Transformation of rat embryo fibroblasts by cloned polyoma virus DNA fragments containing only part of the early region

Stimulation of α1a adrenergic receptors induces cellular proliferation or antiproliferative hypertrophy dependent solely on agonist concentration

Stimulation of α_1aAdrenergic Receptors (ARs) is known to have anti-proliferative and hypertrophic effects; however, some studies also suggests this receptor can increase cell proliferation. Surprisingly, we find the α_1aAR expressed in rat-1 fibroblasts can produce either phenotype, depending exclusively on agonist concentration. Stimulation of the α_1aAR by high dose phenylephrine (>10⁻⁷ M) induces an antiproliferative, hypertrophic response accompanied by robust and extended p38 activation. Inhibition of p38 with SB203580 prevented the antiproliferative response, while inhibition of Erk or Jnk had no effect. In stark contrast, stimulation of the α_1aAR with low dose phenylephrine (∼10⁻⁸ M) induced an Erk-dependent increase in cellular proliferation. Agonist-induced Erk phosphorylation was preceded by rapid FGFR and EGFR transactivation; however, only EGFR inhibition blocked Erk activation and proliferation. The general matrix metalloprotease inhibitor, GM6001, blocked agonist induced Erk activation within seconds, strongly suggesting EGFR activation involved extracellular triple membrane pass signaling. Erk activation required little Ca²⁺ release and was blocked by PLCβ or PKC inhibition but not by intracellular Ca²⁺ chelation, suggesting Ca²⁺ independent activation of novel PKC isoforms. In contrast, Ca²⁺ release was essential for PI3K/Akt activation, which was acutely maximal at non-proliferative doses of agonist. Remarkably, our data suggests EGFR transactivation leading to Erk induced proliferation has the lowest activation threshold of any α_1aAR response. The ability of α_1aARs to induce proliferation are discussed in light of evidence suggesting antagonistic growth responses reflect native α_1aAR function.

Polyoma virus middle T antigen and its role in identifying cancer-related molecules

Most cancer researchers take for granted some of the basic concepts about the molecular changes that underlie tumorigenesis. These include the principles that tyrosine kinases and the phosphorylation of phosphatidylinositol by phosphatidylinositol 3-kinases are important in the signalling pathways that control proliferation and apoptosis, and hence cancer formation. However, how many know that a small DNA mouse virus was crucial in establishing both of these tenets?

Viral DNA synthesis in nonpermissive rat F-111 cells and its role in neoplastic transformation by polyomavirus

We have investigated the occurrence and role of polyomavirus DNA synthesis in neoplastic transformation by this virus. We show that after infection of Fischer rat F-111 cells at 37 degrees C, there is two- to threefold increase in the level of viral DNA as compared with the input signal, with a peak observed between 5 and 7 days postinfection. Viral DNA synthesis is about 10 times higher at 33 degrees C and increases up to 15 days postinfection. Most of the viral DNA produced is supercoiled (form I DNA). On the basis of in situ hybridization, it appears that viral replication is restricted to a small fraction of the population. At the lower temperature, more cells are permissive for viral DNA synthesis and the level of synthesis per permissive cell is higher. The DNA synthesis observed is large T-antigen dependent, and the increase in viral DNA synthesis at 33 degrees C is paralleled by an increase in the expression of this viral protein. When large T antigen is inactivated, the half-life of de novo-synthesized viral DNA is less than 12 h, suggesting that large T antigen may be responsible for the stability of the viral genomes as well as their synthesis. Surprisingly, at early times postinfection (0 to 48 h), when the essential function of large T antigen in transformation is expressed (as demonstrated in shift-up experiments with tsa mutants), the level of large T antigen is below the detection level and is at least 10-fold lower than the levels observed in permissive infections at the start of viral DNA synthesis. The difference in viral DNA at 37 and 33 degrees C allowed us to study its effect on transformation. Although an increase in transformation frequency is observed in wild-type A2 infections carried at 33 degrees C (frequencies two to three times higher than at 37 degrees C), this increase appears to be unrelated to the increase in viral DNA synthesis. Furthermore, the overall level of viral DNA and large T antigen in F-111 cells may not affect the integration of the viral genome, since the patterns of integration in cells transformed by wild-type A2 at 33 and 37 degrees C appear similar. The results are compatible with a role for large T antigen in integration-transformation which is not simply to amplify the viral genome to enhance the probability of its integration.

Multiple subelements within the polyomavirus enhancer function synergistically to activate DNA replication

The polyomavirus origin for DNA replication comprises at least two essential, but functionally distinct, cis-acting components. One of these, the origin core, is required only for DNA replication. It includes binding sites for large T antigen and the origin of bidirectional DNA replication. The other component is required for both transcription and DNA replication and is represented by two functionally redundant regions, alpha and beta, which are elements of the polyomavirus enhancer. Whereas either enhancer element will activate DNA replication, both enhancer elements are required to constitute a functional enhancer of transcription. To identify the sequences that make up each enhancer element, we have subjected them separately to in vitro mutagenesis and measured their capacity to activate replication in cis of the origin core in MOP-8 cells, which provide all trans-acting replicative functions including large T antigen. The results reveal that the beta enhancer element is composed of three subelements, two auxiliary subelements, and a core subelement. The core subelement independently activated DNA replication, albeit poorly. The auxiliary subelements, which were inactive on their own, acted synergistically with the core subelement to increase its activity. Interestingly, dimers of the beta core subelement functioned as well as the combination of a beta auxiliary subelement and a core subelement, suggesting that the subelements are functionally equivalent. The alpha enhancer element is organized similarly; it too comprises an auxiliary subelement and a core subelement. These results lead us to suggest that the polyomavirus enhancer comprises two levels of organization; two or more enhancer elements form an enhancer, and two or more subelements make up an enhancer element. The subelements share few sequences and serve as binding sites for distinct cellular factors. It appears, therefore, that a number of different cellular proteins function cooperatively to activate polyomavirus DNA replication by a common mechanism.

