Preparative isolation and some properties of SV40 T-antigen]

SV40 T-antigen was isolated from hamster tumors and purified about 1600-fold by the procedure including successive ammonium sulfate precipitation, chromatography on DEAE-cellulose, preparative polyacrylamide gel electrophoresis and elimination of the bulk of contaminating cell proteins by the interaction with antibodies to the tissues of normal hamsters. The resulting preparation was not quite homogenous being contaminated with some of cell proteins left. T-antigen in the tumor extract was revealed at least in three distinct forms with molecular weight of 100 000, 200 000, and 400 000. It is proposed that these forms correspond to mono-, di-, and tetramers of the basal protein of T-antigen, although the alternative explanation, the existence of complex of T-antigen with cell proteins, cannot be ruled out.     

Induction of the replicative synthesis of DNA by SV40 virus T antigen introduced into cells using liposomes

The role of virus SV40 T-antigen in the induction of cell DNA synthesis during its incorporation into cell liposomes was studied, using monolamellar liposomes obtained by phase reversal with incorporated highly purified T-antigen. Immunofluorescence studies revealed that T-antigen effectively penetrates inside the cells and after 10 hours is accumulated in the nuclei, where its level remains unchanged for 24 hours. Injections of purified T-antigen into the renal cells of serum-starved CV1 monkeys resulted in an almost 10-fold increase in the number of DNA-synthesizing cells 18 hours after the exposure. The same effect was observed during stimulation of a 10% serum culture. Removal of T-antigen from the preparation by specific immunoadsorption eliminated this effect. Centrifugation of cells grown in the presence of bromodeoxyuridine in a CsCl gradient was used to demonstrate the replicative type of cell DNA synthesis during T-antigen induction.     

A 61,000-dalton truncated large T-antigen is uniformly expressed in hamster cells transformed by polyomavirus

Various polyomavirus-transformed hamster cell lines derived from tumors or from infected hamster cell cultures synthesized polyoma middle and small tumor (T)-antigens but no full-size large T-antigen. Instead, all cell lines produced the same or similar polyoma T-antigen-related proteins of ca. 61 kilodaltons (kDal). Like large T-antigen synthesized in lytically infected mouse cells, the 61-kDal proteins were phosphoproteins showing electrophoretic and charge heterogeneities. Chromatographic analysis of the methionine-containing tryptic peptides indicated that the 61-kDal proteins were truncated forms of large T-antigen comprising amino acid residues 1 to 485 (+/- 25). Analysis of viral DNA present in hamster chromosomal DNA of three independently isolated cell lines confirmed that synthesis of the 61-kDal proteins was due to a discontinuity in the large T-antigen coding sequence, most likely located between 7 and 8.9 map units on the polyoma DNA map. The three cell lines yielded essentially the same patterns of viral DNA-containing restriction enzyme fragments, suggesting that insertion of viral DNA into the hamster chromosomes took place at closely similar sites.     

Transformation of bone marrow cells in rodents by recombinant plasmid pBRSV

Bone marrow cells (mouse strain CBA/Ca and Syrian hamster cells) were transformed with pBRSV DNA containing T-antigen of the SV40 virus. The SV40 T-antigen in transformed cell was detected in 0.5% cases by immunofluorescence with specific antibodies. Extrachromosomal localization of recombinant DNA was shown by means of retransformation of E. coli cells with cytoplasmic spleen DNA from mice previously injected intravenously the transformed bone marrow cells.     

Lymphotropic papovavirus transformation of hamster embryo cells

Hamster embryo cells were transformed by African green monkey lymphotropic papovavirus (LPV). The transformed cells contained intranuclear T-antigens demonstrable by fluorescent antibody staining with hamster anti-LPV serum. Analysis of uncloned and cloned lines of transformed cells for LPV sequences revealed that the viral DNA was present as free nonintegrated and integrated genomes; there were approximately 10 copies of free DNA and about one to two copies of integrated genomes per cell. The cells were highly tumorigenic when inoculated into hamsters and produced progressively growing tumors in 100% of newborn or 10-day-old hamsters that were inoculated with LPV-transformed cells. The serum from tumor-bearing hamsters reacted with LPV-transformed cells and also showed a weak reaction with simian virus 40-, BK virus-, and JC virus-transformed cells, thereby showing an antigenic relationship with the T-antigens of other primate polyomaviruses. The large T-antigen of LPV was found to be an 84,000-molecular-weight protein which was immunoprecipitated by hamster anti-LPV (antiviral) as well as by tumor serum.     

Comparison of the DNA sequence of the Crawford small-plaque variant of polyomavirus with those of polyomaviruses A2 and strain 3.

