DNA polymerase alpha is associated with replicating SV40 nucleoprotein complexes.

Simian virus 40 (SV40) nucleoprotein complexes were extracted from nuclei of infected monkey cells and fractionated on neutral sucrose density gradients. Complexes which contained replicating SV40 DNA (95S) separated well from those containing closed circular supercoiled viral DNA (75S). DNA polymerase activity was associated with the replicating nucleoprotein complexes but not with the slower sedimenting complexes. This DNA polymerase activity coprecipitated with the nucleoprotein complexes in the presence of MgCl2 and remained associated with the 95S complexes. This DNA polymerase activity has been identified as primarily DNA polymerase alpha on the basis of its sedimentation behavior, optimum salt concentration, and sensitivity to N-ethylmaleimide. DNA polymerase gamma activity was also detected in the complexes, but DNA polymerase beta was not associated with the complexes.     

In situ nucleoprotein structure involving origin-proximal SV40 DNA control elements.

Nucleoprotein structures at the SV40 GC-box and adjacent AT-rich region have been probed by nucleases in permeabilized cells at nucleotide level resolution. The patterns of nuclease protection and hypersensitivity in these permeabilized cells that allow initiation of RNA and DNA synthesis are quite different from those observed in isolated nuclei that are inactive. Whereas simple DNA protection by factors is found in nuclei, the pattern in permeabilized cells includes very strong nuclease hypersensitive sites. Their arrangement suggests that the region exists as a higher order nucleoprotein complex in vivo, which is disturbed during the preparation of nuclei. The pattern is also found to be disturbed in permeabilized cells when T-antigen is inactivated by temperature-sensitive mutation. Since T-antigen origin binding sites and the GC-box region have been shown previously to interact functionally, the existence of a higher order structure involving both components provides a likely physical basis for the functional interaction of separate control elements.     

Nicking-closing enzyme is associated with SV40 DNA in vivo as a sodium dodecyl sulfate-resistant complex.

A fraction of the cellular nicking-closing (NC) enzyme cosediments with SV40 chromatin isolated after Triton X-100 treatment of infected cells nuclei. Extraction of viral DNA according to the Hirt procedure by treatment of infected cells with sodium dodecyl sulfate (SDS) followed by sedimentation in sucrose gradient to separate the DNA from the bulk of detergent also revealed NC activity associated with DNA. Reconstitution experiments showed that only prebinding of the NC enzyme to DNA protects it against irreversible inactivation by SDS. These results suggest that a fraction of the cellular NC activity is indeed associated with the viral chromosome in vivo.     

Interaction of SV40 T-antigen with homologous and heterologous DNA

Using the DNA filter binding assay, the effects of ionic strength and pH on SV40 T-antigen interaction with viral DNA were studied. The apparent association constants for T-antigen binding to SV40 DNA in Scatchard coordinates in the presence of 40 mM NaCl are equal to 0.67 . 10(6) M-1 (pH 6.0) and 0.86 x 10(7) M-1 (pH 7.4). These data indicate that the interaction between T-antigen and SV40 DNA is more specific at pH 7.4. The coincident values of association constants for T-antigen binding to viral and cellular DNAs (Ka = 0.9 x 10(7) M-1 for cellular DNA) at pH 7.4 and the absence of competition between the two DNA species upon binding with T-antigen suggest that viral and cellular DNAs possess similar sites for T-antigen binding. Denatured DNA competes with viral DNA only at pH 6.0, when the T-antigen--SV40 DNA interaction is less specific.     

Random location and absence of movement of the nucleosomes on SV 40 nucleoprotein complex isolated from infected cells.

SV 40 nucleoprotein complexes (NPC) containing viral DNA and cellular histones were extracted from nuclei of permissive cells and treated with either EcoR1 or BamI endonucleases. The fraction of SV 40 linear NPC, monitored by electron microscopy, reached a plateau value of about 15–20% after one hour and no further change occurred during further incubation for 2 hours. Free viral DNA added to the incubation mixture was totally cleaved. During the incubations of NPC and DNA, no redistribution of histones occurred, all the complexe still contained on average 21 nucleosomes and no nucleosomes were generated on the naked viral DNA. Our results suggest a random location and absence of movement of the nucleosomes in vitro on SV 40 nucleoprotein complex isolated from infected cells.     

Assembly of the replication initiation complex on SV40 origin DNA

The assembly of the complex that forms over the simian virus 40 origin to initiate DNA replication is not well understood. This complex is composed of the virus-coded T antigen and three cellular proteins, replication protein A (RPA), DNA polymerase α/primase (pol/prim) and topoisomerase I (topo I) in association with the origin. The order in which these various proteins bind to the DNA was investigated by performing binding assays using biotinylated origin DNA. We demonstrate that in the presence of all four proteins, pol/prim was essential to stabilize the initiation complex from the disruptive effects of topo I. At the optimal concentration of pol/prim, topo I and RPA bound efficiently to the complex, although pol/prim itself was not detected in significant amounts. At higher concentrations less topo I was recruited, suggesting that DNA polymerase is an important modulator of the binding of topo I. Topo I, in turn, appeared to be involved in recruiting RPA. RPA, in contrast, seemed to have little or no effect on the recruitment of the other proteins to the origin. These and other data suggested that pol/prim is the first cellular protein to interact with the double-hexameric T antigen bound to the origin. This is likely followed by topo I and then RPA, or perhaps by a complex of topo I and RPA. Stoichiometric analysis of the topo I and T antigen present in the complex suggested that two molecules of topo I are recruited per double hexamer. Finally, we demonstrate that DNA has a role in recruiting topo I to the origin.     

