SV40 viral minichromosome: preferential exposure of the origin of replication as probed by restriction endonucleases.

Isolated SV40 minichromosomes [1-3] were treated with different single-cut restriction endonucleases to probe the arrangement of nucleosomes in relation to the SV70 DNA sequence. While Eco RI and Bam HI each cut 22-27% of the SV40 minichromosomes under limit-digest conditions, Bgl I, which cuts SV40 DNA at or very near the origin of replication [4,5], cleaves 90-95% of the minichromosomes in a preparation. Similar results were obtained with minichromosomes which had been fixed with formaldehyde before endonuclease treatment. One possible interpretation of these findings is that the arrangement of nucleosomes in the compact SV40 minichromosomes is nonrandom at least with regard to sequences near the origin of DNA replication.     

Chromosome of the mature virion of simian virus 40 contains H1 histone.

In addition to free SV40 minichromosomes in the compact form, complete virions were obtained from the nuclear extract of productively infected cells. Capsid proteins VP1, VP2, and VP3, as well as histones, were observed on electrophoregrams of proteins prepared from virions. In contrast to the widely accepted view, histone H1 was found in virions in stoichiometric amounts with respect to other histones. The same is true for virions isolated by a conventional method. Free minichromosomes present in infected cells contain all histones and practically no viral proteins.     

Preferential association of newly synthesized histones with replicating SV40 DNA.

The assembly of newly synthesized histones into nucleosomes during replication of SV40 minichromosomes in vivo was studied. Infected cells were labeled with 35S-methionine for a time shorter than that required to complete a round of viral DNA replication. Mature and replicating SV40 minichromosomes were extracted and separated by zonal sedimentation, and their histone content was analyzed by polyacrylamide gel electrophoresis (SDS and acidic urea). We show that the pulse-labeled histones associate preferentially with the replicating DNA.     

Evidence for SV40 Specific RNA containing Virus and Host Specific Sequences

AFTER infection of monkey kidney cells with simian virus 40 (SV40), several species of SV40 specific RNA are synthesized¹. Most SV40 RNA have a molecular weight of about 6×10⁵ and 8×10⁵ as measured by polyacrylamide gel electrophoresis¹. In addition to these classes of RNA, a large heterogeneous SV40 specific RNA species of up to three times the length of the monomeric SV40 DNA molecule has been observed^1–4. Nothing is known about the structure of this large heterogeneous virus specific RNA.     

Replication of SV40 minichromosomes in vitro

We operationally define two forms of SV40 minichromosomes, a 75S-form, prepared at low salt concentration, referred to as native minichromosomes, and a 50S-form, obtained after treatment with 0.5M potassium acetate, the salt-treated minichromosomes. Both preparations of minichromosomes serve well as templates for replication in vitro. Their respective replication products are strikingly different: replicated native minichromosomes contain a densely packed array of the maximal number of nucleosomes whereas replicated salt-treated minichromosomes carry, on average, half of the maximal number. We conclude that in both cases parental nucleosomes are transferred to progeny DNA, and, in addition, that an assembly of new nucleosomes occurs during the replication of native minichromosomes. This is apparently due to the presence of a nucleosome assembly factor as a constituent of native minichromosomes that dissociates upon treatment with salt. We further show that preparations of minichromosomes usually contain significant amounts of copurifying hnRNP particles and SV40 virion precursor particles. However, these structures do not detectably affect the replication and the chromatin assembly reactions.     

Structure of replicating simian virus 40 minichromosomes. The replication fork, core histone segregation and terminal structures

The structure of replicating simian virus 40 (SV40) minichromosomes was studied by DNA crosslinking with trimethyl-psoralen. The procedure was used both in vitro with extracted SV40 minichromosomes as well as in vivo with SV40-infected cells. Both procedures gave essentially the same results. Mature SV40 minichromosomes are estimated to contain about 27 nucleosomes (error +/- 2), except for those molecules with a nucleosome-free gap, which are interpreted to contain 25 nucleosomes (error +/- 2). In replicative intermediates, nucleosomes are present in the unreplicated parental stem with the replication fork possibly penetrating into the nucleosomal DNA before the histone octamer is removed. Nucleosomes reassociate on the newly replicated DNA branches at distances from the branch point of 225 ( +/- 145) nucleotides on the leading strand and of 285( +/- 120) nucleotides on the lagging strand. In the presence of cycloheximide, daughter duplexes contained unequal numbers of nucleosomes, supporting dispersive and random segregation of parental nucleosomes. These were arranged in clusters with normal nucleosome spacing. We detected a novel type of interlocked dimer comprising two fully replicated molecules connected by a single-stranded DNA bridge. We cannot decide whether these dimers represent hemicatenanes or whether the two circles are joined by a Holliday-type structure. The joining site maps within the replication terminus. We propose that these dimers represent molecules engaged in strand segregation.     

