Structural and biological analysis of integrated polyoma virus DNA and its adjacent host sequences cloned from transformed rat cells.

EcoRI fragments containing integrated viral and adjacent host sequences were cloned from two polyoma virus-transformed cell lines (7axT and 7axB) which each contain a single insert of polyoma virus DNA. Cloned DNA fragments which contained a complete coding capacity for the polyoma virus middle and small T-antigens were capable of transforming rat cells in vitro. Analysis of the flanking sequences indicated that rat DNA had been reorganized or deleted at the sites of polyoma virus integration, but none of the hallmarks of retroviral integration, such as the duplication of host DNA, were apparent. There was no obvious similarity of DNA sequences in the four virus-host joins. In one case the virus-host junction sequence predicted the virus-host fusion protein which was detected in the transformed cell line. DNA homologous to the flanking sequences of three out of four of the joins was present in single copy in untransformed cells. One copy of the flanking host sequences existed in an unaltered form in the two transformed cell lines, indicating that a haploid copy of the viral transforming sequences is sufficient to maintain transformation. The flanking sequences from one cell line were further used as a probe to isolate a target site (unoccupied site) for polyoma virus integration from uninfected cellular DNA. The restriction map of this DNA was in agreement with that of the flanking sequences, but the sequence of the unoccupied site indicated that viral integration did not involve a simple recombination event between viral and cellular sequences. Instead, sequence rearrangements or alterations occurred immediately adjacent to the viral insert, possibly as a consequence of the integration of viral DNA.     

Mutant din-21, a variant of polyoma virus containing a mouse DNA sequence in the viral genome.

An unusual non-defective mutant of polyoma virus with an anomalously large genome, designated din-21, has been isolated. The viral chromosome lacks 49 base pairs of the putative control region between the origin of replication and the initiation codon for the early proteins, the T-antigens. In their stead , 95 base pairs, with limited homology to the deleted sequence and apparently of mouse origin, have been inserted. The primary sequence of the insert DNA has been determined and some of the biological properties of the mutant examined. It transforms rat-1 cells slightly better than wild-type virus and grows slightly less well in lytically infected mouse cells. It does not interfere with the growth of wild-type polyoma virus. The properties of this mutant suggest that it is a natural isolate of mouse cells. The mutant was presumably generated by reciprocal recombination between polyoma DNA and mouse host DNA. This could be associated with the integration of a viral DNA sequence into the host chromosome during the viral replicative cycle.     

Immunization against the polyoma virus-induced tumor-specific transplantation antigen by early region mutants of the virus

To investigate the relation between the polyoma tumor-specific transplantation antigen and the virus-coded proteins, mice were immunized by inoculation of a variety of viable polyoma virus mutants and then challenged with polyoma virus-induced tumors. Two classes of early region mutants were used. One class produces a normal small T-antigen and truncated middle and large T-antigens. The second class (hr-t mutants) forms a normal large T-antigen together with N-terminal fragments of small and middle T-antigens. All mutants, transforming as well as nontransforming, induced protection against polyoma virus tumors. However, there were quantitive differences between the mutants. The finding that an hr-t mutant could induce tumor rejection suggests that full-length middle and small T-antigens are not necessary for the induction of this response. Since intact middle T-antigen is the only virus-coded protein known to associate with the plasma membrane, the possibility must be considered that the polyoma virus tumor-specific transplantation antigen consists of cellular components.     

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.     

Sequence from early region of polyoma virus DNA containing viral replication origin and encoding small, middle and (part of) large T antigens.

The sequence of about one third of the polyoma virus genome is presented. This sequence covers the origin of replication of two large plaque strains (A2 and A3) of polyoma virus. The two strains differ by 11 bp in the origin region. A model for replication is suggested. The sequence probably also covers the entire coding region of two of the polyoma virus early proteins--small and middle T antigens--as well as part of the coding region for large T antigen. Over a small region of the DNA, all three coding frames contain termination codons, which argues a need for spliced early messenger RNAs. In another region of the DNA, two coding frames can be used. Correlation with protein data suggests that one frame codes for part of middle T antigen and the other for part of large T antigen.     

Polyoma virus DNA: Sequence from the late region that specifies the leader sequence for late mRNA and codes for VP2, VP3, and the N-terminus of VP1.

The DNA sequence of part of the late region of the polyoma virus genome is presented. This sequence of 1,348 nucleotide pairs encompasses the leader region for late mRNA and the coding sequence for the two minor capsid proteins VP2 and VP3. The coding sequence for the N-terminus of the major capsid protein overlaps the C-terminus of VP2/VP3 by 32 nucleotide pairs. From the DNA sequence the sizes and sequences of VP2 and VP3 could be predicted. Potential splicing signals for the processing of late mRNA's could be identified. Comparisons are made between the sequence of polyoma virus DNA and corresponding regions of simian virus 40 DNA.     

