppRb) stimulates the activity of DNA polymerase alpha. I describe here the biochemical characteristics of this stimulatory activity. DNA polymerase alpha-stimulatory activity of ppRb was most remarkable when using activated DNA as a template-primer, rather than using poly(dT)-(rA)(10), poly(dA)-(dT)(12-18), and so on. Kinetic analysis showed that there was no significant difference in K(m) value for deoxyribonucleotides of DNA polymerase alpha in the presence of ppRb. Adding ppRb resulted in the overcoming pause site on the template, but did not affect the rate of misincorporation of incorrect deoxyribonucleotides. By adding ppRb, the optimal concentration of template-primer was shifted to a higher region, but not using M13 singly primed DNA. The ppRb seemed to assist the process that DNA polymerase alpha changed its conformation resulting in appropriate enzyme activity. These results suggest that ppRb affects both template-primer and DNA polymerase alpha and makes appropriate circumstances for the enzyme reaction.

Modulation of DNA polymerases alpha, delta and epsilon by lactate dehydrogenase and 3-phosphoglycerate kinase

Literature documents that glycolytic enzymes (among them lactate dehydrogenase and 3-phosphoglycerate kinase) can reside in nuclei of mammalian cells and exert functions in DNA replication, transcription and DNA repair, in addition to their role as catalysts in the cytoplasm. Transfer of glycolytic enzymes to cell nuclei requires modification, for example phosphorylation. We studied the effects of phosphorylated lactate dehydrogenase and 3-phosphoglycerate kinase on (i) UV-induced DNA repair, using permeabilized human fibroblasts, and (ii) in vitro DNA synthesis catalyzed by purified DNA polymerases alpha, delta, and epsilon from proliferating rat liver. (i) Phosphorylated lactate dehydrogenase stimulated UV-induced DNA repair synthesis in normal fibroblasts in a dose-dependent manner; the unphosphorylated enzyme slightly inhibited. In repair-deficient xeroderma pigmentosum fibroblasts reparative synthesis was not enhanced whether lactate dehydrogenase was phosphorylated or not, indicating that reparative DNA synthesis must be possible in order to be stimulated. (ii) Activity of purified DNA polymerases alpha, delta, and epsilon was differentially stimulated or inhibited, according to the phosphorylation status of lactate dehydrogenase. DNA polymerases were also modulated by 3-phosphoglycerate kinase, depending on the primer-templates used which were gapped DNA (mimicking a repair mode of DNA synthesis) or single-stranded M13 DNA (representing the replicative mode of DNA synthesis). Since glycolytic enzymes in cell nuclei retain binding ability for their cofactors, cytoplasmic substrates and inhibitors, a regulatory linkage might exist between the energy state of a cell and its replicative and reparative functions.

Annexin II tetramer: structure and function

The annexins are a family of proteins that bind acidic phospholipids in the presence of Ca2+. The interaction of these proteins with biological membranes has led to the suggestion that these proteins may play a role in membrane trafficking events such as exocytosis, endocytosis and cell-cell adhesion. One member of the annexin family, annexin II, has been shown to exist as a monomer, heterodimer or heterotetramer. The ability of annexin II tetramer to bridge secretory granules to plasma membrane has suggested that this protein may play a role in Ca(2+)-dependent exocytosis. Annexin II tetramer has also been demonstrated on the extracellular face of some metastatic cells where it mediates the binding of certain metastatic cells to normal cells. Annexin II tetramer is a major cellular substrate of protein kinase C and pp60src. Phosphorylation of annexin II tetramer is a negative modulator of protein function.

