Recurring defective variants of simian virus 40 containing monkey DNA segments.

Four independently and newly isolated defective variants of simian virus 40 have been characterized. All four are very similar, if not identical, to two previously and independently isolated variants (Wakamiya et al., J. Biol. Chem. 254:3584-3591, 1979; J. Papamatheakis, E. Kuff, E. Winocour, and M. F. Singer, J. Biol. Chem. 255:8919-8927, 1980). The documented similarities include restriction endonuclease maps and the presence of the same monkey DNA segments covalently linked to simian virus 40 DNA sequences. Each of the newly described variants was first detected upon serial passaging of wild-type simian virus 40 at a high multiplicity of infection at 33 degrees C as recently described (M. F. Singer and R. E. Thayer, J. Virol. 35:141-149, 1980). A variety of experiments support the idea that the various isolates were independent and do not reflect inadvertent cross-contamination. Two of the new isolates arose during passage of wild-type strain 777 virus in BSC-1 cells, one during passage of strain 776 in BSC-1 cells, and one during passage of strain 776 in primary African green monkey kidney cells. The two variants obtained after passage of strain 776 were shown to contain a particular recognition site for restriction endonuclease MboII within their simian virus 40 DNA segments, as do the two previous isolates. This site is not present in wild-type strain 776 DNA but is shown here to be present in wild-type strain 777 DNA. The surprising recurrence of closely related variants and particularly the unexpected presence of the endo R.MboII site in variants derived from passaging strain 776 suggest that these variants may arise by mechanisms other than recombination between the initial infecting viral genome and the host DNA.     

Homologous recombination of monkey alpha-satellite repeats in an in vitro simian virus 40 replication system: possible association of recombination with DNA replication.

To study homologous recombination between repeated sequences in an in vitro simian virus 40 (SV40) replication system, we constructed a series of substrate DNAs that contain two identical fragments of monkey alpha-satellite repeats. Together with the SV40-pBR322 composite vector encoding Apr and Kmr, the DNAs also contain the Escherichia coli galactokinase gene (galK) positioned between two alpha-satellite fragments. The alpha-satellite sequence used consists of multiple units of tandem 172-bp sequences which differ by microheterogeneity. The substrate DNAs were incubated in an in vitro SV40 DNA replication system and used to transform the E. coli galK strain DH10B after digestion with DpnI. The number of E. coli galK Apr Kmr colonies which contain recombinant DNAs were determined, and their structures were analyzed. Products of equal and unequal crossovers between identical 172-bp sequences and between similar but not identical (homeologous) 172-bp sequences, respectively, were detected, although those of the equal crossover were predominant among all of the galK mutant recombinants. Similar products were also observed in the in vivo experiments with COS1 cells. The in vitro experiments showed that these recombinations were dependent on the presence of both the SV40 origin of DNA replication and SV40 large T antigen. Most of the recombinant DNAs were generated from newly synthesized DpnI-resistant DNAs. These results suggest that the homologous recombination observed in this SV40 system is associated with DNA replication and is suppressed by mismatches in heteroduplexes formed between similar but not identical sequences.     

Genetic analysis of simian virus 40 from brains and kidneys of macaque monkeys.

Simian virus 40 (SV40) was isolated from the brains of three rhesus monkeys and the kidneys of two other rhesus monkeys with simian immunodeficiency virus-induced immunodeficiency. A striking feature of these five cases was the tissue specificity of the SV40 replication. SV40 was also isolated from the kidney of a Taiwanese rock macaque with immunodeficiency probably caused by type D retrovirus infection. Multiple full-length clones were derived from all six fresh SV40 isolates, and two separate regions of their genomes were sequenced: the origin (ori)-enhancer region and the coding region for the carboxy terminus of T antigen (T-ag). None of the 23 clones analyzed had two 72-bp enhancer elements as are present in the commonly used laboratory strain 776 of SV40; 22 of these 23 clones were identical in their ori-enhancer sequences, and these had only a single 72-bp enhancer element. We found no evidence for differences in ori-enhancer sequences associated with tissue-specific SV40 replication. The T-ag coding sequence that was analyzed was identical in all clones from kidney. However, significant variation was observed in the carboxy-terminal region of T-ag in SV40 isolated from brain tissues. This sequence variation was located in a region previously reported to be responsible for SV40 host range in cultured cell lines. Thus, SV40 appears to be an opportunistic pathogen in the setting of simian immunodeficiency virus-induced immunodeficiency, similarly to JC virus in human immunodeficiency virus-infected humans, the enhancer sequence organization generally attributed to SV40 is not representative of natural SV40 isolates, and sequence variation near the carboxy terminus of T-ag may play a role in tissue-specific replication of SV40.     