Partial amino-terminal sequences of the polyoma nonhistone proteins VP1, VP2, and VP3 synthesized in vitro.

The three polyoma virus capsid proteins VP1, VP2, and VP3 were synthesized in vitro in the presence of several radiolabeled amino acids and, after purification on sodium dodecyl sulfate-polyacrylamide gels, were subjected to sequential Edman degradation. The partial amino-terminal amino acid sequences obtained were compared with the sequence of amino acids predicted from the polyoma virus DNA sequencing (Arrand et al., J. Virol. 33:606--618, 1980). Together, these results showed that the 5' ends of the VP1, VP2, and VP3 coding sequences are located 1,217, 289, and 634 nucleotides, respectively, from the junction of HpaII restriction fragments 3 and 5.     

Regulatory mutants of polyoma virus defective in DNA replication and the synthesis of early proteins

In polyoma virus the origin of replication, the 5′ ends of early mRNAs, and the initiation codon for early protein synthesis map within an approximately 200 bp region of the genome. We have previously reported the isolation and partial characterization of viable mutants of polyoma virus with deletions in this important regulatory region of the genome. Three of the mutants with large deletions, one of which had significantly altered growth properties, have been further characterized with respect to their nucleotide sequence alterations and their levels of viral DNA replication and of early protein synthesis. The nearly coincident deletions in mutants 17 and 2–19 reduce the capacity of these viruses to replicate, even in the presence of a coinfecting virus; thus they help define one boundary of the origin of DNA replication. The deletion in mutant 75 appears to remove sequences that are essential for efficient expression of early genes, but has little or no effect upon DNA replication. Its defect is complemented in trans by wild-type virus. All three mutants eliminate sequences which are candidates for RNA polymerase and ribosome binding sites near the initiation codon for early proteins.     

Genomic structure of human polyoma virus JC: nucleotide sequence of the region containing replication origin and small-T-antigen gene

The nucleotide sequence of the region of human polyoma virus JC DNA between 0.5 and 0.7 map units from a unique EcoRI cleavage site was determined and compared with those of the corresponding regions of another human polyoma virus, BK, and simian virus 40 DNAs. Within this region consisting of 945 base pairs, we located the origin of DNA replication near 0.7 map units, the entire coding region for small T antigen, and the splice junctions for large-T-antigen mRNA. The deduced amino acid sequences for small T antigen and the part of large T antigen markedly resembled those of polyoma virus BK and simian virus 40. The results strongly suggest that polyoma virus JC has the same organization of early genome as polyoma virus BK and simian virus 40 on the physical map, with the EcoRI site as a reference point.     

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.     

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.     

Structural and functional analysis of a polyoma-related mammalian plasmid (L factor): the enhancer activity and plasmid establishment.

L factor is a unique plasmid DNA which was originally discovered in a subclone (B822) of mouse L cells at a high copy number (more than 5,000 copies/cell). The presence of L factor caused no detectable abnormalities to the plasmid-bearing cells. We determined the total DNA sequence of the L factor I (and a part of L factor II) and compared it with that of polyoma DNA. Both DNA are common to the general construction of DNA frames such as early, late and noncoding regions, suggesting the two to be closely related. On the other hand, the L factor DNA sequences differ substantially from that of polyoma in the DNA sequences corresponding to the polyoma large T antigen, capsid proteins and a portion of the enhancer region. In order to investigate the mechanism of plasmid establishment of L factor, we compared the enhancer activity, capacity of DNA replication and efficiency of plasmid establishment of L factor with those of polyoma. The results indicate that L factor enhancer activity and DNA replication capacity were considerably lower than those of polyoma, suggesting that these altered (lowered) activities associated with L factor contribute to the plasmidal establishment and stable maintenance of L factor.     

Subcellular localisation of the middle and large T-antigens of polyoma virus.

The distribution of two of the polyoma virus early proteins (the large and middle T-antigens) in lytically infected mouse cells and transformed rat cells has been investigated by indirect immunofluorescence and immuno-electron microscopy using well-characterised monoclonal antibodies. By these techniques, the viral large T-antigen was found almost exclusively in the nucleus, sometimes in association with nuclear pores, but never in the nucleolus. In lytically infected, but not transformed cells, fluorescence was detected in discrete areas ('hot spots') within the nucleus and, in a minor population of lytically infected cells, cytoplasmic immunoreactive material was observed. The viral middle T-antigen was found in association with most cytoplasmic membranes and in the majority of cells mainly in the endoplasmic reticulum. Only a fraction of the staining was observed in the plasma membrane and no staining in the nucleoplasm was observed. The data suggest that the site of action of the major transforming activity of polyoma virus need not be at the plasma membrane. Functions associated with the viral antigens are discussed in terms of their subcellular distributions within cells.     

