Polyoma virus minichromosomes: associated enzyme activities

Topoisomerase I is associated with the regulatory region of transcriptionally active SV 40 minichromosomes

Proteins bound to SV 40 DNA in sarkosyl-treated nuclei have been studied. The major component is topoisomerase I, a 60-70 kDa protein which possesses a strong DNA-nicking activity in the presence of sarkosyl and camptothecin. An SV 40 DNA fraction containing sarkosyl-resistant proteins constitutes 2 to 3% of the total nuclear SV 40 DNA and is enriched in transcriptionally active DNA (as monitored by distribution of RNase-resistant in vivo pulse-labeled RNA). An SV 40 DNA fraction, which is nicked due to covalent binding of topoisomerase I upon sarkosyl treatment is also enriched in transcriptionally active DNA. Topoisomerase I cleavage sites on SV 40 DNA which arise following sarkosyl treatment of nuclei or camptothecin treatment of infected cells have been mapped. The strongest site is located at nucleotide 381 on the non-coding strand and is framed by nuclease hypersensitive sites.

Effects of VM26, a specific inhibitor of type II DNA topoisomerase, on SV40 chromatin replication in vitro

We have examined the influence of VM26 (teniposide), a specific inhibitor of mammalian type II DNA topoisomerase, on the replication of SV40 minichromosomes in vitro. The replication system we used consists of replicative intermediate SV40 chromatin as substrate which is converted to mature SV40 chromatin in the presence of ATP, deoxynucleotides and a protein extract from uninfected cells. The addition of 100 microM VM26 to this system reduces DNA synthesis to 70 to 80 percent of the control and leads to an accumulation of 'late replicative intermediates'. The VM26 induced block of replication was not released by the addition of large quantities of type I DNA topoisomerase. We conclude, that type II DNA topoisomerase is essential for the final replication steps leading from late Cairns structures of replicative intermediates to monomeric minichromosomes. It appears that type I DNA topoisomerase can function as a swivelase during most of the replicative elongation phase, but must later be replaced by type II DNA topoisomerase.

Simian virus 40 minichromosomes contain torsionally strained DNA molecules

Sundin and Varshavsky (J. Mol. Biol. 132:535-546, 1979) found that nearly two-thirds of simian virus 40 (SV40) minichromosomes obtained from nuclei of SV40-infected cells become singly nicked or cleaved across both strands after digestion with staphylococcal nuclease at 0 degrees C. The same treatment of SV40 DNA causes complete digestion rather than the limited cleavages produced in minichromosomal DNA. We have explored this novel behavior of the minichromosome and found that the nuclease sensitivity is dependent upon the topology of the DNA. Thus, if minichromosomes are pretreated with wheat germ DNA topoisomerase I, the minichromosomal DNA is completely resistant to subsequent digestion with staphylococcal nuclease at 0 degrees C. If the minichromosome-associated topoisomerase is removed, virtually all of the minichromosomes are cleaved to nicked or linear structures by the nuclease treatment. The cleavage sites are nonrandomly located; instead they occur at discrete loci throughout the SV40 genome. SV40 minichromosomal DNA is also cleaved to nicked circles and full-length linear fragments after treatment with the single strand-specific endonuclease S1; this cleavage is also inhibited by pretreatment with topoisomerase I. Thus, it may be that the nuclease sensitivity of minichromosomes is due to the transient or permanent unwinding of discrete regions of their DNA. Direct comparisons of the extent of negative supercoiling of native and topoisomerase-treated SV40 minichromosomes revealed that approximately two superhelical turns were removed by the topoisomerase treatment. The loss of these extra negative supercoils from the DNA probably accounts for the resistance of the topoisomerase-treated minichromosomes to the staphylococcal and S1 nucleases. These findings suggest that the DNA in SV40 intranuclear minichromosomes is torsionally strained. The functional significance of this finding is discussed.