The DNA sequence of two wild-type strains of polyomavirus (A2 and strain 3) are known. We have determined the majority of the DNA sequence of a third strain, the Crawford small-plaque virus. This virus has been noted for its capacity to induce readily detected tumor-specific transplantation antigen in hamster cells, a property that is most likely attributable to an altered middle T-antigen. A comparison of its DNA sequence with those of the A2 and strain 3 viruses reveals numerous nucleotide substitutions, insertions, and deletions throughout the genome. Most sequence changes in coding regions are silent mutations; however, variability in proteins can be predicted from these sequence data at 5 locations in middle T-antigen, 10 in large T-antigen, and 10 in VP1. The Crawford small-plaque virus noncoding regulatory region contains, in addition to nucleotide substitutions, a 44-base-pair tandem repeat of sequences on the late side of the origin of DNA replication.     

Characterization of the Tumorlike (T) Antigen Induced by Type 12 Adenovirus : I. Purification of the Antigen from Infected KB Cells and a Hamster Tumor Cell Line

The T antigen induced by type 12 adenovirus was purified from KB cells infected in the presence of 10(-6)m 5-fluoro-2-deoxyuridine to inhibit synthesis of viral capsid antigens. The antigen was purified approximately 200-fold, and the purified product contained only negligible amounts of host-cell contaminants, as judged by the residual radioactivity from (14)C-labeled uninfected cells which had been added to infected cells at the initiation of the purification. Immunoelectrophoresis indicated that the purified T-antigen preparation contained a single antigenic species. The T antigen from a hamster cell line (HT-1) derived from a type 12 adenovirus-induced tumor was purified by the same procedure. The T antigens from the two different sources were shown to be immunologically similar by use of a rabbit antiserum prepared against the purified T antigen from infected KB cells and sera from hamsters bearing tumors induced by type 12 adenovirus.     

Correlation between the presence of T-antigen and the reinitiation of host DNA synthesis in senescent human diploid fibroblasts after SV40 infection

Senescent human diploid fibroblasts, TIG-1, had labelling indices of about 0.5-3% when labelled with [3H]thymidine for 3 days in fresh medium containing 10% fetal bovine serum. When these cells were infected with SV40, the percentage of nuclei incorporating [3H]thymidine increased by about 10-fold. The frequency of T-antigen-positive cells and that of [3H]thymidine-incorporating cells were almost the same. About 80% of T-antigen-positive cells were also positive to incorporation of [3H]thymidine, and the same result was obtained in infected young cells. These results indicated that senescent human diploid cells which are brought to synthesize T-antigen always initiate DNA synthesis as young cells do. The characteristics of senescent cells as compared with younger cells was low incidence of T-antigen-positive cells after infection. The basis of low susceptibility of senescent cells to initiate DNA synthesis by SV40 infection thus seems to be concerned with an event after the adsorption of virus, but before the synthesis of a detectable amount of T-antigen.     

Chromatin-bound and free RNA polymerase A activities in rat thymus cells following glucocorticoid treatment

Subcellular fractions from SV-40 transformed hamster lens cells, prepared by chemical extractions, were tested for the presence of T-antigen by immunoautoradiography. Most of the T-antigen was present in the nucleus and was resistant to extraction by 2 M NaCl, indicating an association with the nuclear matrix. Another part of the T-antigen was, under certain conditions, resistant to extraction of the cells with a nonionic detergent. This T-antigen could be solubilized by Ca2+ at low temperature, conditions that also cause a specific depolymerization of microtubules.     

Transformation of Hamster Kidney Cells by BK Papovavirus DNA

Supercoiled BK papovavirus DNA was shown to transform hamster kidney cells using the calcium phosphate co-precipitation technique. The transformed cells contained intranuclear T-antigen(s) and rescuable virus and produced progressively growing tumors when inoculated into hamsters. A novel finding was the production in tumor-bearing animals of antinuclear antibody, which reacted against normal, untransformed cells; in addition, tumor serum contained antibody against virus-specific T-antigen(s).     

Transformation of hamster kidney cells by BK papovavirus DNA.

Supercoiled BK papovavirus DNA was shown to transform hamster kidney cells using the calcium phosphate co-precipitation technique. The transformed cells contained intranuclear T-antigen(s) and rescuable virus and produced progressively growing tumors when inoculated into hamsters. A novel finding was the production in tumor-bearing animals of antinuclear antibody, which reacted against normal, untransformed cells; in addition, tumor serum contained antibody against virus-specific T-antigen(s).     

A novel selection system for recombinational and mutational events within an intron of a eucaryotic gene.

