Two DNA polymerases may be required for synthesis of the lagging DNA strand of simian virus 40

Agents discriminating between DNA polymerase alpha and DNA polymerases of class delta (polymerase delta or epsilon) were used to characterize steps in the synthesis of the lagging DNA strand of simian virus 40 during DNA replication in isolated nuclei. The synthesis of lagging-strand intermediates below 40 nucleotides, termed DNA primers (T. Nethanel, S. Reisfeld, G. Dinter-Gottlieb, and G. Kaufmann, J. Virol. 62:2867-2873, 1988), was selectively inhibited by butylphenyl dGTP or by neutralizing DNA polymerase alpha monoclonal antibodies. The synthesis of longer lagging chains of up to 250 nucleotides (Okazaki pieces) was affected to a lesser extent, possibly indirectly, by these agents. Aphidicolin, which inhibits both alpha- and delta-class enzymes, elicited the opposite pattern: DNA primers accumulated in its presence and were not converted into Okazaki pieces. These and previous data suggest that DNA polymerase alpha primase synthesizes DNA primers, whereas another DNA polymerase, presumably DNA polymerase delta or epsilon, mediates the conversion of DNA primers into Okazaki pieces.</jats:p

Assembly of simian virus 40 Okazaki pieces from DNA primers is reversibly arrested by ATP depletion

We have previously proposed that DNA polymerase alpha-primase provides short RNA-DNA precursors below 40 nucleotides (DNA primers), several of which assemble into an Okazaki piece after intervening RNA has been removed and the gaps have been filled by DNA polymerase delta (or epsilon) (T. Nethanel, S. Reisfeld, G. Dinter-Gottlieb, and G. Kaufmann, J. Virol. 62:2867-2873, 1988; T. Nethanel and G. Kaufmann, J. Virol. 64:5912-5918, 1990). In this report, we confirm and extend these conclusions by studying the effects of deoxynucleoside triphosphate (dNTP) concentrations and the presence of ATP on the occurrence, dynamics, and configuration of DNA primers in simian virus 40 replicative intermediate DNA. We first show that these parameters are not significantly affected by a 10-fold increase in dNTP precursor concentrations. We then demonstrate that Okazaki piece synthesis can be arrested at the level of DNA primers by ATP depletion. The arrested DNA primers faced short gaps of 10 to 20 nucleotides at their 3' ends and were progressively chased into Okazaki pieces when ATP was restored. ATP could not be substituted in this process by adenosine-5'-O-(3-thiotriphosphate) or adenyl-imidodiphosphate. The chase was interrupted by aphidicolin but not by butylphenyl-dGTP. The results implicate an ATP-requiring factor in the switch between the two DNA polymerases engaged in Okazaki piece synthesis. They also suggest that the replication fork advances by small, DNA primer-size increments.</jats:p

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.</jats:p

Distinctive activities of dna polymerases during human dna replication

The contributions of human DNA polymerases (pols) alpha, delta and epsilon during S-phase progression were studied in order to elaborate how these enzymes co-ordinate their functions during nuclear DNA replication. Pol delta was three to four times more intensely UV cross-linked to nascent DNA in late compared with early S phase, whereas the cross-linking of pols alpha and epsilon remained nearly constant throughout the S phase. Consistently, the chromatin-bound fraction of pol delta, unlike pols alpha and epsilon, increased in the late S phase. Moreover, pol delta neutralizing antibodies inhibited replicative DNA synthesis most efficiently in late S-phase nuclei, whereas antibodies against pol epsilon were most potent in early S phase. Ultrastructural localization of the pols by immuno-electron microscopy revealed pol epsilon to localize predominantly to ring-shaped clusters at electron-dense regions of the nucleus, whereas pol delta was mainly dispersed on fibrous structures. Pol alpha and proliferating cell nuclear antigen displayed partial colocalization with pol delta and epsilon, despite the very limited colocalization of the latter two pols. These data are consistent with models where pols delta and epsilon pursue their functions at least partly independently during DNA replication