Construction and analysis of viable deletion mutants of polyoma virus

Comparison of phosphorylation of two polyoma virus middle T antigens in vivo and in vitro

Two species of polyoma virus middle T antigen were detected in both lytically infected and transformed cells by in vitro kinase assay of immunoprecipitates. A minor species with an apparent molecular weight of 58,000 (58K) represented less than 10% of the total middle T protein. This species was roughly 10 times more active as a phosphate acceptor than was the predominant 56K form. Partial proteolytic mapping experiments showed that the same site was phosphorylated in both species. Mapping of the middle T antigens from a series of deletion mutants suggested that the major site of phosphorylation is tyrosine residue 315. Phosphorylation occurred on both middle T species in vivo, involving sites predominantly other than the tyrosine labeled in vitro. The 56K and 58K middle T forms differed from each other in their in vivo phosphorylation patterns. Some phosphate was incorporated into the 58K species in a region of the molecule to which at least part of the apparent molecular weight different could be mapped. hr-t mutant NG-59, which codes for a slightly altered middle T, produced only a single species (56K) which was inactive in the in vitro kinase reaction. Moreover, no 58K species appeared in vivo with this mutant. hr-t mutants are therefore defective in both aspects of phosphorylation. Phenotypically normal revertant cells of a polyoma transformed line failed to express any middle T antigens or associated kinase activity.

Growth and persistence of polyoma early region deletion mutants in mice

Replication of early region deletion mutations in polyoma in the kidneys of mice was in most cases reduced by 10- to 10,000-fold, as compared with wild-type polyoma, and the mutants failed to produce the persistent infection observed with wild-type polyoma.

Characterization of polyoma mutants with altered middle and large T-antigens

The viable polyoma mutants dl1013, dl1014, and dl1015 produced shortened middle and large T-antigens. In mouse 3T3 cells, dl1013 and dl1014 grew at normal rates, and dl1015 grew at a reduced rate. dl1015 behaved phenotypically as a double mutant, with deficiencies both in the stimulation of the host cell and the replication of viral DNA. Only the former defect could be complemented by the ts-a mutant, which produced a normal middle T-antigen and a temperature-sensitive large T-antigen. This result suggests that middle T-antigen is involved in the induction of cellular DNA synthesis. Of the three mutants, dl1015 alone failed to transform rat fibroblasts to growth in semisolid medium. This defect could not be complemented by the ts-a mutant. Determination of the base sequences of the mutant DNAs showed that dl1013 and dl1014 had overlapping deletions of 21 and 9 base pairs, respectively, and that the dl1015 deletion of 30 base pairs was contiguous to the other mutations on their 3' sides. Analyses of the mutant t-antigens showed that all three mutants produced shortened middle T-antigens, whereas only dl1015 large T-antigen was detectably reduced in size.

Transformation of rat fibroblasts by cloned defective polyoma DNA

Defective polyoma DNA molecules isolated from mouse cells infected with high-multiplicity-passaged virus were cloned in pBR322, and the recombinant plasmids were tested for their capacity to transform Fischer rat 3T3 cells in culture. Recombinants carrying an intact proximal portion of the early region, i.e., the region coding for both small and middle T antigens, were able to induce the transformed phenotype. A recombinant plasmid containing a defective polyoma genome with a deletion of about 300 base pairs in the region coding for the C-terminal segment of middle T antigen failed to transform.

Transformation of rat cells by an altered polyoma virus genome expressing only the middle-T protein

A modified polyoma virus genome has been constructed which can encode the middle-T protein, but not the large-T or small-T proteins. This was achieved, starting with the full length viral DNA inserted into a plasmid vector, by replacing a small genomic restriction fragment spanning the middle-T intervening sequence with the equivalent fragment from a cloned partial cDNA copy of the middle-T protein mRNA. Transfection of the modified viral DNA into cultured rat cells efficiently induced the formation of transformed cell foci which gave rise to cell lines that grew as tumours after injection into Fisher rats. The only viral early-region antigen synthesized by the cell lines was the middle-T protein. Expression of the middle-t protein is therefore sufficient to establish and maintain a transformed state. The viral mRNA produced by two of the transformed cell lines was structurally indistinguishable from the normal middle-T mRNA found in productively infected cells, suggesting that RNA splicing is not an essential step in the biogenesis of this messenger.

Antibodies specific for the polyoma virus middle-size tumor antigen

We have obtained antibodies specific for the polyoma virus middle-size tumor antigen (middle T antigen) by immunizing rabbits with a synthetic peptide, Lys-Arg-Ser-Arg-His-Phe, corresponding to the six carboxy-terminal amino acids of the middle T antigen predicted from the nucleotide sequence of polyoma DNA. The antipeptide serum precipitates the polyoma middle T antigen but not the small or large tumor antigens, and precipitation is inhibited in the presence of the peptide. Two cellular proteins, 30,000 and 26,000 daltons, are also precipitated specifically by the antipeptide serum and may have amino acid sequences related to the peptide. Two other cellular proteins, 33,000 and 25,000 daltons, are precipitated only in the presence of the peptide and may associate with it in cell extracts. Antisera directed against synthetic peptides are likely to be important in various ways, including the production of antibodies directed against particular determinants and the recognition of unknown proteins whose genes have been analyzed.

