SV40病毒的培养、增殖及鉴定

目的：建立SV40病毒在Vero细胞上培养的方法,观察其生长过程,获得SV40病毒,并建立相应的SV40病毒检测方法,为SV40灭活疫苗的制备奠定良好的基础。方法：在Vero细胞上培养和增殖SV40-776株病毒。收获病毒后,应用PCR、免疫荧光以及克隆特异性片段进行测序比较来鉴定SV40病毒。结果：SV40在Vero细胞中增殖很快,并且使细胞出现明显的病变。小规模分离到了SV40病毒颗粒,获得了病毒DNA。不同的鉴定方法均显示出良好的特异性。结论：探讨了SV40病毒病变的基本过程,建立了病毒的培养、增殖和鉴定的方法。     

Response of Simian Virus 40-Transformed Cell Lines and Cell Hybrids to Superinfection with Simian Virus 40 and Its Deoxyribonucleic Acid

Whereas normal human and monkey cells were susceptible both to intact simian virus 40 (SV40) and to SV40 deoxyribonucleic acid (DNA), human and monkey cells transformed by SV40 were incapable of producing infectious virus after exposure to SV40, but displayed susceptibility to SV40 DNA. On the other hand, mouse and hamster cells, either normal or SV40-transformed, were resistant both to the virus and to SV40 DNA. Hybrids between permissive and nonpermissive parental cells revealed a complex response: whereas most hybrids tested were resistant, three of them produced a small amount of infectious virus upon challenge with SV40 DNA. All were resistant to whole virus challenge. The persistence of infectious SV40 DNA in permissive and nonpermissive cells up to 96 hr after infection was ascertained by cell fusion. The decay kinetics proved to be quite different in permissive and nonpermissive cells. Adsorption of SV40 varied widely among the different cell lines. Very low adsorption of SV40 was detected in nonsusceptible cells with the exception of the mKS-BU100 cell line. A strong increase in SV40 adsorption was produced by pretreating cells with polyoma virus. In spite of this increased adsorption, the resistance displayed by SV40-transformed cells to superinfection with the virus was maintained.     

SV40灭活疫苗的制备及其对小鼠免疫的研究

猿猴空泡病毒40(Simian vacuolating virus 40,SV40) 属于乳多空病毒科,是一种DNA肿瘤病毒。亚洲猿类特别是恒河猴是SV40的天然宿主。感染SV40病毒可导致猴体急性病变或呈长期带毒状态,此外能诱使幼鼠产生肿瘤,并能使多种培养细胞发生转化。本研究初步建立了SV40 病毒在Vero细胞中的增殖培养方法,并且初步建立了β丙内脂灭活病毒的方法和纯化工艺。使用SV40病毒灭活疫苗对Balb/c小鼠进行了免疫,结果表明该疫苗具有较好的免疫原性。随后对SV40 病毒DNA在免疫小鼠的重要脏器中的整合情况进行了调查,结果表明SV40病毒DNA未在小鼠重要脏器中整合。本研究为SV40病毒灭活疫苗的研制和进一步开展猴体抗SV40 感染实验奠定了良好的基础。     

Contrasting roles of endosomal pH and the cytoskeleton in infection of human glial cells by JC virus and simian virus 40

Infection of eukaryotic cells by pathogens requires the efficient use of host cell endocytic and cytoplasmic transport mechanisms. Understanding how these cellular functions are exploited by microorganisms allows us to better define the basic biology of pathogenesis while providing better insight into normal cellular functions. In this report we compare and contrast intracellular transport and trafficking of the human polyomavirus JC virus (JCV) with that of simian virus 40 (SV40). We have previously shown that infection of human glial cells by JCV requires clathrin-dependent endocytosis. In contrast, infection of cells by SV40 proceeds by caveola-dependent endocytosis. We now examine the roles of endosomal pH and the cellular cytoskeleton during infection of glial cells by both viruses. Our results demonstrate that JCV infection is sensitive to disruption of endosomal pH, whereas SV40 infection is pH independent. Infection by JCV is inhibited by treatment of glial cells with cytochalasin D, nocodazole, and acrylamide, whereas SV40 infection is affected only by nocodazole. These data point to critical differences between JCV and SV40 in terms of endocytosis and intracellular trafficking of their DNA genomes to the nucleus. These data also suggest a unique sequential involvement of cytoskeletal elements during infection of glial cells by JCV.     

