Isolation of Defective Lysogens from Simian Virus 40-transformed Mouse Kidney Cultures

Rescue of simian virus 40 (SV40) from hamster and murine cell lines transformed by nonirradiated or by ultraviolet (UV)-irradiated SV40 (10(-3) to 10(-5) survival) was studied. A combination of tests was employed to detect induction of SV40 synthesis: (i) co-cultivation with susceptible monkey kidney (CV-1) cells; (ii) treating mixtures of transformed and CV-1 cells with UV-irradiated Sendai virus (UV-Sendai) prior to co-cultivation; and (iii) plating untreated or UV-Sendai-treated mixtures of transformed and CV-1 cells with freshly trypsinized CV-1 cells. The first and second tests provided a measure of the total infectious SV40 yield per culture, and the third test provided a measure of the frequency of induction (fraction of transformed cells giving rise to infectious centers). With the combination of tests, SV40 was rescued in all trials from TSV-5 hamster cells, mKS-BU100 mouse cells, and from several lines of mouse kidney cells transformed by UV-irradiated SV40 (mKS-U lines). The frequency of induction was about 7 x 10(-2) for TSV-5 cells, about 3 x 10(-3) for mKS-BU100 cells, greater than 10(-4) for the mKS-U lines which were "good" yielders, and about 10(-5) to 10(-4) for the mKS-U lines which were "average" yielders. SV40 of a plaque type different from parental virus was rescued from four of the mKS-U cell lines. Virus was also easily rescued from: (i) tumor cells produced from the mKS-A line of transformed mouse kidney cells; (ii) mouse kidney cells transformed by SV40 which had been rescued from mKS-BU100 cells; and (iii) tumor cells (HATS) which had been produced by inoculating newborn hamsters with SV40 rescued from mKS-BU100 cells. The frequency of induction of HATS cells was of the same order of magnitude as the frequency of induction of TSV-5 cells. In a study of the kinetics of virus induction, it was shown that SV40 could be detected 28, 40, and 48.5 hr after UV-Sendai treatment of mixtures of CV-1 and TSV-5, HATS, or mKS-BU100 cells, respectively. Although all of the mKS-U lines contained the SV40-specific tumor antigen, some were poor virus yielders (SV40 was recovered in less than 50% of the trials) and five lines were rare virus yielders (SV40 recovered only once in four or more trials). Forty-eight mKS-U lines were nonyielders; SV40 was never recovered by any test used thus far. UV-Sendai-treated mixtures of pairs of nonyielder mKS-U lines with CV-1 cells also did not yield infectious virus. Various factors affecting rescue have been discussed. The mKS-U lines which were poor virus yielders, rare yielders, or which never yielded virus have been classified tentatively as "defective lysogens" which contain mutational lesions at loci essential for detachment of SV40 from integration sites or for SV40 replication, or for both.     

Properties of Somatic Cell Hybrids Between Mouse Cells and Simian Virus 40-Transformed Rat Cells

Hybrids between mouse cells and simian virus 40 (SV40)-transformed rat cells were made, and their properties and chromosome constitution were investigated over many generations. Their hybrid nature was confirmed by enzyme studies. During a period of 1 year a loss of 10 to 20% of the total number of chromosomes was observed. The SV40 tumor antigen was present and remained present in the hybrids. The parental and hybrid cells were studied for agglutination with concanavalin A, for growth in soft agar, and for serum requirement. These growth and surface characteristics of the transformed cells appeared in the hybrids.     

Identification of the Simian Virus 40 Which Replicates When Simian Virus 40-Transformed Human Cells Are Fused with Simian Virus 40-Transformed Mouse Cells or Superinfected with Simian Virus 40 Deoxyribonucleic Acid

Simian virus 40 (SV40) was rescued from heterokaryons of transformed mouse and transformed human cells. To determine whether the rescued SV40 was progeny of the SV40 genome resident in the transformed mouse cells, the transformed human cells, or both, rescue experiments were performed with mouse lines transformed by plaque morphology mutants of SV40. The transformed mouse lines that were used yielded fuzzy, small-clear, or large-clear plaques after fusion with CV-1 (African green monkey kidney) cells. The transformed human lines that were used did not release SV40 spontaneously or after fusion with CV-1 cells. From each mouse-human fusion mixture, only the SV40 resident in the transformed mouse cells was recovered. Fusion mixtures of CV-1 and transformed mouse cells yielded much more SV40 than those from transformed human and transformed mouse cells. The rate of SV40 formation was also greater from monkey-mouse than from human-mouse heterokaryons. Deoxyribonucleic acid (DNA) from SV40 strains which form fuzzy, largeclear, or small-clear plaques on CV-1 cells was also used to infect monkey (CV-1 and Vero), normal human, and transformed human cell lines. The rate of virion formation and the final SV40 yields were much higher from monkey than from normal or transformed human cells. Only virus with the plaque type of the infecting DNA was found in extracts from the infected cells. Two uncloned sublines of transformed human cells [W18 Va2(P363) and WI38 Va13A] released SV40 spontaneously. Virus yields were not appreciably enhanced by fusion with CV-1 cells. However, clonal lines of W18 Va2(P363) did not release SV40 spontaneously or after fusion with CV-1 cells. In contrast, several clonal lines of WI38 Va13A cells did continue to shed SV40 spontaneously.     