In order to identify a poison sequence that might be useful in studying illegitimate recombination of mammalian cell chromosomes, several DNA segments were tested for their ability to interfere with gene expression when placed in an intron. A tRNA gene and its flanking sequences (267 bp) were shown to inhibit SV40 plaque formation 100-fold, when inserted into the intron in the T-antigen gene. Similarly, when the same DNA segment was placed in the second intron of the adenosine phosphoribosyl transferase (APRT) gene from CHO cells, it inhibited transformation of APRT-CHO cells 500-fold. These two tests indicated that the 267-bp DNA segment contained a poison sequence. The poison sequence did not affect replication since the replication of poisoned SV40 genomes was complemented by viable SV40 genomes and poisoned APRT genes were stably integrated into cell chromosomes. Cleavage of the poison sequence in the SV40 T-antigen intron by restriction enzymes indicated that the tRNA structural sequences and the 5' flanking sequences were not required for inhibition of SV40 plaque formation. Sequence analysis of viable mutant SV40, which arose after transfection of poisoned genomes, localized the poison sequence to a 35 bp segment immediately 3' of the tRNA structural sequences.     

DNA binding properties of simian virus 40 T-antigens synthesized in vivo and in vitro.

Simian virus 40 large T- and small t-antigens have been shown previously to share immunological determinants and common sequences and to have roles in virus-induced cell transformation. However, only large T-antigen is a DNA binding protein. Under all conditions tested, small t-antigen did not interact with DNA. Large T-antigen synthesized in infected cells bound to both native calf thymus and simian virus 40 DNAs. As its binding efficiency was less than 100%, it is likely that there are different forms of T-antigen which vary in their affinity for DNA. Large T-antigen synthesized in cell-free protein-synthesizing systems primed by simian virus 40 mRNA also bound to DNA-cellulose, whereas small t-antigen similarly synthesized in vitro did not. An 82,000-molecular-weight T-antigen polypeptide synthesized in cell-free protein-synthesizing systems primed by simian virus 40 complementary RNA transcribed in vitro from simian virus 40 DNA by Escherichia coli RNA polymerase bound efficiently to simian virus 40 DNA. As this product did not share sequences with the small t-antigen, it can be concluded that the amino-terminal portion of the T-antigen is not required for some of its specific DNA binding properties.     

Simian virus 40 origin auxiliary sequences weakly facilitate T-antigen binding but strongly facilitate DNA unwinding.

The complete simian virus 40 (SV40) origin of DNA replication (ori) consists of a required core sequence flanked by two auxiliary sequences that together increase the rate of DNA replication in monkey cells about 25-fold. Using an extract of SV40-infected monkey cells that reproduced the effects of ori-auxiliary sequences on DNA replication, we examined the ability of ori-auxiliary sequences to facilitate binding of replication factors and to promote DNA unwinding. Although the replicationally active form of T antigen in these extracts had a strong affinity for ori-core, it had only a weak but specific affinity for ori-auxiliary sequences. Deletion of ori-auxiliary sequences reduced the affinity of ori-core for active T antigen by only 1.6-fold, consistent with the fact that saturating concentrations of T antigen in the cell extract did not reduce the stimulatory role of ori-auxiliary sequences in replication. In contrast, deletion of ori-auxiliary sequences reduced the efficiency of ori-specific, T-antigen-dependent DNA unwinding in cell extracts at least 15-fold. With only purified T antigen in the presence of topoisomerase I to unwind purified DNA, ori-auxiliary sequences strongly facilitated T-antigen-dependent DNA conformational changes consistent with melting the first 50 base pairs. Under these conditions, ori-auxiliary sequences had little effect on the binding of T antigen to DNA. Therefore, a primary role of ori-auxiliary sequences in DNA replication is to facilitate T-antigen-dependent DNA unwinding after the T-antigen preinitiation complex is bound to ori-core.     

Stabilization of a reactive, electrophilic carcinogen, benzo[a]pyrene diol epoxide, by mammalian cells

We have studied several features of the interactions of 7r,8t-dihydroxy-9t,10t-oxy-7,8,9,10-tetrahydrobenzo[a]pyrene (BPDE-I) with a DNA repair-proficient derivative of Chinese hamster ovary cells (CHO), AT3-2, and with a UV-light sensitive mutant, UVL-10, derived from AT3-2. Methods were developed for quantitating the amount of unhydrolysed BPDE-I associated with cells and for purifying DNA from cells under conditions where artificial labeling during preparation is minimized. In both cell types, about 30% of the BPDE-I added to a cell culture is rapidly taken up by the cells and is maintained in a cellular compartment in which the half-life of BPDE-I is about 10-fold longer than in aqueous medium. The kinetics of covalent binding to DNA were measured in both cell types and found to be described well by a single exponential process with a half-life of about 60 min. This is virtually identical to the half-life for intracellular hydrolysis of BPDE-I (57 min), consistent with the suggestion that this intracellular, relatively stable BPDE-I is responsible for binding.     