Interference with simian virus 40 DNA replication by adenovirus type 2 during mixed infection of monkey cells.

Infection of monkey cells with human adenovirus (Ad) is abortive, but the infection can be enhanced by coinfecting with simian virus 40 (SV40). However, in the coinfected monkey cells, Ad interferes strongly with SV40 DNA biosynthesis. This interference was found to be a reproducible, delicately controlled phenomenon that was proportional to the multiplicity of infection of Ad and dependent on the active expression of the Ad genome. Newly synthesized SV40 DNA was not broken down in cells after delayed superinfection with Ad, and several early events of SV40 infection such as adsorption, penetration, uncoating, induction of cellular DNA synthesis, and enhancement of Ad infection were not markedly influenced by Ad-mediated interference. It is unlikely that interference is simply due to competition between SV40 and Ad for metabolites, enzymes, or replication sites. The interference effect could be partially neutralized by an increase in the multiplicity of coinfecting SV40 or by an increase in the time interval between SV40 infection and Ad coinfection. Interference was shown to be due to the activity of an Ad early gene product. However, the detailed mechanism of this Ad interference is still unclear.     

野生及笼养猕猴SV40T抗原基因检测方法的建立

目的建立猴外周血单核细胞SV40DNA的PCR检测方法,对猕猴SV40T抗原基因进行检测。方法使用PCR方法对分别来自野外（云南宁蒗71只、景东60只）及笼养猕猴（64只）的SV40大T抗原基因进行检测,同时对扩增出的阳性结果进行测序。结果在195份样本中,有4只来自野生猴样本扩增出SV40大T抗原基因（3．1％,4／131）,1只来自笼养猴样本扩增出SV40大T抗原基因（1．6％,1／64）。测序结果显示：猴血样本扩增片段序列与GenBank中的SV40大T抗原C-末端的基因序列片段有15个核苷酸不同（3．3％差异）,与SV40．776标准株的序列基本一致,但SV40—776在nt3020处有一缺口。结论云南野生及笼养猕猴猴群均能检出SV40T抗原基因。因此建立SV40病毒的DNA检测技术,对用于科研及疫苗生产的实验猕猴的病毒学质量控制具有重要意义。     

SV40 vector with early gene replacement efficient in transducing exogenous DNA into mammalian cells.

An early replacement SV40 vector, SV40-Mu beta, was constructed by replacing part of the early genes of the virus with mouse interferon-beta (IFN-beta) cDNA. Upon transfection of COS-7 cells with this DNA, transducing viral particles were produced, which could infect various cells and cause efficient production of mouse IFN-beta. The viral stock contained no detectable wild-type SV40. The IFN production after the virus infection was very high in monkey kidney cells, but less so in human epithelial cells, and low in mouse, pig, hamster cells and in human lymphocytes. The efficiency of introduction of the DNA to monkey kidney cells was compared with that by the calcium phosphate precipitation method, and the viral vector was found to be more efficient by a factor of several tens to hundreds.     

Comparison of JC and BK human papovaviruses with simian virus 40: DNA homology studies.

Studies were performed to ascertain the relationship of human papovavirus JC to BK virus and to simian virus 40 (SV40) by further restriction endonuclease analysis and by DNA-DNA competition hybridization on membrane filters. Form I DNA extracted from two new isolates from cases of progressive multifocal leukoencephalopathy of human papovaviruses that were JC-like in their antigenic properties were found to yield restriction endonuclease fragmentation patterns similar to those of prototypic JC virus DNA and different from those of BK or SV40. Form I DNA preparations of JC and BK viruses were found to be related to each other and to SV40 DNA to a similar extent, with JC and BK virus DNAs containing sequences homologous to both early and late regions of the SV40 genome. The relatedness in each comparison was less than 50%, and heterologous hybrids between either JC or BK and SV40 DNAs were found to be less stable than homologous SV40-SV40 hybrids in high concentrations of formamide, suggesting substantial mismatch within homologous regions, to the extent of 15 to 30%. The new JC-like isolates were also studied in competition hybridization reactions with SV40 DNA and yielded results similar to those obtained with JC virus.     

Initiation of JC virus DNA replication in vitro by human and mouse DNA polymerase alpha-primase.