A single stranded DNA binding protein isolated from HeLa cells facilitates Ni2+ activation of DNA polymerases in vitro

The divalent nickel ion (Ni2+) is one of several metal ions that can substitute for Mg2+ in the activation of DNA polymerases in vitro, but usually with very low efficiency. We have purified and partially characterized a Ni(2+)-binding protein (p40) from HeLa cell extracts that can specifically enhance the polymerase activity of DNA polymerase alpha (pol alpha) and other DNA polymerases in response to Ni2+. This protein, with a molecular mass of 40 kDa, is a single stranded DNA binding protein that binds to a M13 DNA template-primer with an optimum stoichiometry of approximately 90 equiv of protein per equiv of DNA template and enhances the affinity of pol alpha for the primer-template. In the presence of Ni2+, p40 exhibits an increased affinity for DNA. The p40 increased by 3- to 6-fold the rates at which pol alpha and the Klenow fragment of Escherichia coli DNA polymerase I (KF) replicate different DNA templates in response to Ni2+. The low processivity of Ni(2+)-activated pol on primed M13 ssDNA was also enhanced by the presence of p40. The rates of Ni(2+)-dependent replication by inherently more processive enzymes, DNA polymerase delta and T4 DNA polymerase, were not significantly increased by p40 when M13 ssDNA was used as a template; however, p40 did increase the activity of T4 polymerase on an activated calf thymus DNA template. The protein did not stimulate Mg(2+)-activated DNA replication.

DNA helicase associated with DNA polymerase alpha: isolation by a modified immunoaffinity chromatography

We have developed a novel immunoaffinity method for isolating a DNA polymerase alpha-associated DNA helicase from the yeast Saccharomyces cerevisiae. Earlier we have reported the characterization of a DNA helicase activity associated with the multiprotein DNA polymerase alpha complex from yeast [Biswas, E. E., Ewing, C. M., & Biswas, S. B. (1993) Biochemistry 32, 3030-3027]. We report here the isolation of the DNA helicase from the DNA polymerase alpha (pol alpha) complex bound to an anti-pol alpha immunoaffinity matrix. The DNA helicase activity eluted at approximately 0.35 M NaCl concentration. The eluted ATPase/helicase peak was further purified by size-exclusion high-performance liquid chromatography (HPLC). At low ionic strength (50 mM NaCl), it remained associated with other proteins and eluted as a large polypeptide complex. At high ionic strength (500 mM NaCl), the helicase dissociated, and the eluted ATPase/helicase fraction contained 90-, 60-, and 50-kDa polypeptides. Photoaffinity cross-linking of helicase with ATP during the isolation process demonstrated a 90-kDa polypeptide to be the likely ATP binding component of the helicase protein. The DNA helicase has single-stranded DNA (ssDNA)-stimulated ATPase and dATPase activities. The ATPase activity was stimulated by yeast replication protein A (RPA). The DNA helicase activity was stimulated by Escherichia coli ssDNA binding protein and RPA. The DNA helicase migrated on a DNA template in the 5'-->3' direction which is also the overall direction of migration of pol alpha on the lagging strand of the replication fork.(ABSTRACT TRUNCATED AT 250 WORDS)

Purification and characterization of a yeast DNA polymerase alpha complex with associated primase, 5'-->3' exonuclease, and DNA-dependent ATPase activities

We have purified a multimeric form of yeast DNA polymerase alpha with DNA polymerase, primase, 5'-->3' exonuclease, and single-stranded (ss) DNA-dependent ATPase activities to near-homogeneity. The molecular mass of complex was 650 kDa with subunits ranging in sizes from 30 to 180 kDa. The alpha-subunit of the complex could be detected by DNA polymerase alpha antibody. No cross-reactivity of polypeptides within the complex was observed with antibodies directed against polymerase delta or epsilon. The multimeric polymerase alpha could be selectively inhibited by p-n-butylphenyl-dGTP (I50 of approximately 0.2 microM), p-n-butylanilino-dATP (I50 of 1.3 microM), and aphidicolin (I50 of 2.5 micrograms/mL). The complex synthesized RNA primers on various ssDNA templates and rapidly elongated these primers into nascent DNA fragments in the presence of required deoxynucleotides. It has a strong 5'-->3' exonuclease activity. In addition, the complex hydrolyzed both ATP and dATP in a ssDNA-dependent manner. Thus, the multiprotein complex of DNA polymerase alpha had multiple activities (primase, polymerase, and ATPase) which could act concertedly to synthesize primers and elongate the primers to nascent DNA fragments in the lagging strand of the fork.