Heterokaryon Formation of Simian Virus 40-transformed Cells in the Presence of Ultraviolet-irradiated Sendai Virus

Most simian virus 40-transformed mouse kidney lines form heterokaryons with CV-1 cells in the presence of ultraviolet-irradiated Sendai. However, two nonyielder lines, mKS-U2 and mKS-U20, fuse poorly.     

Analysis of Simian Virus 40-Induced Transformation of Hamster Kidney Tissue in Vitro VIII. Induction of Infectious Simian Virus 40 from Virogenic Transformed Hamster Cells by Amino Acid Deprivation or Cycloheximide Treatment

Clones of virogenic simian virus 40 (SV40)-transformed hamster kidney cells were exposed to medium deficient in the essential amino acids leucine, arginine, or methionine. Infectious virus was induced after deprivation periods of from 24 to 32 hr. The highest yields of infectious SV40 were obtained from cultures deprived for 3 to 4 days. Infectious virus was also induced in cells that were treated with the metabolic inhibitor cycloheximide. Pulse labeling experiments revealed that both protein synthesis and deoxyribonucleic acid (DNA) synthesis were inhibited by concentrations of cycloheximide which were effective for virus induction. It is suggested that inhibition of protein synthesis by either amino acid deprivation or by cycloheximide was responsible for the induction of infectious virus from virogenic cells. We postulate that the inhibition of protein synthesis caused a temporary inhibition of DNA synthesis which resulted in the induction of infectious virus.     

Superinfection of Simian Virus 40-Transformed Permissive Cells with Simian Virus 40

Evidence that the resistance of simian virus (SV40)-transformed permissive cells to superinfection with SV40 is due to lack of virus uptake is presented. When virus uptake is enhanced, the events of infection proceed as in normal permissive cells, resulting in production of infectious virus.     

Transformation of Mouse Macrophages by Simian Virus 40

Studies were undertaken to prove that simian virus 40 (SV40) can transform the mouse macrophage, a cell type naturally restricted from deoxyribonucleic acid (DNA) replication. Balb/C macrophages infected with SV40 demonstrated T-antigen production and induced DNA synthesis simultaneously. In the absence of apparent division, these cells remained T antigen-positive for at least 45 days. SV40 could be rescued from nondividing, unaltered macrophages during the T antigen-producing period. Proliferating transformants appeared at an average of 66 days post-SV40 infection. Established cell lines were T antigen-positive and were negative for infectious virus, but yielded SV40 after fusion with African green monkey kidney cells. Their identity as transformed macrophages was substantiated by evaluation of cellular morphology, phagocytosis, acid phosphatase, beta(1c) synthesis, and aminoacridine incorporation.     

In Vitro Transformation of Rat and Mouse Cells by DNA from Simian Virus 40

Primary rat kidney cells and mouse 3T3 cells can be transformed by DNA of simian virus 40 when use is made of the calcium technique (Graham and van der Eb, 1973). The transformation assay in primary rat cells is reproducible, but the dose response is not linear.     

Thymidine Kinase from Normal, Simian Virus 40-Transformed and Simian Virus 40-Lytically Infected Cells

Simian virus 40 (SV40) infection of human diploid cells failed to cause an enhanced production of thymidine kinase during the first 10 days after infection. Thymidine kinase activities from extracts of SV40-transformed cultures (human or simian) were considerably higher than the activity levels in extracts from the normal cells of origin. In addition, whereas the kinase activities obtained for human diploid cultures decreased as the cell sheet became confluent, the kinase activities for SV40-transformed human cells remained high after confluence was reached. Antisera obtained from hamsters bearing SV40 or adeno-7-SV40 hybrid virus tumors selectively inhibited enzyme from transformed sources (human or simian). Also, the antisera selectively inhibited enzyme extracted from SV40-lytically infected monkey cells. Sera from normal animals or from hamsters bearing polyoma tumors failed to inhibit enzymes from normal, SV40-transformed, or SV40-lytically infected cells. The Michaelis constant of partially purified enzyme from SV40-transformed cells was two to five times as high as that obtained for partially purified enzyme from human diploid cell cultures.     