Host species specificity of the polyomaviruses simian virus 40 (SV40) and mouse polyomavirus (PyV) has been shown to be determined by the host DNA polymerase alpha-primase complex involved in the initiation of both viral and host DNA replication. Here we demonstrate that DNA replication of the related human pathogenic polyomavirus JC virus (JCV) can be supported in vitro by DNA polymerase alpha-primase of either human or murine origin indicating that the mechanism of its strict species specificity differs from that of SV40 and PyV. Our results indicate that this may be due to differences in the interaction of JCV and SV40 large T antigens with the DNA replication initiation complex.     

Adenovirus transcription. II. RNA sequences complementary to simian virus 40 and adenovirus 2DNA in AD2+ND1- and AD2+ND3-infected cells.

The genomes of the two nondefective adenovirus 2/simian virus 40 (Ad2/SV 40) hybrid viruses, nondefective Ad2/SV 40 hybrid virus 1 (Ad2+ND1) and nondefective hybrid virus 3 (Ad2+ND3), WERE FORMED BY A DELETION OF ABOUT 5% OF Ad2 DNA and insertion of part of the SV40 genome. We have compared the cytoplasmic RNA synthesized during both the early and late stages of lytic infection of human cells by these hybrid viruses to that expressed in Ad2-infected and SV40-infected cells. Separated strands of the six fragments of 32P-labeled Ad2 DNA produced by cleavage with the restriction endonuclease EcoRI (isolated from Escherichia coli) and the four fragments of 32P-labeled SV40 DNA produced by cleavage with both a restriction nuclease isolated from Haemophilus parainfluenzae, Hpa1, and EcoRI were prepared by electrophoresis of denatured DNA in agarose gels. The fraction of each fragment strand expressed as cytoplasmic RNA was determined by annealing fragmented 32P-labeled strands to an excess of cellular RNA extracted from infected cells. The segment of Ad2 DNA deleted from both hybrid virus genomes is transcribed into cytoplasmic mRNA during the early phase of Ad2 infection. Hence, we suggest that Ad2 codes for at least one "early" gene product which is nonessential for virus growth in cell culture. In both early Ad2+ND1 and Ad2+ND3-infected cells, 1,000 bases of Ad2 DNA adjacent to the integrated SV40 sequences are expressed as cytoplasmic RNA but are not similarly expressed in early Ad2-infected cells. The 3' termini of this early hybrid virus RNA maps in the vicinity of 0.18 on the conventional SV40 map and probably terminates at the same position as early lytic SV40 cytoplasmic RNA. Therefore, the base sequence in this region of SV40 DNA specifies the 3' termini of early messenger RNA present in both hybrid virus and SV40-infected cells.     

Inhibition of simian virus 40 DNA synthesis in Yaba virus-preinfected cells.

The effect of Yaba virus preinfection on DNA synthesis in SV40-infected Jinet cells was studied. Time-course synthesis studies were conducted using the incorporation of labeled thymidine. Yaba virus preinfection resulted in the inhibition of SV40 DNA synthesis when the elapsed time between Yaba virus and SV40 infections was three days. This inhibition was demonstrated by hybridization studies and sedimentation analysis. In addition, the usual stimulation of cellular DNA synthesis induced by SV40 infection was inhibited. This inhibition occurred at a time in Yaba virus infection when no cytoplasmic Yaba virus-specific DNA synthesis occurred.     

Efficient transformation of human fibroblasts by adenovirus-simian virus 40 recombinants.

The origin-defective simian virus 40 (SV40) mutant 6-1 has been useful in transforming human cells (Small et al., Nature [London] 296:671-672, 1982; Nagata et al., Nature [London] 306:597-599, 1983). However, the low efficiency of transformation achieved by DNA transfection is a major drawback of the system. To increase the efficiency of SV40-induced transformation of human fibroblasts, we used recombinant adenovirus-SV40 virions which contain a complete SV40 early region including either a wild-type or defective (6-1) origin of replication. The SV40 DNA was cloned into the adenovirus vector in place of early region 1. Cell lines transformed by viruses containing a functional origin of replication produced free SV40 DNA. These cell lines were subcloned, and some of the subclones lost the ability to produce free viral DNA. Subclones that failed to produce free viral DNA were found to possess a mutated T antigen. Cell lines transformed by viruses containing origin-defective SV40 mutants did not produce any free DNA. Because of the high efficiency of transformation, we suggest that the origin-defective chimeric virus is a convenient system for establishing SV40-transformed cell lines from any human cell type that is susceptible to infection by adenovirus type 5.     