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.

Cell cycle-dependent biosynthesis of Plasmodium falciparum DNA polymerase-alpha

The DNA polymerase-alpha of Plasmodium falciparum was characterized according to aphidicolin sensitivity and immunological reactivity with monoclonal anti-sera against human DNA polymerase-alpha. Two major (105 and 72 kDa) and two minor (180 and 130 kDa) catalytic subunits of P. falciparum DNA polymerase-alpha were detected on activity gels. Activity gels did not indicate the presence of a DNA polymerase-beta in P. falciparum. Metabolically labeled polypeptides at 180, 105, 72, and 52 kDa were immunoprecipitated from Plasmodium nuclear extracts with the anti-KB cell DNA polymerase-alpha monoclonal antibody and, by size, correspond to the major subunits of mammalian DNA polymerase-alpha. The monoclonal antibody also neutralized Plasmodium DNA polymerase activity. Plasmodium DNA polymerase was synthesized predominantly at an early schizont stage at which time the parasite began to synthesize its DNA and multiply. No evidence for phosphorylation of the major catalytic subunit was obtained. Plasmodium growth, DNA synthesis, and DNA polymerase activity were inhibited significantly in parallel by aphidicolin. These results suggest that P. falciparum has a typical eukaryotic DNA polymerase-alpha and that regulation of its activity appears to be at the transcriptional level.

Purification and characterization of DNA polymerases from Plasmodium berghei

DNA polymerases from the malaria parasite Plasmodium berghei were purified more than 50-fold. Several distinct enzymatic activities were isolated that could be distinguished by the use of various specific DNA polymerase inhibitors. In particular, subdivision into an aphidicolin-sensitive and an aphidicolin-resistant group was possible. Further analysis allowed a better comparison with host DNA polymerases and indicated that one aphidicolin-sensitive DNA polymerase resembled DNA polymerase alpha displaying processive DNA synthesis and using RNA primers, whereas another aphidicolin-sensitive DNA polymerase was distributive and only used DNA primers. Marked differences from the host enzymes do exist, however, such as insensitivity to BuPdGTP. Another P. berghei DNA polymerase was isolated that showed characteristics of a DNA polymerase beta-like enzyme, but which differed from host DNA polymerase beta in its insensitivity to dideoxynucleotides.

Eukaryotic DNA replication. Enzymes and proteins acting at the fork

A complex network of interacting proteins and enzymes is required for DNA replication. Much of our present understanding is derived from studies of the bacterium Escherichia coli and its bacteriophages T4 and T7. These results served as a guideline for the search and the purification of analogous proteins in eukaryotes. model systems for replication, such as the simian virus 40 DNA, lead the way. Generally, DNA replication follows a multistep enzymatic pathway. Separation of the double-helical DNA is performed by DNA helicases. Synthesis of the two daughter strands is conducted by two different DNA polymerases: the leading strand is replicated continuously by DNA polymerase delta and the lagging strand discontinuously in small pieces by DNA polymerase alpha. The latter is complexed to DNA primase, an enzyme in charge of frequent RNA primer syntheses on the lagging strand. Both DNA polymerases require several auxiliary proteins. They appear to make the DNA polymerases processive and to coordinate their functional tasks at the replication fork. 3'----5'-exonuclease, mostly part of the DNA polymerase delta polypeptide, can perform proof-reading by excising incorrectly base-paired nucleotides. The short DNA pieces of the lagging strand, called Okazaki fragments, are processed to a long DNA chain by the combined action of RNase H and 5'----3'-exonuclease, removing the RNA primers, DNA polymerase alpha or beta, filling the gap, and DNA ligase, sealing DNA pieces by phosphodiester bond formation. Torsional stress during DNA replication is released by DNA topoisomerases. In contrast to prokaryotes, DNA replication in eukaryotes not only has to create two identical daughter strands but also must conserve higher-order structures like chromatin.