Natural Isolates of Simian Virus 40 from Immunocompromised Monkeys Display Extensive Genetic Heterogeneity: New Implications for Polyomavirus Disease

Simian virus 40 (SV40) DNAs in brain tissue and peripheral blood mononuclear cells (PBMCs) of eight simian immunodeficiency virus-infected rhesus monkeys with SV40 brain disease were analyzed. We report the detection, cloning, and identification of five new SV40 strains following a quadruple testing-verification strategy. SV40 genomes with archetypal regulatory regions (containing a duplication within the G/C-rich regulatory region segment and a single 72-bp enhancer element) were recovered from seven animal brains, two tissues of which also contained viral genomes with nonarchetypal regulatory regions (containing a duplication within the G/C-rich regulatory region segment as well as a variable duplication within the enhancer region). In contrast, PBMC DNAs from five of six animals had viral genomes with both regulatory region types. It appeared, based on T-antigen variable-region sequences, that nonarchetypal virus variants arose de novo within each animal. The eighth animal exclusively yielded a new type of SV40 strain (SV40-K661), containing a protoarchetypal regulatory region (lacking a duplication within the G/C-rich segment of the regulatory region and containing one 72-bp element in the enhancer region), from both brain tissue and PBMCs. The presence of SV40 in PBMCs suggests that hematogenous spread of viral infection may occur. An archetypal version of a virus similar to SV40 reference strain 776 (a kidney isolate) was recovered from one brain, substantiating the idea that SV40 is neurotropic as well as kidney-tropic. Indirect evidence suggests that maternal-infant transmission of SV40 may have occurred in one animal. These findings provide new insights for human polyomavirus disease.     

Phylogenetic analysis of polyomavirus simian virus 40 from monkeys and humans reveals genetic variation

A phylogenetic analysis of 14 complete simian virus 40 (SV40) genomes was conducted in order to determine strain relatedness and the extent of genetic variation. This analysis included infectious isolates recovered between 1960 and 1999 from primary cultures of monkey kidney cells, from contaminated poliovaccines and an adenovirus seed stock, from human malignancies, and from transformed human cells. Maximum-parsimony and distance methods revealed distinct SV40 clades. However, no clear patterns of association between genotype and viral source were apparent. One clade (clade A) is derived from strain 776, the reference strain of SV40. Clade B contains isolates from poliovaccines (strains 777 and Baylor), from monkeys (strains N128, Rh911, and K661), and from human tumors (strains SVCPC and SVMEN). Thus, adaptation is not essential for SV40 survival in humans. The C terminus of the T-antigen (T-ag-C) gene contains the highest proportion of variable sites in the SV40 genome. An analysis based on just the T-ag-C region was highly congruent with the whole-genome analysis; hence, sequencing of just this one region is useful in strain identification. Analysis of an additional 16 strains for which only the T-ag-C gene was sequenced indicated that further SV40 genetic diversity is likely, resulting in a provisional clade (clade C) that currently contains strains associated with human tumors and human strain PML-1. Four other polymorphic regions in the genome were also identified. If these regions were analyzed in conjunction with the T-ag-C region, most of the phylogenetic signal could be captured without complete genome sequencing. This report represents the first whole-genome approach to establishing phylogenetic relatedness among different strains of SV40. It will be important in the future to develop a more complete catalog of SV40 variation in its natural monkey host, to determine if SV40 strains from different clades vary in biological or pathogenic properties, and to identify which SV40 strains are transmissible among humans.     

Recombination Between Endogenous and Exogenous Simian Virus 40 Genes. II. Biochemical Evidence for Genetic Exchange