Interaction of DNA polymerase alpha-primase with cellular replication protein A and SV40 T antigen.

The purified human single-stranded DNA binding protein, replication protein A (RP-A), forms specific complexes with purified SV40 large T antigen and with purified DNA polymerase alpha-primase, as shown by ELISA and a modified immunoblotting technique. RP-A associated efficiently with the isolated primase, as well as with intact polymerase alpha-primase. The 70 kDa subunit of RP-A was sufficient for association with polymerase alpha-primase. Purified SV40 large T antigen bound to intact RP-A and to polymerase-primase, but not to any of the separated subunits of RP-A or to the isolated primase. These results suggest that the specific protein-protein interactions between RP-A, polymerase-primase and T antigen may play a role in the initiating of SV40 DNA replication.     

Purification and characterization of the DNA untwisting enzyme from rat liver.

The DNA untwisting enzyme has been purified approximately 300-fold from rat liver nuclei. The protein is greater than 90% pure as judged by sodium dodecyl sulfate-acrylamide gel electrophoresis. The native enzyme has a molecular weight between 64 000 and 68 000 and is composed of a single polypeptide chain. Evidence is presented that the protein can act catalytically. A trace amount of endonuclease activity associated with the most pure fraction could be a contaminant or it could be due to the action of the DNA untwisting enzyme itself.     

Absence of nucleosomes in a histone-containing nucleoprotein complex obtained by dissociation of purified SV40 virions

Reduction of disulfide bonds involving the major capsid protein with dithiothreitol and removal of the calcium ions by EGTA disrupts the simian virus 40 virions. This process yields normal circular viral minichromosomes containing the four core histones and traces of the capsid proteins at pH values higher than 8.5. However, when carried out at pH 7.5, this procedure yields nucleoprotein complexes that contain both histones and the viral structural proteins. These pH 7.5 complexes appear as circular structures with a mean of 93 +/- 17 beads with a diameter of 7 nm and no visible nucleosomes when observed by electron microscopy. In contrast to the compaction of the viral DNA in minichromosomes, the length of these beaded structures is roughly the same as free DNA. We suggest that VP1, the major capsid protein, can act as a nucleosome unfolding agent in neutral pH and low ionic strength.     

Species-specific functional interactions of DNA polymerase alpha-primase with simian virus 40 (SV40) T antigen require SV40 origin DNA.

Physical and functional interactions of simian virus 40 (SV40) and polyomavirus large-T antigens with DNA polymerase alpha-primase were analyzed to elucidate the molecular basis for the species specificity of polymerase alpha-primase in viral DNA replication. SV40 T antigen associated more efficiently with polymerase alpha-primase in crude human extracts than in mouse extracts, while polyomavirus T antigen interacted preferentially with polymerase alpha-primase in mouse extracts. The apparent species specificity of complex formation was not observed when purified polymerase alpha-primases were substituted for the crude extracts. Several functional interactions between T antigen and purified polymerase alpha-primase, including stimulation of primer synthesis and primer elongation on M13 DNA in the presence or absence of the single-stranded DNA binding protein RP-A, also proved to be independent of the species from which polymerase alpha-primase had been purified. However, the human DNA polymerase alpha-primase was specifically required for primosome assembly and primer synthesis on SV40 origin DNA in the presence of T antigen and RP-A.     

Interaction between SV40 DNA and camptothecin, an antitumor alkaloid

Camptothecin specifically interacted with closed superhelical circular SV40 DNA during incubation in 1.0 M NaCl at 37 degrees C and induced an alkali-labile linkage in the E strand. No interaction occurred in the reaction mixture containing 0.1 M NaCl, or at 4 degrees C. As camptothecin did not affect linear SV40 DNA, the superhelical structure of DNA appeared to be essential. The site of the alkali-labile linkage induced in SV40 DNA I through interaction with camptothecin was near the origin of replication on the basis of the results of experiments with restriction enzymes. Neither sulfhydryl reagents nor EDTA affected the interaction between camptothecin and SV40 DNA I, so the action of camptothecin is different from those of antitumor antibiotics, bleomycin or neocarzinostatin. Analysis of the s20,0w value of SV40 DNA I after the interaction with camptothecin and the sedimentation profiles of DNA after heating in the reaction mixture indicated that the interaction between camptothecin and SV40 DNA I was different from those of intercalating or alkylating agents such as ethidium bromide and methylmethanesulfonate. Replacement of the OH group at C-20 in the E ring of camptothecin by H-, CH3-, and Cl- resulted in the reduction, in this order, of the potency for interaction with SV40 DNA I to induce an alkali-labile linkage.