Replicating premeiotic germ cells of the mouse contain a novel DNA primase stimulatory factor

A protein factor that stimulates DNA primase activity associated with DNA polymerase alpha has been identified in mouse germ cell populations enriched in spermatogonia and preleptotene spermatocytes. The partially purified factor enhances DNA primase activity from homologous cell types as well as DNA primase activity from Xenopus laevis oocytes in a poly dT or M 13 directed reaction. The factor does not stimulate DNA polymerase alpha activity in a gapped salmon sperm or poly dT-rA directed reaction. The DNA primase stimulating factor is identified in a male mouse germ cell population enriched in premeiotic cells; it is not detectable in middle-late pachytene spermatocytes, spermatids, Sertoli cells or fibroblasts.

A double-loop model for the replication of eukaryotic DNA

Coordinated DNA synthesis of both strands at the replication fork by a fixed 'replisome' may cause dynamic and topological problems. Based upon known properties of DNA helicase, DNA primase and DNA topoisomerases, and on novel properties of DNA polymerases and DNA ligase, we propose a 'double-loop' model for the replication of eukaryotic DNA that could minimize such problems.

Age-related changes in DNA polymerase alpha expression

DNA polymerase alpha isozymes differing in specific activity and affinity of binding to DNA were purified from human fibroblasts derived from donors of different ages. Fetal-derived fibroblasts expressed a single, high-activity enzyme (A2), with high affinity of binding to DNA. Adult-derived fibroblasts exhibited two forms of DNA polymerase alpha, one identical to the fetal enzyme, and a second with about tenfold less activity showing low affinity of binding to DNA (A1). The ratio of DNA polymerase A2/A1 decreased dramatically with age, from 100% A2 in fetal-derived fibroblasts to about 94% A1 in fibroblasts derived from a 66-year-old donor. The DNA binding affinity of polymerase alpha A1 from adult-derived fibroblasts increased concomitant with a significant increase in activity when the enzyme was treated with phosphatidylinositol-4-monophosphate (PIP), or with inositol-1, 4-bisphosphate (I(1,4)P2). The enzyme reverted back to a less active form, with loss of the noncovalently bound I(1,4)P2, as a function of time. When permeabilized human fibroblasts with low DNA excision repair capacity were treated with 7,8-dihydrodiol-9,10-epoxybenzo(a)-pyrene (BPDE) in the presence of 32P-ATP, phosphatidylinositol, and cycloheximide, excision repair was initiated and 32P-labeled DNA polymerase alpha was recovered in the absence of de novo protein synthesis. DNA synthesis associated with either scheduled DNA synthesis or BPDE-initiated excision repair declined as a function of increased age in human cells. The data suggest that the decline in both DNA excision repair-associated and mitogen-activated DNA synthesis may be correlated with decreased total intracellular levels of DNA polymerase and with the decline in polymerase alpha activity as a function of age, that DNA repair-associated initiation of DNA synthesis in adult-derived cells may increase with activation of a pool of low activity DNA polymerase alpha, and that DNA polymerase alpha activity increases as a function of enzyme interaction with a component of the PI phosphorylation cascade.

Stimulation of purified DNA polymerase alpha by various basic proteins which interact with activated DNA

Extensive purification of DNA polymerase alpha-primase resulted in a marked loss of the DNA polymerase alpha activity. This loss is due partly to the elimination of some basic proteins from the enzyme preparation since the activity of purified enzyme was stimulated 10- to 15-fold by the addition of various basic proteins, including all five classes of histones, protamine, poly-L-lysine, and poly-L-arginine, at a concentration of 2 micrograms/0.2 ml in the presence of 20 micrograms/0.2 ml of activated DNA. The optimum concentration of the basic proteins and the maximum activity attained at that concentration varied with varying concentrations of the template primer used, indicating that the observed stimulation is caused by an interaction between these basic proteins and activated DNA. The enzyme activity with an optimal concentration of activated DNA was markedly inhibited by the addition of denatured DNA. The suppressed enzyme activity could be restored by an appropriate concentration of histone H1. These results suggest that histone H1 and other basic proteins protect the enzyme from forming an abortive complex with single-stranded DNA or with a long stretch of the single-stranded part of activated DNA as single-stranded DNA-specific binding proteins do (M. Sapp, H. König, H. D. Riedel, A. Richter, and R. Knippers (1985) J. Biol. Chem. 260, 1550-1556). Spermine also showed a similar stimulatory effect. All acidic proteins tested were ineffective.