Properties of Simian Virus 40 Rescued from Cell Lines Transformed by Ultraviolet-Irradiated Simian Virus 40

Simian virus 40 (SV40) strains have been rescued from various clonal lines of mouse kidney cells that had been transformed by ultraviolet (UV)-irradiated SV40. To learn whether some of the rescued SV40 strains were mutants, monkey kidney (CV-1) cells were infected with the rescued virus strains at 37 C and at 41 C. The SV40 strains studied included strains rescued from transformed cell lines classified as "good," "average," "poor," and "rare" yielders on the basis of total virus yield, frequency of induction, and incidence of successful rescue trials. Four small plaque mutants isolated from "poor" yielder lines and fuzzy and small plaque strains isolated from an "average" and a "good" yielder line, respectively, were among the SV40 strains tested. Virus strains rescued from all classes of transformed cells were capable of inducing the transplantation antigen, and they induced the intranuclear SV40-T-antigen, thymidine kinase, deoxyribonucleic acid (DNA) polymerase, and cellular DNA synthesis at 37 C and at 41 C. With the exception of four small plaque strains rescued from "poor" yielders, the rescued SV40 strains replicated their DNA and formed infectious virus with kinetics similar to parental SV40 at either 37 or 41 C. The four exceptional strains did replicate at 37 C, but replication was very poor at 41 C. Thus, only a few of the rescued virus strains exhibited defective SV40 functions in CV-1 cells. All of the virus strains rescued from the "rare" yielder lines were similar to parental SV40. Several hypotheses consistent with the properties of the rescued virus strains are discussed, which may account for the significant variations in virus yield and frequency of induction of the transformed cell lines.     

Simian Virus 40 Deoxyribonucleic Acid Replication: I. Effect of Cycloheximide on the Replication of SV40 Deoxyribonucleic Acid in Monkey Kidney Cells and in Heterokaryons of SV40-transformed and Susceptible Cells

Infectious deoxyribonucleic acid (DNA) was extracted from green monkey kidney (CV-1) cultures at various times after the cultures were infected with simian virus 40 (SV40) at input multiplicities of 0.01 and 0.1 plaque-forming unit (PFU) per cell. A pronounced decrease in infectious DNA was observed from 3 to 16 hr after virus infection, suggesting that structurally altered intracellular forms may have been generated early in infection. Evidence is also presented that SV40 DNA synthesis requires concurrent protein synthesis. DNA replication was studied in the presence and absence of cycloheximide in: (i) SV40-infected and uninfected cultures of CV-1 cells; (ii) cultures synchronized with 1-β-d-arabinofuranosylcytosine (ara-C) for 24 to 30 hr prior to the addition of cycloheximide; and (iii) in heterokaryons of SV40-transformed hamster and susceptible monkey kidney cells. DNA synthesis was determined by pulse-labeling the cultures with ³H-thymidine at various times from 24 to 46 hr after infection. In addition, the total infectious SV40 DNA was measured. Addition of cycloheximide, even after early proteins had been induced, grossly inhibited both SV40 and cellular DNA syntheses. The activities of thymidine kinase, DNA polymerase, deoxycytidylate deaminase, and thymidylate kinase were measured; these enzyme activities remained high for at least 9 hr in the presence of cycloheximide. SV40 DNA prelabeled with ³H-thymidine before the addition of cycloheximide was also relatively stable during the time required for cycloheximide to inhibit further DNA replication.     

Replication of Simian Foamy Virus in Monkey Kidney Cells

The structure of foamy virus, its mode of maturation, and the origin of vacuoles in monkey kidney cells are described.     

Nucleoprotein Complexes in Simian Virus 40-Infected Cells

When African green monkey kidney cells (BSC-1) were infected with simian virus 40 (SV40) and extracted with 0.25% Triton X-100 after exposure to (3)H-thymidine, the (3)H-SV40 deoxyribonucleic acid (DNA) was present in a form which had a sedimentation coefficient in sucrose gradients of 44S. The change from the sedimentation coefficient of purified SV40 DNA (21S) was shown to result from the association of the SV40 DNA in the Triton extracts with protein by means of sensitivity to Pronase digestion and labeling with (14)C-amino acids. Short-term labeling experiments with (3)H-thymidine demonstrated that SV40 DNA molecules in the course of replication (25S) were also present as nucleoprotein complexes in Triton-extracted material. Labeled DNA extracted with Triton in the form of nucleoprotein complexes was obtained in amounts which were quantitatively equivalent to the amounts extracted with deoxycholate in parallel experiments. This indicated that the newly synthesized pools of SV40 DNA may not occur as free DNA in the infected cell.     