The genome of the simian virus 40 (SV40) temperature-sensitive (ts) mutant tsD202 rescued by passage on transformed permissive monkey lines (see accompanying paper [Y. Gluzman et al., J. Virol. 24:534-540, 1977]) was analyzed by restriction endonuclease cleavage mapping to obtain biochemical evidence that the rescue of the ts phenotype results from recombination with the resident SV40 genome of the transformed cell. It was demonstrated that the endonuclease R. HaeIII cleavage site, which is located at 0.9 map unit in the standard viral genome (and which is in the proximity of the known map position of the tsD lesion), is missing in the DNAs of the parental tsD202 virus and of three independent revertants of tsD202. In contrast, this cleavage site was shown to be present in the DNAs of four out of five independently derived rescued D202 populations and in the DNA of the SV40 strain, 777, used to transform the monkey cells. Comparison of the endonuclease R. Hin(II + III) cleavage patterns of SV40 strain 777 DNA and tsD202 DNA revealed differences in the electrophoretic mobilities of Hin fragments A, B, and F. However, the corresponding Hin fragments from all four rescued D202 genomes were identical in their mobilities to those of tsD202 DNA, indicating that these regions of the rescued D202 genome are characteristic of the tsD202 parent. We conclude, therefore, that the genome of the rescued D202 virus is a true recombinant, since it contains restriction endonuclease cleavage sites characteristic of both parents, the endogenous resident SV40 genome of the transformed monkey cells and the exogenous tsD202 mutant.     

Preferential replication of a class of host-substituted defective simian virus 40 variants at low temperature

The host-substituted variant termed CVP8/1/P2 (EcoRI res) was first isolated several years ago after serial passage of simian virus 40 strain 777 on BSC-1 cells at 37 degrees C. When BSC-1 are coinfected with wild-type simian virus 40 strain 777 and variant CVP8/1/P2 (EcoRI res), the variant rapidly becomes the dominant species produced, often representing as much as 80% of the total DNA I synthesized after infection. We present evidence that the replicative advantage of the variant was increased when the infection was carried out at 33 rather than 37 degrees C. Also described are nine new and independent serial passage experiments carried out at 33 degrees C with several purified wild-type virus stocks, including strain 776, and both BSC-1 and primary African green monkey kidney cells. In each series variants related to CVPs/1/P2 (EcoRI res) were detected in the progeny viral genomes after four serial passages. Hybridization data suggest that at least some of these variant DNA I molecules contain simian virus 40 DNA sequences, monkey alpha-component DNA sequences (highly repetitive), and the infrequently reiterated monkey DNA sequences found in CVP8/1/P2 (EcoRI res), all covalently linked as in CPV8/1/P2 (EcoRI res). It appears that this type of variant emerges with some frequency during infection and is then preferentially replicated at 33 degrees C, thereby becoming readily detectable in passaged stocks. A variety of control experiments indicated that the repeated emergence of similar, if not identical, variants is unlikely to be the result of inadvertent cross-contamination or the presence of detectable amounts of the variant in the plaque-purified viral stocks.     

Genomic structure of human polyoma virus JC: nucleotide sequence of the region containing replication origin and small-T-antigen gene

The nucleotide sequence of the region of human polyoma virus JC DNA between 0.5 and 0.7 map units from a unique EcoRI cleavage site was determined and compared with those of the corresponding regions of another human polyoma virus, BK, and simian virus 40 DNAs. Within this region consisting of 945 base pairs, we located the origin of DNA replication near 0.7 map units, the entire coding region for small T antigen, and the splice junctions for large-T-antigen mRNA. The deduced amino acid sequences for small T antigen and the part of large T antigen markedly resembled those of polyoma virus BK and simian virus 40. The results strongly suggest that polyoma virus JC has the same organization of early genome as polyoma virus BK and simian virus 40 on the physical map, with the EcoRI site as a reference point.     

Effect of ICRF-193, a novel DNA topoisomerase II inhibitor, on simian virus 40 DNA and chromosome replication in vitro.

The effect of ICRF-193, a noncleavable-complex-forming topoisomerase II inhibitor, on simian virus 40 (SV40) DNA and SV40 chromosome replication was examined by using an in vitro replication system composed of HeLa cell extracts and SV40 T antigen. Unlike the topoisomerase inhibitors VP-16 and camptothecin, ICRF-193 had little effect on DNA chain elongation during SV40 DNA replication, but high-molecular-weight DNAs instead of segregated monomer DNAs accumulated as major products. Analysis of the high-molecular-weight DNAs by two-dimensional gel electrophoresis revealed that they consisted of catenated dimers and late Cairns-type DNAs. Incubation of the replicated DNA with topoisomerase II resulted in conversion of the catenated dimers to monomer DNAs. These results indicate that ICRF-193 induces accumulation of catenated dimers and late Cairns-type DNAs by blocking the decatenating and relaxing activities of topoisomerase II in the late stage of SV40 DNA replication. In contrast, DNA replication of SV40 chromosomes was severely blocked by ICRF-193 at the late stage, and no catenated dimers were synthesized. These results are consistent with the finding that topoisomerase II is required for unwinding of the final duplex DNA in the late stage of SV40 chromosome replication in vitro.     

