virus multiplication (human astroglial cells/progressive multifocal leukoencephalopathy/c
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Primary cultures of human fetal brain cells were transfected with plasmid DNA pMK16, containing an or- igin-defective mutant of simian virus 40 (SV40). Several weeks after DNA treatment, proliferation of glial cells was evident in the culture, allowing passage of the cells at low split ratios. Initially, only 10% of the cells demonstrated nuclear fluores- cence staining using a hamster tumor antibody to the SV40 T protein. By the sixth passage, however, 100% of the cells re- acted positively to the same antibody. During these early pas- sages, the cells designated SVG began growing very rapidly and acquired a homogenous morphology. Cell division re- quired only low serum concentrations, was not contact-inhibit- ed, and remained anchorage dependent. These characteristics of the SVG cells have been stable through 25 passages or -80 cell generations. The SV40 T protein is continuously produced in the cells and can direct the replication of DNA inserts in the pSV2 vector, determined by in situ hybridization using biotin- labeled DNA probes, which contains the SV40 replication ori- gin. More importantly, SVG cells support the multiplication of the human papovavirus JCV at levels comparable to primary cultures of human fetal glial cells, producing infectious virus as early as 1 week after viral adsorption. Their brain-cell deri- vation has been established as astroglial, based on their reac- tivity with a monoclonal antibody to glial fibrillary acid pro- tein and lack of activity with an anti-galactocerebroside anti- body, which identifies oligodendroglial cells. The SVG cells represent a unique line of continuous rapidly growing human fetal astroglial cells that synthesizes a replication-proficient SV40 T protein. Their susceptibility to JC virus (JCV) infec- tion obviates a host restriction barrier that limited JCV studies to primary cultures of human fetal brain and thus should allow for more detailed molecular studies of human brain cells and JCV that infects them.Keywords:
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Previous studies with simian virus 40-transformed mouse 3T3 cells which are temperature sensitive for the expression of the transformed phenotype (ts SV3T3 cells) have shown that T-antigen expression and viral DNA transcription are under cell cycle control. Using these ts SV3T3 cells, we studied the expression of the viral genome under proliferating and non-proliferating conditions, in the presence and absence of inhibitors of macromolecular synthesis and of the tumor promoter phorbol myristate acetate. ts SV3TE cells which are growth arrested at 39 degrees C by low serum concentration or saturation density accumulated in G1 and did not express T-antigen. When these cells were induced to proliferate, at either 32 or 39 degrees C, T-antigen synthesis preceded the entry of the cells into the S-phase and was not coupled to DNA replication. G1-arrested ts SV3T3 cells were induced to synthesize T-antigen by phorbol myristate acetate treatment, but T-antigen alone was not sufficient to induce cellular DNA synthesis. Isoleucine deprivation arrested growth of ts SV3T3 cells, but these cells, as well as normal 3T3, did not accumulate in G1 and continued to express T-antigen. The temperature-sensitive expression of the transformed phenotype in the ts SV3T3 cells does not appear to be due to a lack of transcription of specific regions of the integrated simian virus 40 genome at 39 degrees C.
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Simian virus 40 (SV40) T antigen binds to the tumor suppressor p53 protein, and this association may contribute to oncogenic transformation by the virus. We investigated the importance of this binding on transformation by examining three replication-competent mutants of SV40 (402DE, 402DN, and 402DH). These mutants express T antigens defective in binding to human and monkey p53s but retain some binding with mouse p53. All showed significant reduction in their ability to induce transformed cell foci of two normal human cell lines as well as a slight reduction with mouse embryo cells. Other comparable mutants which express T antigens retaining the ability to complex with p53 were able to induce foci at wild-type levels in both human and mouse cells. Further studies were performed with five T-antigen-positive clones isolated from the few human cell foci that appeared after transfection with 402 mutant DNAs. All five clones reached senescence at about the same point as did the parental untransformed cells. However, six other human cell clones obtained after transfection with DNA from nondefective mutants or wild-type virus were still growing well at more than 10 passages beyond their expected life span. These results suggest that the ability of T antigen to form stable complexes with p53 is necessary for SV40 to extend the life span and partially transform human cells in culture.
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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.
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The limitations to SV40 growth in nonpermissive cells are poorly understood. In differentiated mouse cells, early mRNA and T-antigens are synthesized, but no viral DNA replication has been detected. A plausible explanation for the limitation to viral DNA synthesis in these cells might be the inability of a mouse cell-specific DNA polymerase to interact with the SV40 T-antigen-viral DNA complex. In spite of this abortive viral-cell interaction, SV40 late viral transcripts can be detected in infected mouse cells. Both early and late transcripts can be detected in infected mouse cells. Both early and late SV40 transcriptional activities peak between 10 and 15 h post infection; by 24 h after infection SV40 RNA is almost undetectable. In spite of the detection of late SV40 mRNA in mouse cells, we have been unable to detect any structural proteins (VP1, VP2, or VP3) encoded by these transcripts. A more restrictive interaction occurs between SV40 and undifferentiated mouse teratocarcinoma cell lines. Using an in vitro technique, the viral transcriptional complex (VTC) assay, we were able to demonstrate viral transcriptional activity on both the early and the late strands of SV40 in F9 embryonal carcinoma cells. Nevertheless, no mature processed mRNAs or viral encoded polypeptides were detected in these cells. After differentiation of the F9 cells with retinoic acid, however, spliced early mRNAs, as well as the SV40 T-antigen, were present.