Effect of sodium butyrate on induction of cellular and viral DNA syntheses in polyoma virus-infected mouse kidney cells

Sodium butyrate inhibited initiation of viral and cellular DNA replication in polyoma virus-infected mouse kidney cells. Ongoing viral or cellular DNA replication, however, was not affected by the presence of the substance. Butyrate had no effect on T-antigen synthesis and on the stimulation of transcription, one of the earliest reactions of the infected cells to the appearance of T-antigen, nor did it inhibit expression of late viral genes (synthesis of viral capsid proteins). In addition to blocking the onset of DNA synthesis, butyrate also inhibited stimulation of the activities of enzymes involved in DNA synthesis. When butyrate was removed, viral and cellular DNA syntheses were induced in parallel after a lag period of approximately 4 h. At the same time, the activities of enzymes involved in DNA synthesis increase. If protein synthesis was inhibited during part of the lag period, the initiation of DNA synthesis was retarded for the same time interval, suggesting that the proteins involved in the initiation of DNA replication had to be made. We have developed an in vitro system for measuring DNA synthesis in crude nuclear preparations which mimics the status of DNA replication in intact cells and may help in future experiments to study the requirements for initiation of cellular and viral DNA synthesis and the possible involvement of T-antigens in this reaction.

DNA sequences of polyoma virus early deletion mutants

The DNA sequences of four "early" viable deletion mutants of polyoma virus have been determined. Two of these (dl-8 and dl-23) are mutants with deletions in the region of the genome that codes for parts of both large and middle T-antigens, and two (dl-6 and dl-28) are mutants with deletions around the viral origin of replication. The former mutants have altered transformation properties relative to wild-type virus, and dl-8 appears to be replication deficient (B. E. Griffin and C. Maddock, J. Virol. 31:645-656, 1979). Sequences are discussed in terms of the altered phenotypes observed for the various mutants, the DNA structures and protein sequences that are affected by the deletions, and how these might affect the biological properties of the mutants.

Requirement for the C-terminal region of middle T-antigen in cellular transformation by polyoma virus

Deletions of polyoma virus DNA around the region that codes for the C-terminus of the viral middle T-antigen were created using a transforming fragment (BamH I/EcoR I) of viral DNA cloned in the plasmid vector pAT153. These species were recloned and assayed for their ability to transform Rat-1 cells in culture. Our results showed that whereas the DNA sequence between the presumed translational termination codon for the viral middle T-antigen and the single viral EcoR I site could be removed with no apparent effect on transformation, the removal of the termination codon itself or any amino acid coding sequences of this protein caused a drastic decrease in the transforming ability of the DNA. Transfection of Rat-1 cells with plasmids that contained viral DNA with deletions which corresponded to the last fourteen or more amino acids of the middle T-antigen never gave rise to cellular transformation.

Nucleotide sequence changes in polyoma ts-a mutants: correlation with protein structure

The mutations in three polyoma ts-a mutants have been determined. Two mutants, ts-25 and ts-52, have different single-base changes at the same position (2883) in the early region corresponding to a conserved glycine residue very near the C-terminus of the polyoma large T antigen. Mutant ts-48 has a single-base change at position 2341, as well as a second change at position 1228, in the region of large T antigen shared with medium T antigen.

A cloned polyoma DNA fragment representing the 5' half of the early gene region is oncogenic

The two polyoma DNA fragments generated by cleavage with BamHI and EcoRI were cloned in pBR322, and their oncogenic potential was tested in vivo and in vitro. Only recombinant plasmid DNA containing a polyoma DNA fragment which extends clockwise from 58 to 0 map units and include approximately the 5'-proximal half of the early gene region produced tumors in newborn hamsters and transformed rat embryo cells in tissue culture. Southern blotting analysis indicated that the entire 2.2-kilobase polyoma BamHI-EcoRI fragment was intact in both a tumor cell line and a cell line transformed in culture which we examined. The presence of polyoma middle and small T antigen in these lines was demonstrated by immunoprecipitation and tryptic peptide mapping. DNA from a recombinant plasmid containing a polyoma genome deleted between 90 and 4 map units failed to induce tumors or transform cells.

Polyoma virus middle t antigen: a tumor progression factor

Polyoma virus (PyV) deletion mutant dl23 (affecting both large T and middle t but not small t antigens) was used to study transformation of 3T3 rat cells. This mutant generated stable transformants in the agar assay at a frequency similar to that of wild-type virus (WT). However, WT-induced transformants were detected 3 weeks after infection, whereas those induced by the mutant could not be detected until 6 to 8 weeks after infection. In this respect, dl23 PyV behaved like WT simian virus 40 (SV40). Cells transformed by WT SV40 or by dl23 PyV were similar in all their transformed properties. Those transformed by WT PyV were different from the others on the basis of morphology, cell adhesion to the substrate, release of protease activity, efficiency of doubling in agar, growth rate, and time required for tumor formation. Saturation density, the ability to grow in agar, the serum requirement for cloning, and the ability to grow on a cell monolayer were similar for all transformants. Middle t antigen enhanced membrane alterations and growth rate of the transformed cells, shortening the time required for tumor formation in rats.

Viable deletion mutant in the medium and large T-antigen-coding sequences of the polyoma virus genome

A polyoma virus mutant that maps in the early region between the known hr-t and ts-a mutants has been isolated. Its 66-base-pair deletion results in structural changes in both medium and large T-antigens but causes no substantial alterations in viral replication or cell transformation.

Deletion mutants of polyoma virus defining a nonessential region between the origin of replication and the initiation codon for early proteins

Mutants of polyoma virus with deletions as large as 90 base pairs were isolated by selecting spontaneously arising genomes resistant to endonuclease HaeII or by treating HaeII- or BglI- cleaved linear DNAs with S1 nuclease and exonuclease III. All of the mutants were viable and, therefore, defined a nonessential region in the polyoma genome between the origin of DNA replication and the initiation codon for translation of early proteins. Several mutants with large deletions had altered growth properties, giving smaller plaques and lower virus yields than the parental wild-type virus. These viruses may lack sites that are important for DNA replication or for transcription and translation of early mRNA's. All of the mutants tested could transform BHK-21 cells to anchorage independence.