Isolation and characterization of defective simian virus 40 genomes which complement for infectivity.

A new variant of simian virus 40 (EL SV40), containing the complete viral DNA separated into two molecules, was isolated. One DNA species contains nearly all of the early (E) SV40 sequences, and the other DNA contains nearly all of the late (L) viral sequences. Each genome was encircled by reiterated viral origins and termini and migrated in agarose gels as covalently closed supercoiled circles. EL SV40 or its progenitor appears to have been generated in human A172 glioblastoma cells, as defective interfering genomes during acute lytic infections, but was selected during the establishment of persistently infected (PI) green monkey cells (TC-7). PI TC-7/SV40 cells contained EL SV40 as the predominant SV40 species. EL SV40 propagated efficiently and rapidly in BSC-1, another line of green monkey cells, where it also formed plaques. EL SV40 stocks generated in BSC-1 cells were shown to be free of wild-type SV40 by a number of criteria. E and L SV40 genomes were also cloned in the bacterial plasmid pBR322. When transfected into BSC-1 cell monolayers, only the combination of E and L genomes produced a lytic infection, followed by the synthesis of EL SV40. However, transfection with E SV40 DNA alone did produce T-antigen, although at reduced frequency.     

Spontaneous Virus Production by Clonal Lines of Simian Virus 40-Transformed Cells and Effects of Superinfection by Deoxyribonucleic Acid from Mutant Simian Virus 40 Strains

Small amounts of infectious simian virus 40 (SV40) were recovered from parental cultures of SV40-transformed human embryonic lung (WI38 Va13A) cells, from 12 primary clones, from 17 secondary clones, and from 18 tertiary clones. The cloning experiments demonstrated that the capacity for spontaneous virus production is a hereditary property of WI38 Va13A cells. Infectious virus was not recovered from every clone at every passage. Repeated trials at different passage levels were necessary to detect virus production. Approximately one in 10(5) to 10(6) of the cells of the clonal lines initiated plaque formation when plated on the CV-1 line of African green monkey kidney cells. No increase in infectious center formation was observed after the clonal lines were treated with bromodeoxyuridine, iododeoxyuridine, or mitomycin C or after heterokaryon formation of treated cells with CV-1 cells. The clonal lines of WI38 Va13A cells were susceptible to superinfection by SV40 deoxyribonucleic acid (DNA). To determine whether only those cells which spontaneously produced virus supported the replication of superinfecting SV40 DNA, cultures were infected with DNA from a plaque morphology mutant and a temperature-sensitive mutant of SV40. After infection by SV40 DNA, approximately 100 to 4,400 times more transformed cells formed infectious centers than were spontaneously producing virus. To determine whether the resident SV40 genome or the superinfecting SV40 genome was replicating, infectious centers produced by SV40 DNA-infected WI38 Va13A cells on CV-1 monolayers were picked and the progeny virus was analyzed. Only the superinfecting SV40 was recovered from the infectious centers, indicating that in the majority of superinfected cells the resident SV40 was not induced to replicate.     

Fate of Infecting Simian Virus 40-Deoxyribonucleic Acid in Nonpermissive Cells: Integration into Host Deoxyribonucleic Acid

Nonpermissive 3T3 cells were infected with purified superhelical simian virus 40 (SV40) deoxyribonucleic acid I (DNA I). One hour after infection, approximately 60% of the intracellular SV40 DNA was converted to relaxed forms. One day after infection, all intracellular SV40 DNA was present as slow-sedimenting material, and no SV40 DNA I was detectable. At 2 days after infection there appeared viral DNA sequences cosedimenting with cellular DNA during alkaline velocity centrifugation. Furthermore, by both alkaline equilibrium gradient centrifugation and by DNA-ribonucleic acid hybridization analysis, covalent linkage of viral DNA sequences to cellular DNA was demonstrated. Integration of SV40 DNA into cellular DNA did not appear to require DNA synthesis, although DNA synthesis followed by mitotic division of the cells enhanced the amount of viral DNA integrated. Based on data obtained by two different methods, it was calculated that 1,100 to 1,200 SV40 DNA equivalents must be integrated per cell by 48 hr after infection.     

Selectivity of interferon action in simian virus 40-transformed cells superinfected with simian virus 40.