Mutants of simian virus 40 differing in plaque size, oncogenicity, and heat sensitivity

Takemoto, K. K. (National Institute of Allergy and Infectious Diseases, Bethesda, Md.), R. L. Kirschstein, and K. Habel. Mutants of simian virus 40 differing in plaque size, oncogenicity, and heat sensitivity. J. Bacteriol. 92:990-994. 1966.-Three mutants of simian virus 40 were isolated on the basis of the type of plaques produced in primary cultures of African green monkey kidney cells and designated as L (large), S (small), and M (minute) strains. Significant differences in oncogenicity for hamsters were observed, with the 50% oncogenic dose being 10(4.5) for the L, 10(5.2) for the S, and 10(5.8) for the M strains. All three strains were capable of transforming human diploid cells (W138 strain). At temperatures up to 41 C, the S and M mutants were capable of multiplying to titers almost equivalent to those obtained at 37 C. In contrast, infectious virus was not produced when cells were infected with the L mutant and were incubated at temperatures above 39 C, although complement-fixing viral and tumor antigens were formed. The temperature-sensitive phase of replication of the L strain was shown to be a late stage in viral maturation or assembly.     

Formation of a cruciform structure at the simian virus 40 replication origin abolishes T-antigen binding to the origin in vitro.

Heteroduplex DNA molecules were formed by annealing an intact simian virus replication origin-containing fragment to a mutant derivative lacking the indigenous wild-type 27-base-pair (bp) inverted repeat within this structure and containing a nonhomologous 26-bp inverted repeat sequence in its place. Results of restriction enzyme and S1 endonuclease cleavage analyses strongly suggested that a 13-bp stem-loop structure formed at the site of nonhomology between these two DNAs. This structure lies within the boundary of simian virus 40 T-antigen-binding site 2, and its presence inhibited T-antigen binding to that sequence but not to an adjacent higher-affinity binding site (site 1). Therefore, the conformation of sequences within an otherwise intact T-antigen-binding site can have major effects upon T-antigen binding there.     

High-fidelity PCR amplification of infectious copies of the complete simian virus 40 genome from plasmids and virus-infected cell lysates

We describe here a long-polymerase chain reaction (PCR) method that can be used to amplify complete simian virus 40 (SV40) DNA with high fidelity, and we show that authentic, viable virus can be produced from molecular clones of the PCR-amplified viral DNAs. A commercial long-PCR kit that employed a combination of Taq and GB-D polymerases was used, together with a pair of overlapping primers that recognized a unique EcoRI site in the SV40 genome. Efficient amplification required linearization of the circular SV40 genomic DNAs with EcoRI. Entire SV40 genomes were successfully PCR-amplified from an SV40 plasmid and from two different SV40-infected cell lysates and were cloned into pUC-19. Three separate segments of the cloned viral genomes were DNA sequenced, and no nucleotide changes relative to the parental virus were detected, suggesting that the viral DNAs had been amplified with high fidelity. Each PCR clone was infectious, and no differences were detected in the growth characteristics of viruses derived from these clones as compared to the original viral strain. The procedure we utilized shortens and simplifies the molecular cloning of small double-stranded DNA viruses and will be useful for viral diagnostic tests and for recovery of virus from clinical samples. The results of these experiments have broad implications, as the methodology is applicable to many systems.     

Electrophoretic Differences in the Capsid Proteins of Simian Virus 40 Plaque Mutants

The structural proteins of three mutants of simian virus 40 (SV40) which differ in plaque size, temperature sensitivity, oncogenicity, host cell restriction, and immunological properties were studied. The polypeptide components of these SV40 strains could not be distinguished by their polyacrylamide gel electrophoretic patterns. When the dissociated virions of two of the mutants were analyzed by the isoelectric focusing technique in a urea gradient, the capsid protein peaks were found to differ significantly in their isoelectric points. The capsid protein of the small-plaque mutant had an isoelectric point of pH 6.51 as compared with pH 6.28 for the large-plaque strain. Isoelectric focusing of the isolated capsid protein revealed three components, a single major subunit and two minor forms. The coat proteins of two of the mutants, small-plaque and minute-plaque strains, were indistinguishable by this technique. The capsid protein peaks obtained by isoelectric focusing were further analyzed by polyacryalmide gel electrophoresis.     