Deoxyribonucleic Acid Replication in Simian Virus 40-Infected Cells: III. Comparison of Simian Virus 40 Lytic Infection in Three Different Monkey Kidney Cell Lines

A comparative study of simian virus 40 (SV40) lytic infection in three different monkey cell lines is described. The results demonstrate that viral deoxyribonucleic acid (DNA) synthesis and infectious virus production begin some 10 to 20 hr earlier in CV-1 cells and primary African green monkey kidney (AGMK) cells than in BSC-1 cells. Induction of cellular DNA synthesis by SV40 was observed in CV-1 and AGMK cells but not with BSC-1 cells. Excision of large molecular weight cellular DNA to smaller fragments was easily detectable late in infection of AGMK cells. Little or no excision was observed at comparable times after infection of CV-1 and BSC-1 cells. The different kinds of responses of these three monkey cell lines during SV40 lytic infection suggest the involvement of cellular functions in the virus-directed induction of cellular DNA synthesis and the excision of this DNA from the genome.     

Isolation of Simian Virus 40 Recombinants from Cells Infected with Oligomeric Forms of Simian Virus 40 Deoxyribonucleic Acid

Oligomeric forms of simian virus 40 (SV40) deoxyribonucleic acid (DNA) were isolated from monkey kidney cells infected with two plaque morphology mutants of SV40. Recombinant, large clear-plaque-type SV40 was produced in cells productively infected with oligomeric forms of SV40 DNA.     

Translation of mRNA from Simian Virus 40-Infected Cells into Simian Virus 40 Capsid Protein by Cell-Free Extracts

Messenger RNA was isolated from simian virus 40 (SV40)-infected and mock-infected cells by chromatography on poly(U) sepharose. When added to cell-free extracts from Chinese hamster ovary cells or rabbit reticulocytes, RNA from the infected cells, but not from mock-infected cells, stimulated synthesis of the major SV40 capsid protein. Identification of this species was done by sodium dodecyl sulfate gel electrophoresis, peptide mapping, and immunoprecipitation. The in vitro synthesized capsid protein was slightly different from virion assembled capsid protein, as shown by separation upon chromatography on hydroxylapatite and by minor differences in the peptide map.     

Initial Site of Synthesis of Virus During Rescue of Simian Virus 40 from Heterokaryons of Simian Virus 40-Transformed and Susceptible Cells

Simian virus 40 (SV40) can be rescued from certain SV40-transformed hamster cells by fusion with susceptible African green monkey kidney (CV-1) cells, in the presence of ultraviolet-irradiated Sendai virus. We have determined the sites in which SV40 is produced during rescue in these heterokaryons. To determine the sequence, nuclei were isolated from fused cells at various times after fusion, separated on sucrose-density gradients, and assayed for infectious center formation and virus content on CV-1 monolayers. Virus was first detected in the transformed nucleus (40 hr postfusion), and later associated with both transformed and susceptible nuclei (68 to 72 hr). Viral rescue apparently does not depend upon the transfer of SV40 deoxyribonucleic acid to a susceptible CV-1 nucleus, since the transformed nucleus is the primary site of virus production. The time course of certain cytological events in the rescue process and in productive infection was found to be similar.     

Protein Kinase Stimulated by Cyclic GMP in Uninfected and Simian Virus 40-Infected Monkey Kidney Cells

Uninfected African green monkey kidney cells contain a cyclic GMP-stimulated protein kinase. The level or specific activity of the enzyme was not significantly increased after infection of the cells with simian virus 40. This enzyme probably catalyzes the phosphorylation of the structural proteins of the virus.     

Sedimentation Properties of Simian Virus 40-Specific Ribonucleic Acid Present in Green Monkey Cells During Productive Infection and in Mouse Cells Undergoing Abortive Infection

The size distribution of polyribosome-associated simian virus 40 (SV40) ribonucleic acid (RNA) was examined at various times after productive infection. Eight hours after infection, virus-specific RNA was detected in the 14 to 17S region of a sucrose gradient by deoxyribonucleic acid (DNA)-RNA hybridization; RNA present in fractions sedimenting more rapidly did not react with SV40 DNA. At successively later times, SV40 RNA was detected in more rapidly sedimenting regions. By 24 hr, a portion of the SV40 RNA was detected in the 28S region, sedimenting slightly more rapidly than a MS2 RNA marker. Nuclear SV40 RNA, prepared from cells 48 hr after infection, was distributed in more rapidly sedimenting regions of the gradient, peaking at about 32 to 34S. Some nuclear virus-specific RNA could be detected in the 45 to 50S region. During the abortive infection of mouse cells, the sedimentation profile of SV40 RNA was very similar to that observed during the early phases of the lytic cycle.     

Integration of Simian Virus 40 Deoxyribonucleic Acid into the Deoxyribonucleic Acid of Permissive Monkey Kidney Cells

Integration of simian virus 40 (SV40) deoxyribonucleic acid (DNA) into cellular DNA occurred when permissive African green monkey kidney (CV-1) cells were infected at a low multiplicity of SV40 in the presence of cytosine arabinoside.