Treatment of African green monkey kidney CV-1 cells with human alpha interferons before infection with simian virus 40 (SV40) inhibited the accumulation of SV40 mRNAs and SV40 T-antigen (Tag). This inhibition persisted as long as the interferons were present in the medium. SV40-transformed human SV80 cells and mouse SV3T3-38 cells express Tag, and interferon treatment of these cells did not affect this expression. SV80 and SV3T3-38 cells which had been exposed to interferons were infected with a viable SV40 deletion mutant (SV40 dl1263) that codes for a truncated Tag. Exposure to interferons inhibited the accumulation of the truncated Tag (specified by the infecting virus) but had no significant effect on the accumulation of the endogenous Tag (specified by the SV40 DNA integrated into the cellular genome). The level of Tag in SV40-transformed mouse SV101 cells was not significantly decreased by interferon treatment. SV40 was rescued from SV101 cells and used to infect interferon-treated and control African green monkey kidney Vero cells. Tag accumulation was inhibited in the cells which had been treated with interferons before infection. Our data demonstrate that even within the same cell the interferon system can discriminate between expression of a gene in the SV40 viral genome and expression of the same gene integrated into a host chromosome.     

Human glioblastoma cells persistently infected with simian virus 40 carry nondefective episomal viral DNA and acquire the transformed phenotype and numerous chromosomal abnormalities.

A stable, persistent infection of A172 human glioblastoma cells with simian virus 40 (SV40) was readily established after infection at an input of 450 PFU per cell. Only 11% of the cells were initially susceptible to SV40, as shown by indirect immunofluorescent staining for the SV40 T antigen at 48 h. However, all cells produced T antigen by week 11. In contrast, viral capsid proteins were made in only about 1% of the cells in the established carrier system. Weekly viral yields ranged between 10(4) and 10(6) PFU/ml. Most of the capsid protein-producing cells contained enormous aberrant (lobulated or multiple) nuclei. Persistent viral DNA appeared in an episomal or "free" state exclusively in Southern blots and was indistinguishable from standard SV40 DNA by restriction analysis. Viral autointerference activity was not detected, and yield reduction assays did not indicate defective interfering particle activity, further implying that variant viruses were not a factor in this carrier system. Interferon was also not a factor in the system, as shown by direct challenge with vesicular stomatitis virus. Persistent infection resulted in cellular growth changes (enhanced saturation density and plating efficiency) characteristic of SV40 transformation. Persistent infection also led to an increased frequency of cytogenetic effects. These included sister chromatid exchanges, a variety of chromosomal abnormalities (ring chromosomes, acentric fragments, breaks, and gaps), and an increase in the chromosome number. Nevertheless, the persistently infected cells continued to display a bipolar glial cell-like morphology with extensive process extension and intercellular contacts.     

Isolation and characterization of human DNA fragments with nucleotide sequence homologies with the simian virus 40 regulatory region.

A recombinant library of human DNA sequences was screened with a segment of simian virus 40 (SV40) DNA that spans the viral origin of replication. One hundred and fifty phage were isolated that hybridized to this probe. Restriction enzyme and hybridization analyses indicated that these sequences were partially homologous to one another. Direct DNA sequencing of two such SV40-hybridizing segments indicated that this was not a highly conserved family of sequences, but rather a set of DNA fragments that contained repetitive regions of high guanine plus cytosine content. These sequences were not members of the previously described Alu family of repeats and hybridized to SV40 DNA more strongly than do Alu family members. Computer analyses showed that the human DNA segments contained multiple homologies with sequences throughout the SV40 origin region, although sequences on the late side of the viral origin contained the strongest cross-hybridizing sequences. Because of the number and complexity of the matches detected, we could not determine unambiguously which of the many possible heteroduplexes between these DNAs was thermodynamically most favored. No hybridization of these human DNA sequences to any other segment of the SV40 genome was detected. In contrast, the human DNA segments isolated cross-hybridized with many sequences within the human genome. We tested for the presence of several functional domains on two of these human DNA fragments. One SV40-hybridizing fragment, SVCR29, contained a sequence which enhanced the efficiency of thymidine kinase transformation in human cells by approximately 20-fold. This effect was seen in an orientation-independent manner when the sequence was present at the 3' end of the chicken thymidine kinase gene. We propose that this segment of DNA contains a sequence analogous to the 72-base-pair repeats of SV40. The existence of such an "activator" element in cellular DNA raises the possibility that families of these sequences may exist in the mammalian genome.