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.     

A new runaway type episomal vector for mammalian cells based on a temperature-sensitive simian virus 40 and inducible erythropoietin production

A runaway vector for mammalian cells was constructed from the simian virus 40 (SV40) genome with a temperature-sensitive mutation of the large T antigen and bacterial neo ^r gene. Replication of this plasmid was repressed above 39°C and vigorous DNA propagation was observed below 33°C in simian CV-1 cells. The human erythropoietin gene was inserted downstream of the SV40 late promoter of the plasmid and the recombinant plasmid was introduced into CV-1 cells. By a temperature shift from 37 to 33°C, the plasmid copy number increased from 5 × 10² to 5 × 10³ copies per cell and the specific production rate of erythropoietin increased more than ten-fold. The bacterial-derived sequences such as the neo ^r gene and vector pUC sequences were prone to delete but the main body of the recombinant plasmid such as SV40 and the erythropoietin-coding sequences were stably maintained at either 33 or 37°C.     

Transfer of nucleosomes from parental to replicated chromatin.

Simian virus 40 (SV40) minichromosomes were used as the substrate for in vitro replication. Protein-free SV40 DNA or plasmids, carrying the SV40 origin of replication, served as controls. Replicated minichromosomal DNA possessed constrained negative superhelicity indicative of the presence of nucleosomes. The topological state of replicated minichromosomal DNA was precisely determined by two-dimensional gel electrophoresis. We show that most or all nucleosomes, present on the replicated minichromosomal DNA, were derived from the parental minichromosome substrate. The mode and the rate of nucleosome transfer from parental to minichromosomal daughter DNA were not influenced by high concentrations of competing replicating and nonreplicating protein-free DNA, indicating that nucleosomes remain associated with DNA during the replication process. The data also show that parental nucleosomes were segregated to the replicated daughter DNA strands in a dispersive manner.     

Conditions for sliding of nucleosomes along DNA: SV 40 minichromosomes

'Sliding' of nucleosomes along DNA under nearly physiological conditions was studied using treatment of SV 40 minichromosomes with the single-cut restriction endonucleases EcoRI and BamHI. Each enzyme can convert no more than 20-25% of the circular DNA molecules of minichromosomes into the linear form irrespective of the presence of histone H1. This suggests absence of the nucleosomes lateral migration (sliding) along DNa at least in the vicinity of the restriction endonucleases cleavage sites during several hours of incubation. The sites available for EcoRI and BamHI in minichromosomes seem to be located predominantly in the spacer DNA regions of nucleosomes. Introduction of only one double-strand (but not single-strand) break into the DNA of minichromosomes stripped of histone H1 is sufficient to induce redistribution of the nucleosome core particles due to their sliding along DNA. Thus, sliding of the nucleosome core particles can be induced under physiological conditions by rather low energy expenditures.     

A domain of SV40 capsid polypeptide VP1 that specifies migration into the cell nucleus.

In order to identify the determinants responsible for the nuclear migration of simian virus 40 (SV40) polypeptide VP1, the 5'-terminal portion of the SV40 VP1 gene was fused with the complete cDNA sequence of poliovirus capsid polypeptide VP1 and the hybrid gene was inserted into an SV40 vector in place of the normal SV40 VP1 gene. Deletions of various length were generated in the SV40 VP1 portion of the hybrid gene, resulting in a set of truncated genes encoding 2-40 NH2-terminal amino acids from SV40 VP1, followed by poliovirus VP1. Monkey kidney cells were infected by the deleted hybrid viruses in the presence of an early SV40 amber mutant as helper, and the subcellular localization of the fusion proteins was determined by indirect immunofluorescence using an anti-poliovirus VP1 immune serum. The presence of the first 11 NH2-terminal amino acids from SV40 VP1 was found to be sufficient to target the fusion protein to the cell nucleus. Deletions extending from the NH2- towards the COOH-terminal end of the protein were next generated. Transport of the SV40 VP1-poliovirus VP1 fusion polypeptide to the nucleus was abolished when the first eight amino acids from SV40 VP1 were deleted. Thus the sequence of the first eight NH2-terminal amino acids of SV40 VP1 appears to contain a nuclear migration signal which is sufficient to target the protein to the cell nucleus.     