An amplified genome that may have resulted from recombination within bidirectionally replicating DNA

Temperature shift-down of permissive mouse cells transformed by a temperature-sensitive (ts) polyomavirus (Py) genome has been shown to induce the accumulation of free copies of the viral DNA. We report here on an unusual product from such induction. The structure of this product is that expected from the occurrence of recombination between growing points in a bidirectionally replicating Py-mouse DNA molecule. This observation may be relevant to the mechanism of gene amplification in mammalian cells.

Simian virus 40 minichromosomes contain torsionally strained DNA molecules

Sundin and Varshavsky (J. Mol. Biol. 132:535-546, 1979) found that nearly two-thirds of simian virus 40 (SV40) minichromosomes obtained from nuclei of SV40-infected cells become singly nicked or cleaved across both strands after digestion with staphylococcal nuclease at 0 degrees C. The same treatment of SV40 DNA causes complete digestion rather than the limited cleavages produced in minichromosomal DNA. We have explored this novel behavior of the minichromosome and found that the nuclease sensitivity is dependent upon the topology of the DNA. Thus, if minichromosomes are pretreated with wheat germ DNA topoisomerase I, the minichromosomal DNA is completely resistant to subsequent digestion with staphylococcal nuclease at 0 degrees C. If the minichromosome-associated topoisomerase is removed, virtually all of the minichromosomes are cleaved to nicked or linear structures by the nuclease treatment. The cleavage sites are nonrandomly located; instead they occur at discrete loci throughout the SV40 genome. SV40 minichromosomal DNA is also cleaved to nicked circles and full-length linear fragments after treatment with the single strand-specific endonuclease S1; this cleavage is also inhibited by pretreatment with topoisomerase I. Thus, it may be that the nuclease sensitivity of minichromosomes is due to the transient or permanent unwinding of discrete regions of their DNA. Direct comparisons of the extent of negative supercoiling of native and topoisomerase-treated SV40 minichromosomes revealed that approximately two superhelical turns were removed by the topoisomerase treatment. The loss of these extra negative supercoils from the DNA probably accounts for the resistance of the topoisomerase-treated minichromosomes to the staphylococcal and S1 nucleases. These findings suggest that the DNA in SV40 intranuclear minichromosomes is torsionally strained. The functional significance of this finding is discussed.

Polyomavirus minichromosomes: associated DNA topoisomerase II and DNA ligase activities

Polyomavirus minichromosomes were isolated and fractionated as described previously (B. B. Gourlie, M. R. Krauss, A. J. Buckler-White, R. M. Benbow, and V. Pigiet, J. Virol. 38:805-814, 1981). Specific assays for DNA topoisomerase II and DNA ligase activity were carried out on each fraction. The enzymatic activity in each fraction was determined by quantitative electron microscopy and compared with the number of replicative intermediate and total polyomavirus DNA molecules in each fraction. DNA topoisomerase II activity cosedimented with polyomavirus replicative intermediate minichromosomes. DNA ligase activity cosedimented with mature polyomavirus minichromosomes.

In vitro DNA synthesis by an alpha-like DNA polymerase bound to replicating simian virus 40 chromosomes

Simian virus 40 chromosomes carry out replicative DNA synthesis in vitro which is sensitive to aphidicolin and to N-ethylmaleimide, resistant to 2',3'-dideoxythymidine-5'-triphosphate, and proportional to the amount of chromosome-associated alpha-like polymerase. Thus, an alpha-like DNA polymerase (alpha polymerase or delta polymerase) is responsible for in vitro DNA synthesis.