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We have studied the expression of simian virus 40 (SV40) specific tumor antigen (T-antigen) and viral RNA in SV40-transformed mouse 3T3 cells that are temperature-sensitive for the expression of the transformed phenotype (ts SV3T3). Although transformed by wild-type SV40, ts SV3T3 cells at 32 degrees behave like standard transformants, while at 39 degrees they became arrested in G1 after reaching saturation density or under conditions of serum starvation. ts SV3T3 cells at 32 degrees or exponentially growing at 39 degrees are uniformly T-antigen positive. However, after G1 arrest at 39 degrees the majority of the cells becomes T-antigen negative. Induction of proliferation in the resting cultures results in the reappearance of T-antigen in most of the cells, concomitant with the induction of DNA synthesis. The reason for the disappearance of T-antigen from ts SV3T3 cells arrested in G1 seems to reside in a transcriptional control operating on the integrated viral DNA, since these cells contain no appreciable amounts of SV40 specific RNA. Viral RNA can be easily detected in cells growint at 32 degrees or at 39 degrees. The results suggest that transcription of the viral genome in SV40-transformed cells is cell-cycle-dependent.
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A clonal line of highly oncogenic "spontaneously transformed" mouse cells (T AL/N clone 3) was transformed in tissue culture by simian virus 40 (SV40) and subsequently recloned. The clone of SV40-transformed cells (subclone 1) expressed SV40-specific T (nuclear) and transplantation antigens but was 100 times less tumorigenic than the parent T AL/N clone 3 cells. When large numbers of subclone 1 cells (10(4)-10(5)) were injected into syngeneic AL/N mice, tumors were produced. From the tumors, cell lines were established in culture, all of which were consistently negative for T antigen. Tumor lines tested were found not to contain SV40-specific transplantation antigen and had again become highly tumorigenic. The original subclone 1 cells contained about one copy of SV40 DNA per diploid amount of cell DNA, as well as RNA complementary to the early region of the SV40 genome. The T antigen-negative cells from tumor line 124 contained approximately 0.5 copy of SV40 DNA per diploid equivalent and did not synthesize any detectable virus-specific RNA. Reassociation kinetic analysis with restriction enzyme fragments of viral DNA demonstrated that the cells from tumor line 124 (and also the clones of this line) had lost DNA sequences predominantly from the early region of the SV40 genome. The results indicate that a set of stably integrated SV40 DNA sequences can be present in a cell without the expression of viral antigens.
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Most simian virus 40 (SV40)-transformed BALB/c 3T3 clones employed for biochemical studies have been used without regard to passage level. To determine whether virus-induced properties are stable as a function of passage, we have extensively characterized one transformed clone, FNE, which was isolated after SV40 infection BALB/c 3T3 cells in factor-free medium. From the initial testing at passage 5 and for at least 50 subsequent subcultures, the cells stably maintained many transformed growth properties, including high saturation density, morphology, colony formation on contact-inhibited monolayers, tumorigenicity, and synthesis of viral-specific RNA. However, other properties varied as a function of passage. There was a slight decrease in viral genome equivalents per cell from 1.1 copy/cell at passage 5 to 0.7 copies at passage 40. Initially, the cells were negative for all type C virus; however, cells carried at low density for 13 to 20 passages (65 to 100 generations) began to release an endogenous type C virus that then persisted in the culture. Spontaneous release of type C virus did not occur in control BALB/c 3T3 cells carried under identical culture conditions for 90 passages. When the cultures were releasing type C viruses they stained uniformly and brightly positive for SV40 tumor (T) antigen by immunofluorescence, whereas T antigen staining was variable at early passage. These experiments suggest that subtle but perhaps important differences in viral gene expression can occur as a function of passage; they also demonstrate the importance of evaluating the interactions between SV40 and endogenous type C viruses.
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JC virus (JCV) is a ubiquitous human papovavirus that shares sequence and structural homology with simian virus 40 (SV40). In contrast to SV40, expression of JCV is restricted to a small number of cell types, including human fetal glial cells, uroepithelial cells, amnion cells, and some endothelial cells. To study the control of JCV early region expression, we made heterokaryons and stable hybrids between JCV-transformed hamster glial cells and mouse fibroblasts. Binucleate heterokaryons exhibited extinction of large tumor antigen expression in the hamster nuclei as assayed by indirect immunofluorescence. This extinction was both time and dose dependent: extinction reached maximal levels at 24-36 hr after fusion and was dependent on the ratio of glial cell to fibroblast nuclei in multinucleated heterokaryons. Extinction also was observed in stable hybrids between the glial cells and mouse Ltk- cells. Southern blot analysis showed that the extinguished hybrids contained viral sequences. Reexpression of large tumor antigen was observed in several subclones, suggesting that extinction was correlated with the loss of murine fibroblast chromosomes from these hybrids. The cis-acting region that mediates extinction resides within the viral regulatory region, which contains two 98-base-pair repeats that have enhancer activity. These data demonstrate that cellular factors that negatively regulate viral gene expression contribute to the restricted cell-type specificity of this virus.
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Cell fusion
Heterokaryon
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