Functional identity of proliferating cell nuclear antigen and a DNA polymerase-delta auxiliary protein

The mechanism of replication of the simian virus 40 (SV40) genome closely resembles that of cellular chromosomes, thereby providing an excellent model system for examining the enzymatic requirements for DNA replication. Only one viral gene product, the large tumour antigen (large-T antigen), is required for viral replication, so the majority of replication enzymes must be cellular. Indeed, a number of enzymatic activities associated with replication and the S phase of the cell cycle are induced upon SV40 infection. Cell-free extracts derived from human cells, when supplemented with immunopurified SV40 large-T antigen support efficient replication of plasmids that contain the SV40 origin of DNA replication. Using this system, a cellular protein of relative molecular mass 36,000 (Mr = 36K) that is required for the elongation stage of SV40 DNA replication in vitro has been purified and identified as a known cell-cycle regulated protein, alternatively called the proliferating cell nuclear antigen (PCNA) or cyclin. It was noticed that, in its physical characteristics, PCNA closely resembles a protein that regulates the activity of calf thymus DNA polymerase-delta. Here we show that PCNA and the polymerase-delta auxiliary protein have similar electrophoretic behaviour and are both recognized by anti-PCNA human autoantibodies. More importantly, both proteins are functionally equivalent; they stimulate SV40 DNA replication in vitro and increase the processivity of calf thymus DNA polymerase-delta. These results implicate a novel animal cell DNA polymerase, DNA polymerase-delta, in the elongation stage of replicative DNA synthesis in vitro.

Detection and characterization of a novel factor that stimulates DNA polymerase alpha

A novel factor that stimulates DNA polymerase alpha activity on poly(dA) X oligo(dT) has been identified and partially purified from mouse FM3A cells. The assay system for the factor contained poly(ethylene glycol) 6000. The activities of DNA polymerase alpha on poly(dA) X oligo(dT) in the presence and absence of the stimulating factor were increased greatly by the addition of poly(ethylene glycol). Stimulation by the factor was observed at all the primer to template ratios tested from 0.01 to 0.3. The highest activity was observed at the ratio of 0.05, corresponding to about 3.3 primers on one template in the presence of the factor. The concentration of DNA polymerase alpha used in the assay affected the stimulation by the factor, and the stimulation became more prominent at concentrations of the enzyme lower than 0.04 unit per assay. The stimulating factor lowered the Km value of DNA polymerase alpha for the template-primer, though they had no effect on the Km value for dTTP substrate. The results of product analysis suggested that the stimulation by the factor is mainly due to the increase in the initiation frequency of DNA synthesis from the primers. The stimulating factor specifically stimulated DNA polymerase alpha but not DNA polymerases beta and gamma. Furthermore, the factor formed a complex with DNA polymerase alpha under a certain condition.

Mutational specificity of animal cell DNA polymerases

Since DNA polymerases are involved in DNA replication, recombination, and repair, the frequency with which these enzymes commit errors during synthesis is likely to be an important factor in controlling mutation rates in cells. The fidelity of DNA polymerases was originally studied by following misincorporation using synthetic nucleic acid templates containing only one or two bases. Later, by assaying for reversion of an amber codon after copying phi X174 single-stranded DNA molecules, the base substitution accuracy of in vitro DNA synthesis on natural DNA was determined. Most recently, a forward mutation assay has been developed that uses gap-filling synthesis on an M13mp2 DNA template, thus permitting the detection of a variety of different errors during DNA synthesis on natural DNA templates. Detailed mutational spectra for animal cell polymerases-alpha, beta, and gamma have been determined and demonstrate that a variety of errors can be generated by these purified enzymes. The frequencies of base mispairs, base additions, and deletion errors by DNA polymerases vary widely and depend on both the DNA sequence and the enzyme used. An understanding of the mechanisms by which DNA polymerases avoid or generate various mutations depends on the definition of the parameters that influence the frequency and specificity of particular errors. Future experiments will combine the use of the methods available to measure fidelity with advances in DNA replication enzymology and should lead to exciting new insights into the mechanisms of spontaneous mutagenesis.