Nucleotide sequence of the Hind-C fragment of simian virus 40 DNA. Comparison of the 5'-untranslated region of wild-type virus and of some deletion Mutants.

We report here the nucleotide sequence of the wild-type simian virus 40 (strain 776) restriction fragment Hind-C-P1 DNA and of the homologous region of various mutant DNAs which lack part of this fragment. During this work, we detected between EcoRII fragments N and G an additional, 17-base-pair EcoRII fragment, fragment P, which had previously been overlooked. Also, an additional dTpdG dinucleotide at residues L 339--340 was observed by sequence analysis of the DNA minus (E) strand; the presence of this dinucleotide was masked on sequencing patterns of the plus strand due to the persistence (during gel electrophoresis) of some secondary structures in the strand's 5'-terminal region. These nucleotide additions raise the total length of SV40 DNA to 5243 base pairs. The longest tandemly repeated segment in SV40 DNA now extends over 72 base pairs. SV40 deletion mutants dl 893 and dl 894 and SV40 strains Rh 911 and 1801 all lack an identical 72-base-pair-long DNA segment in the Hind-C region. This deletion corresponds precisely to one of the two aforementioned large tandemly repeated sequences. Mutant dl 895 lacks 66 base pairs, 63 of which are part of the former repetition. All these mutants, except dl 895, very probably were generated by an intramolecular, homologous recombination event. The 40-base-pair deletion in mutant dl 1811 includes the major capping site of SV40 late RNA. dl 1812 lacks only three base pairs, which are part of the overlapping HhaI and HpaII restriction sites at position 0.725--0.726.     

Analysis of simian virus 40 wild-type and mutant virions by agarose gel electrophoresis.

Intact wild-type simian virus 40 particles can be separated and resolved from a temperature-sensitive mutant and from a number of other viruses by agarose gel electrophoresis. The relative mobilities of the viruses appear to be a function of both virion size and surface composition. The virions of a temperature-sensitive strain of simian virus 40, tsB204, have significantly greater mobility than those of wild-type simian virus 40, when electrophoresis was conducted toward the cathode at pH 5.0. When electrophoresis was performed toward the anode at pH 7.0, TSB204 viruses have a slightly slower mobility as compared with that of the wild type. The data indicated that the virions of tsB204 have a greater positive charge at their surface than those of wild-type particles. No differences were detected in the finger print patterns of the tryptic peptides of VP1 and VP3 of these two virus strains. Although it was not possible to identify the structural polypeptide directly affected by the tsB204 mutation, we have shown that this mutation affects charge distribution on the surface of the virion.     

Variable defectiveness for lytic growth of the dl 54/59 mutants of simian virus 40.

When viral growth in TC-7 cells is compared with that in the simian virus 40 (SV40) transformed CV-1 line C6 some mutants of SV40 deleted between 0.54 and 0.59 on the standard map (dl 54/59 mutants) give relative bursts similar to those of wild-type strain 776, whereas others grow markedly poorer in the untransformed cell. In general, viruses which are defective by this criterion have been found to produce neither a fragmentary small-t protein nor a mature small-t mRNA.     

Heterogeneity of the 5'' terminus of late mRNA induced by a viable simian virus 40 deletion mutant.

d1-1811 is a viable simian virus 40 deletion mutant which lacks the DNA region corresponding to the major capping site of the late viral RNA. The exact size of the deletion (40 base pairs) was determined by comparison of the mutant DNA sequence with the wild-type simian virus 40 (strain 776) DNA sequence. Although d1-1811 forms somewhat smaller plaques, the amount of viral RNA late after infection was not significantly reduced compared with that of the wild type. Virus-specific, polyadenylate-containing, 32P-labeled late RNA was purified from the cytoplasm and enzymatically degraded to characterize the 5' terminus. The cap-containing oligonucleotides were isolated, and their structures were analyzed by further digestion. Instead of a single cap structure, we found a variety of capped 5' termini, with adenosine caps occurring much more frequently than guanosine caps. Nevertheless, there was a remarkable homology between both types of terminal sequences. Conceivably, the minor cap population present in wild-type simian virus 40 late mRNA may correspond to the collection of capped termini identified in the d1-1811 late mRNA . Cellular cytoplasmic RNA shows a similar pattern of cap structures, but the relative abundance is quite different.