Influence of core histone acetylation on SV40 minichromosome replication in vitro

We have used the SV40 in vitro replication system to analyze the replication efficiencies of SV40 minichromosomes associated with normal or hyperacetylated histones. We found that elongation of replication occurs with higher efficiency in hyperacetylated minichromosomes in comparison with normal minichromosomes. Our results indicate that the movement of the replication machinery through nucleosomal DNA is facilitated by charge neutralization due to acetylation of the histone tails. Edited by: A. Wolffe     

Circular dichroism of native whole SV40 chromatin.

Circular dichroism properties of SV40 virions, isolated minichromosomes from virions, and SV40 Form I (supercoiled) DNA were studied in a buffer of low ionic strength. The isolated minichromosomes are compact as judged by sedimentation and electron microscopy. The molar ellipticity at 284 nm of the virion, which may be regarded as a minichromosome in its native state, is about 1500 deg cm²/dmol phosphate; this value is in the same range as that reported for core particles (1300–2000) isolated from different sources. When the viral capsid is removed, there is a small increase in the molar ellipticity to about 2000. However, both of these values are much lower than that found for SV40 supercoiled DNA (about 8200). The results strongly suggest that the linker DNA of the native whole chromatin contributes in a similar fashion to the circular dichroic ellipticity as the core DNA.     

Mapping the in vivo arrangement of nucleosomes on simian virus 40 chromatin by the photoaddition of radioactive hydroxymethyltrimethylpsoralen.

Intracellular simian virus 40 (SV40) chromatin was photoreacted with a 3H-labeled psoralen derivative, hydroxymethyltrimethylpsoralen (HMT), at 48 h postinfection. Psoralen compounds have been shown to readily penetrate intact cells and, in the presence of long-wavelength UV light, form covalent adducts to DNA, preferentially at regions unprotected by nucleosomes. The average distribution pattern of [3H]HMT on the SV40 genome was determined by specific activity measurements of the DNA fragments generated by HindIII plus HpaII or by AtuI restriction enzyme digestion. At levels of 1 to 10 [3H]HMT photoadducts per SV40 molecule, the radiolabel was found to be distributed nonrandomly. Comparison of the labeling pattern in vivo with that of purified SV40 DNA labeled in vitro revealed one major difference. A region of approximately 400 base pairs, located between 0.65 and 0.73 on the physical map, was preferentially labeled under in vivo conditions. This finding strongly suggests that the highly accessible region near the origin of replication, previously observed on isolated SV40 "minichromosomes," exists on SV40 chromatin in vivo during a lytic infection.     

Fanconi Anemia Patients Are More Susceptible to Infection with Tumor Virus SV40

Fanconi anemia (FA) is a recessive DNA repair disease characterized by a high predisposition to developing neoplasms. DNA tumor polyomavirus simian virus 40 (SV40) transforms FA fibroblasts at high efficiency suggesting that FA patients could be highly susceptible to SV40 infection. To test this hypothesis, the large tumor (LT) antigen of SV40, BKV, JCV and Merkel Cell (MC) polyomaviruses were tested in blood samples from 89 FA patients and from 82 of their parents. Two control groups consisting of 47 no-FA patients affected by other genetic bone marrow failure diseases and 91 healthy subjects were also evaluated. Although JCV, BKV and MC were not found in any of the FA samples, the prevalence and viral load of SV40 were higher in FA patients (25%; mean viral load: 1.1×10² copies/10⁵cells) as compared with healthy individuals (4.3%; mean viral load: 0.8×10¹ copies/10⁵cells) and genetic controls (0%) (p<0.005). A marked age-dependent frequency of SV40 was found in FA with respect to healthy subjects suggesting that, although acquired early in life, the virus can widespread more easily in specific groups of population. From the analysis of family pedigrees, 60% of the parents of SV40-positive probands were positive for the virus compared to 2% of the parents of the SV40-negative probands (p<0.005). It is worthy of note that the relative frequency of SV40-positive relatives detected in this study was the highest ever reported, showing that asymptomatic FA carriers are also more susceptible to SV40. In conclusion, we favor the hypothesis that SV40 spread could be facilitated by individuals who are genetically more susceptible to infection, such as FA patients. The increased susceptibility to SV40 infection seems to be associated with a specific defect of the immune system which supports a potential interplay of SV40 with an underlying genetic alteration that increases the risk of malignancies.