Polyoma virus minichromosomes: poly ADP-ribosylation of associated chromatin proteins

The host nuclear enzyme poly(ADP-ribose) polymerase has been shown to be associated with the replicative intermediate and mature forms of polyoma virus minichromosomes. Minichromosome-associated histones H2A and H2B as well as several nonhistone proteins were poly ADP-ribosylated by endogenous poly(ADP-ribose) polymerase. In addition, minichromosome fractions catalyzed the formation in vitro of dimers of endogenous histone H1 linked by poly(ADP-ribose). Poly ADP-ribosylated polyoma virus minichromosome chromatin labeled in vivo with [3H]thymidine could be retained and eluted from anti-poly(ADP-ribose) immunoglobulin G-Sepharose. Pulse-labeled replicative intermediate minichromosomes were retained better on the antibody columns than were mature minichromosomes labeled for 2.5 h. The possible role of poly ADP-ribosylation of viral nucleosomes during polyoma replication or transcription is discussed.

Polyoma virus minichromosomes: characterization of the products of in vitro DNA synthesis

A two-dimensional (neutral-alkali) agarose gel electrophoretic system was used to separate three families of replicative intermediate (RI) polyoma virus DNA molecules (form I, form II, and form III RIs). Two of these families, form II and III RIs, are the result of artifactual nicking of one of the parental strands of supercoiled RIs (form I RIs) during in vitro replication of soluble minichromosomes. Kinetic studies in vitro showed that the nicked RIs serve as templates for limited DNA synthesis. The nicked species are not converted into normal products, however. The nicking reaction, which appears to be specific for the parental strands, is dependent on magnesium ions and occurs concurrently with the in vitro synthesis of DNA.

Association of eukaryotic DNA topoisomerase I with nucleosomes and chromosomal proteins

A DNA topoisomerase activity is found to be associated with the nucleosomes released by the Staphylococcal nuclease digestion of HeLa nuclei. Such an association is found to be salt dependent. A number of criteria have established that this DNA topoisomerase activity is due to HeLa topo I (Liu, L. F. and Miller, K. G. (1980) Proc. Natl. Acad. Sci. USA 78, 3489-3491). A similar association has been demonstrated from the in vitro studies using purified mononucleosomes and eukaryotic DNA topoisomerase I. Nonhistone HMG proteins and histone H1 are found to stimulate topoisomerase activity in vitro and form tight complexes with eukaryotic DNA topoisomerase I. The intimate interactions of topoisomerase I with chromosomal proteins and nucleosomes may be an essential feature of the topoisomerase function in vivo.

Polyoma virus minichromosomes: associated DNA molecules

Electron microscopy was used to identify and quantitate DNA molecules associated with 3H-labeled polyoma minichromosomes which had been fractionated on a sucrose gradient. The percentage of replicating DNA molecules observed in the fractions of the gradient normally designated the replicative intermediate region was up to ninefold higher than in fractions from the mature region. Nevertheless, because of the higher overall concentration of polyoma DNA molecules in the mature region, nearly as many replicating DNA molecules were computed to be in the mature region as in the replicative intermediate region. The replicating molecules in the mature region was predominantly early replicative intermediates. Almost all late replicative intermediates were found in the replicative intermediate region. Under aqueous spreading conditions, a substantial fraction of the replicating DNA structures appeared to be asymmetrical or otherwise unusual, suggesting that extensive single-stranded regions may exist in replicating polyoma minichromosomes.

Polyoma virus minichromosomes: a soluble in vitro replication system

Polyoma virus minichromosomes were isolated from infected 3T6 cells by hypotonic extraction of isolated nuclei. The kinetics of in vitro DNA synthesis in the nuclear extract was similar to that observed with intact nuclei. The majority of the products of in vitro DNA synthesis sedimented with replicative intermediate (RI) minichromosomes and migrated as two bands (RI-a and RI-b) on 1.4% agarose gels. The kinetics of deoxynucleotide monophosphate incorporation into these species was consistent with the existence of several rate-limiting steps in in vitro replication by polyoma minichromosomes. Electron microscope analysis showed that the RI-a band consisted almost entirely of RI theta structures ranging from 46 to 87% replicated, with one-half of all theta structures 67 +/- 4% replicated. The RI-b material was more complex, consisting of sigma and alpha structures with tails ranging from 7 to 114% of polyoma genome length and, less frequently, of linked and multiple linked dimeric structures.