A DNA template recognition protein: partial purification from mouse liver and stimulation of DNA polymerase alpha

A protein that specifically enhances up to 13-fold the rate of copying of poly(dT) template by DNA polymerase alpha was partially purified from chromatin of regenerating mouse liver cells. This stimulatory protein, designated herein factor D, also increases 2-3-fold the activity of polymerase alpha with heat-denatured DNA and with primed, circular single-stranded phi X174 DNA. However, factor D has no detectable effect on the copying by polymerase alpha of poly(dG), poly(dA), and poly(dC) templates. Activity of mouse DNA polymerase beta is not affected by factor D with all the tested templates. In contrast to polymerase alpha, factor D is resistant to inactivation by N-ethylmaleimide and calcium ions, but it is readily heat-inactivated at 46 degrees C and is inactivated by trypsin digestion. Partially purified factor D is not associated with detectable activities of DNA polymerase, DNA primase, deoxyribonucleotidyl terminal transferase, and endo- or exodeoxyribonuclease.

Enzymology of DNA replication and repair in the brain

A number of enzymes thought to be involved in DNA replication have been identified in the brain. These include single-stranded DNA-binding proteins, topoisomerases I and II, DNA polymerase alpha, a protein that binds Ap4A and might be classified as a DNA polymerase alpha accessory protein, RNase H, DNA polymerase beta, DNA ligase, an endo- and an exonuclease of unknown function, DNA methyl transferase and poly(ADPR) synthase. In contrast, little is known about the enzymology of DNA repair in brain. The few enzymes identified comprise uracil-DNA glycosylase, DNA polymerase beta, DNA polymerase alpha (which in neurons is present only at immature stages), DNA ligase, poly(ADPR) synthase, and O6-alkylguanine-DNA alkyltransferase. In addition, an exonuclease acting on depurinated single-stranded DNA (tentatively listed here as 3'----5' exonuclease), an endonuclease of unknown function as well as ill-defined acid and alkaline deoxyribonucleases also occur in brain.

5',5'''-P1, P4 diadenosine tetraphosphate (Ap4A): a putative initiator of DNA replication

The proposal that Ap4A acts as an inducer of DNA replication is based primarily on two pieces of evidence (7). The intracellular levels of Ap4A increase ten- to 1000-fold as cells progress into S phase and the introduction of Ap4A into nonproliferating cells stimulated DNA synthesis. There is also some additional suggestive evidence such as the binding of Ap4A to a protein that is associated with multiprotein forms of the replicative DNA polymerase alpha and the ability of this enzyme to use Ap4A as a primer for DNA synthesis in vitro with single-stranded DNA templates. These observations have stimulated interest in the cellular metabolism of Ap4A. This is well since there is a great need for additional experimentation in order to clearly establish Ap4A as an inducer of DNA replication. Microinjection experiments of Ap4A into quiescent cells are needed in order to ascertain if Ap4A will stimulate DNA replication and possibly cell division in intact cells. Studies of the effects of nonhydrolyzable analogs of Ap4A on DNA replication in intact quiescent cells could also prove valuable. Although Ap4A can function as a primer for in vitro DNA synthesis by DNA polymerase alpha this may not be relevant in regard to its in vivo role in DNA replication. Ap4A in vivo could interact with key protein(s) in DNA replication and in this way act as an effector molecule in the initiation of DNA replication. In this regard the interaction of Ap4A with a protein associated with a multiprotein form of DNA polymerase alpha isolated from S-phase cells is of interest. More experiments are required to determine if there is a specific target protein(s) for Ap4A in vivo and what its role in DNA replication is. The cofractionation of tryptophanyl-tRNA synthetase with the replicative DNA polymerase alpha from animal and plant cells is of interest. The DNA polymerase alpha from synchronized animal cells also interacted with Ap4A. Although the plant cell alpha-like DNA polymerase did not interact with Ap4A this DNA polymerase was not a multiprotein form of polymerase alpha and the synchrony of the wheat germ embryos was not known. A possible tie between protein-synthesizing systems and the regulation of proteins involved in DNA replication may exist. The requirement of protein synthesis for the initiation of DNA replication has long been known. Also, it is well established that many temperature-sensitive mutants for tRNA synthetases are also DNA-synthesizing mutants. More investigation in this area may be warranted.(ABSTRACT TRUNCATED AT 400 WORDS)