Cell-Dependent Differences in the Production of Infectious Herpes Simplex Virus at a Supraoptimal Temperature

The replication of herpes simplex virus (HSV) was compared in rabbit and hamster cells at optimal and supraoptimal temperatures. Replication occurred in cells of either species at 33 C, but the total infectious virus yield was routinely about 10-fold greater in rabbit cells than in hamster cells. At 39 C, this difference was exaggerated to greater than 100,000-fold. Whereas infectious virus was produced and plaques formed in rabbit kidney cell monolayers at the higher temperature, neither developed in those derived from hamster embryos. Elevating the temperature from 33 C to 39 C at various time intervals after exposure of the cultures to virus revealed that production of infectious virus in hamster cells was completely heat-sensitive up to 6 hr after infection. Specific viral antigens and viral deoxyribonucleic acid (DNA) were synthesized in both rabbit and hamster cell cultures. In addition, cellular DNA synthesis was depressed and cytopathic effects occurred in both cell systems. These cytopathic effects were not observed in cell cultures treated with HSV previously inactivated with ultraviolet light. Compared with parallel cultures at 33 C, the amount of viral DNA synthesized at 39 C was greatly reduced in both systems. In hamster cells, the reduction was twofold greater than in rabbit cells. This cell-dependent thermal inhibition of HSV replication in hamster cells did not occur with vaccinia virus.     

Existence of a form of SV40 T antigen incapable of interacting with DNA

The interaction of SV40 T-antigen and viral DNA was studied by using adsorption of DNA-protein complexes on nitrocellulose filters. The T-antigen purification procedure included ion-exchange chromatography on DEAE-cellulose, selective adsorption of cellular proteins on single-stranded DNA-cellulose, chromatography on heparin-Sepharose and removal of cell proteins by an immunosorbent. Only the latter step allowed to remove the contamination of cellular DNA-binding proteins, judging from the reaction of T-antigen neutralization by specific antibodies. It was shown that T-antigen and cellular DNA-binding proteins interact with SV40 DNA at different values of pH, namely ah 6,0-6,4 and 7,9, respectively. The T-antigen obtained was passed through a column with native DNA-cellulose at pH and ionic strength values optimal for interaction with DNA. The bulk of T-antigen (30-40%) did not bind to native thymus DNA and did not interact with SV40 DNA. It is assumed that this fraction is a form of T-antigen, which undergoes structural or functional changes during specific interaction with viral or cellular DNAs.     

Recent progress in studies of polyomavirus tumour antigens

The polyomavirus tumour (T) antigens were originally identified by their reactivity with antisera from tumour-bearing animals. The primary structure of the three T-antigens has been established by combining the information from the nucleotide sequencing of DNA, RNA analysis, and peptide mapping. The functions of the T-antigens in productive infection and cellular transformation have largely been analysed by using virus mutants. The large T-antigen binds specifically to polyomavirus DNA. This binding is probably linked to the activity of the protein in the control of viral DNA and RNA synthesis. In addition, the large T-antigen has the ability to confer an unlimited growth potential to cells in culture. The middle T-antigen is a primary inducer of cellular transformation. The part of this protein that is located in the plasma membrane, is associated with a tyrosine kinase activity. The small T-antigen, finally, has not yet been studied extensively. However, small T-antigen has to be expressed to allow a complete productive infection cycle in mouse cells.     

Interaction of Simian Virus 40 chromatin with Simian Virus 40 T-antigen.

We have studied the binding of the tumor antigen (T-antigen) of simian virus 40 to simian virus 40 chromatin (minichromosomes). The minichromosomes isolated from infected cells by a modification of standard techniques were relatively free of contaminating RNA and cellular DNA and had a ratio (by weight) of protein to DNA of approximately 1; their DNA was 50 to 60% digestible to an acid-soluble form by staphylococcal nuclease. Cleavage of this chromatin with restriction endonucleases indicated that the nuclease-resistant regions were randomly distributed in the population of minichromosomes, but were not randomly distributed within minichromosomes. Only 20 to 35% of these minichromosomes adsorbed nonspecifically to nitrocellulose filters, permitting binding studies between simian virus 40 T-antigen and chromatin to be performed. Approximately two to three times as much T-antigen was required to bind chromatin as to bind an equivalent amount of free DNA. When T-antigen was present in excess, both chromatin and free DNA were quantitatively retained on the filters. On the other hand, when DNA or chromatin was present in excess, only one-third as much chromatin as DNA was retained. We suggest that T-antigen-chromatin complexes may be formed by the cooperative binding of T-antigen to chromatin, whereas T-antigen-DNA complexes may be formed by simple bimolecular interactions.