Polyoma virus defective DNAs. II. Physical map of a molecule with rearranged and reiterated sequences (D74).

The structure of the polyoma virus defective species D74 (74% the size of full-length polyoma virus DNA) has been determined and compared with that of polyoma virus A2 DNA. D74 appears to be composed entirely of viral DNA sequences. (No host DNA sequences have been detected.) It is made up of three DNA segments, each about 24, 24 and 27% in size. The two 24% segments appear to be identical and the 27% segment contains one copy of all the sequences found in the 24% fragments as well as a duplication of some of the sequences. When related to the physical map of A2 DNA, each segment is found to be composed of viral sequences from 1 to about 19 map units, 67 to 69 map units and 70 to 72 map units.Three features found in other polyoma virus defective species (Lund et al., 1977) are also present in D74. (1) Sequences from the region around 67 map units are linked to other (non-contiguous) viral sequences. (2) Sequences at about 72 map units are linked to sequences at 1 map unit. (3) Multiple copies of sequences from around the origin of viral DNA replication are present. From studies on other polyoma defective molecules (Griffin &; Fried, 1975; Lund et al., 1977), the origin of DNA replication for polyoma virus has been defined to lie within the sequences from 67 to 72 map units. Since D74 replicates efficiently but lacks the sequences between 69 to 70 map units, the origin of DNA replication appears to be further defined as lying within 67 and 69 map units and/or 70 to 72 map units.     

Electron microscopic demonstration of the presence of amplified sequences at the 5''-ends of the polyoma virus late mRNAs.

Electron microscopic techniques were used to examine the structure of the leader sequences at the 5'-ends of the late polyoma virus mRNAs. The three late mRNA's were partially purified and hybridized to an E. coli plasmid containing two polyoma virus genomes inserted in tandem. The hybrids were spread by the cytochrome c-formamide technique and visualized in the electron microscope. These studies revealed that whereas the body of a given mRNA molecule can hybridize with only one of the two corresponding body sequences in the two adjacent viral genomes, the leader of the same mRNA molecule can hybridize with both copies of the leader sequence-specific DNA. The mVP1 and mVP3 RNA species thus generated hybrids containing two loops, while mVP2 molecules formed hybrids containing one loop. Hence, the leaders of the three polyoma virus late mRNA species must contain two or more repeats of a sequence transcribed from a unique DNA segment. Length measurements showed that most leaders in the late mRNA's consist of at least 200 nucleotides and some contain up to 500 nucleotides, whereas the basic repeat sequence contains about 60 nucleotides.     

Sequence repeats in a polyoma virus DNA region important for gene expression.

The sequenced prototype strains (A2 and A3) of polyoma virus lack sequence duplications characteristic of other papovaviruses. However, we found that five polyoma virus strains (P16, Toronto large plaque, MV, Ts 48, and NG59R) contain tandemly duplicated sequences in a region near the late RNA leader. Although the duplications vary in size (31 to 84 base pairs) and location (between nucleotide [nt] 5068 and nt 5185), the sequence between nt 5114 and nt 5137 is contained within all five duplicated segments. This region is known to be important in polyoma virus early gene expression, and it contains sequences capable of enhancing the expression of nonviral genes. Inspection of the sequences at and around the ends of the repeats indicated that the duplications do not arise by homologous recombination, and there was no indication that a sequence-specific mechanism results in their formation. However, the variation in the structure of the repeats among different polyoma virus strains suggests that these sequence duplications are a recent evolutionary occurrence. The potential biological significance of this variation is discussed.     

mlt Mutants of polyoma virus

New mlt deletion mutants of polyoma virus were isolated, and their abilities to produce a lytic response in mouse cells or to transform rat cells were assessed. Their properties were analyzed in terms of the sequences deleted and their effects upon the structure and functions of the viral middle and large T-antigens.     

Regions of the polyoma genome coding for T antigens.

The early region of the polyoma genome encodes three T antigens. We have analyzed the organization of the coding regions for the T antigens, using the nucleotide sequence of polyoma DNA and peptides derived from purified, radio-labeled T antigens, separated by two-dimensional electrophoresis and chromatography. We compared the peptides, predicted from the nucleotide sequence of the DNA, with those derived from the purified T antigens. We also compared chemically synthesized peptides, predicted from the DNA sequence, with observed peptides. The results show that the three polyoma T antigens are encoded in overlapping regions of the viral DNA, translated, in part, in two different reading frames.