The role of palindromic and non-palindromic sequences in arresting DNA synthesis in vitro and in vivo

The nature of specific DNA sequences that arrest synthesis by mammalian DNA polymerase alpha in vitro was analyzed using circular, single-stranded M13 or phi X174 virion DNA templates annealed to a unique, terminally labeled, DNA primer. This method rigorously defined both the starting nucleotide position and the direction of synthesis, as well as making the amount of radioactivity proportional to the number rather than the length of nascent DNA chains. The precise nucleotide locations of arrest sites were determined over templates with complementary sequences by cloning unique DNA restriction fragments into M13 DNA and isolating virions containing either the Watson or Crick strand. Results were correlated with the locations of palindromic (self-complementary) sequences, repeated sequences, and repeated sequences with mirror-image orientation. Two classes of DNA synthesis arrest sites were identified, distinct in structure but equivalent in activity. Class I sites consisted of palindromic sequences that formed a stable hairpin structure in solution and arrested DNA polymerase on both complementary templates. The polymerase stopped precisely at the base of the duplex DNA stem, regardless of the direction from which the enzyme approached. Class II sites consisted of non-palindromic sequences that could not be explained by either secondary structure or sequence symmetry elements, and whose complementary sequence was not an arrest site. Size limits, orientation and some sequence specificity for arrest sites were suggested by the data. Arrest sites were also observed in vivo by mapping the locations of 3'-end-labeled nascent simian virus 40 DNA strands throughout the genome. Arrest sites closest to the region where termination of replication occurs were most pronounced, and the locations of 80% of the most prominent sites appeared to be recognized by alpha-polymerase on the same template in vitro. However, class I sites were not identified in vivo, suggesting that palindromic sequences do not form hairpin structures at replication forks.

Sequence specificity for the initiation of RNA-primed simian virus 40 DNA synthesis in vivo

Analysis of the nucleotide sequences at the 5' ends of RNA-primed nascent DNA chains (Okazaki fragments) and of their locations in replicating simian virus 40 (SV40) DNA revealed the precise nature of Okazaki fragment initiation sites in vivo. The primary initiation site for mammalian DNA primase was 3'-purine-dT-5' in the DNA template and the secondary site was 3'-purine-dC-5', with the 5' end of the RNA primer complementary to either the dT or dC. The third position of the initiation site was variable with a preference for dT or dA. About 81% of the available 3'-purine-dT-5' sites and 20% of the 3'-purine-dC-5' sites were used. Purine-rich sites, such as PuPuPu and PyPuPu , were excluded. The 5'-terminal ribonucleotide composition of Okazaki fragments corroborated these conclusions. Furthermore, the length of individual RNA primers was not unique, but varied in size from six to ten bases with some appearing as short as three bases and some as long as 12 bases, depending on the initiation site used. This result was consistent with the average size (9 to 11 bases) of RNA primers isolated from specific regions of the genome. Excision of RNA primers did not appear to stop at the RNA-DNA junction, but removed a variable number of deoxyribonucleotides from the 5' end of the nascent DNA chain. Finally, only one-fourth of the replication forks contained an Okazaki fragment, and the distribution of their initiation sites between the two arms revealed that Okazaki fragments were initiated exclusively (99%) on retrograde DNA templates. The data obtained at two genomic sites about 350 and 1780 bases from ori were essentially the same as that reported for the ori region (Hay & DePamphilis , 1982), suggesting that the mechanism used to synthesize the first DNA chain at ori is the same as that used to synthesize Okazaki fragments throughout the genome.