Viral DNA synthesis in nonpermissive rat F-111 cells and its role in neoplastic transformation by polyomavirus

We have investigated the occurrence and role of polyomavirus DNA synthesis in neoplastic transformation by this virus. We show that after infection of Fischer rat F-111 cells at 37 degrees C, there is two- to threefold increase in the level of viral DNA as compared with the input signal, with a peak observed between 5 and 7 days postinfection. Viral DNA synthesis is about 10 times higher at 33 degrees C and increases up to 15 days postinfection. Most of the viral DNA produced is supercoiled (form I DNA). On the basis of in situ hybridization, it appears that viral replication is restricted to a small fraction of the population. At the lower temperature, more cells are permissive for viral DNA synthesis and the level of synthesis per permissive cell is higher. The DNA synthesis observed is large T-antigen dependent, and the increase in viral DNA synthesis at 33 degrees C is paralleled by an increase in the expression of this viral protein. When large T antigen is inactivated, the half-life of de novo-synthesized viral DNA is less than 12 h, suggesting that large T antigen may be responsible for the stability of the viral genomes as well as their synthesis. Surprisingly, at early times postinfection (0 to 48 h), when the essential function of large T antigen in transformation is expressed (as demonstrated in shift-up experiments with tsa mutants), the level of large T antigen is below the detection level and is at least 10-fold lower than the levels observed in permissive infections at the start of viral DNA synthesis. The difference in viral DNA at 37 and 33 degrees C allowed us to study its effect on transformation. Although an increase in transformation frequency is observed in wild-type A2 infections carried at 33 degrees C (frequencies two to three times higher than at 37 degrees C), this increase appears to be unrelated to the increase in viral DNA synthesis. Furthermore, the overall level of viral DNA and large T antigen in F-111 cells may not affect the integration of the viral genome, since the patterns of integration in cells transformed by wild-type A2 at 33 and 37 degrees C appear similar. The results are compatible with a role for large T antigen in integration-transformation which is not simply to amplify the viral genome to enhance the probability of its integration.

Multiple subelements within the polyomavirus enhancer function synergistically to activate DNA replication

The polyomavirus origin for DNA replication comprises at least two essential, but functionally distinct, cis-acting components. One of these, the origin core, is required only for DNA replication. It includes binding sites for large T antigen and the origin of bidirectional DNA replication. The other component is required for both transcription and DNA replication and is represented by two functionally redundant regions, alpha and beta, which are elements of the polyomavirus enhancer. Whereas either enhancer element will activate DNA replication, both enhancer elements are required to constitute a functional enhancer of transcription. To identify the sequences that make up each enhancer element, we have subjected them separately to in vitro mutagenesis and measured their capacity to activate replication in cis of the origin core in MOP-8 cells, which provide all trans-acting replicative functions including large T antigen. The results reveal that the beta enhancer element is composed of three subelements, two auxiliary subelements, and a core subelement. The core subelement independently activated DNA replication, albeit poorly. The auxiliary subelements, which were inactive on their own, acted synergistically with the core subelement to increase its activity. Interestingly, dimers of the beta core subelement functioned as well as the combination of a beta auxiliary subelement and a core subelement, suggesting that the subelements are functionally equivalent. The alpha enhancer element is organized similarly; it too comprises an auxiliary subelement and a core subelement. These results lead us to suggest that the polyomavirus enhancer comprises two levels of organization; two or more enhancer elements form an enhancer, and two or more subelements make up an enhancer element. The subelements share few sequences and serve as binding sites for distinct cellular factors. It appears, therefore, that a number of different cellular proteins function cooperatively to activate polyomavirus DNA replication by a common mechanism.

Recombinant retroviruses encoding simian virus 40 large T antigen and polyomavirus large and middle T antigens

We used a murine retrovirus shuttle vector system to construct recombinants capable of constitutively expressing the simian virus 40 (SV40) large T antigen and the polyomavirus large and middle T antigens as well as resistance to G418. Subsequently, these recombinants were used to generate cell lines that produced defective helper-free retroviruses carrying each of the viral oncogenes. These recombinant retroviruses were used to analyze the role of the viral genes in transformation of rat F111 cells. Expression of the polyomavirus middle T antigen alone resulted in cell lines that were highly tumorigenic, whereas expression of the polyomavirus large T resulted in cell lines that were highly tumorigenic, whereas expression of the polyomavirus large T resulted in cell lines that were unaltered by the criteria of morphology, anchorage-independent growth, and tumorigenicity. More surprisingly, SV40 large T-expressing cell lines were not tumorigenic despite the fact that they contained elevated levels of cellular p53 and had a high plating efficiency in soft agar. These results suggest that the SV40 large T antigen is not an acute transforming gene like the polyomavirus middle T antigen but is similar to the establishment genes such as myc and adenovirus EIa.

Recombinant retroviruses encoding simian virus 40 large T antigen and polyomavirus large and middle T antigens

We used a murine retrovirus shuttle vector system to construct recombinants capable of constitutively expressing the simian virus 40 (SV40) large T antigen and the polyomavirus large and middle T antigens as well as resistance to G418. Subsequently, these recombinants were used to generate cell lines that produced defective helper-free retroviruses carrying each of the viral oncogenes. These recombinant retroviruses were used to analyze the role of the viral genes in transformation of rat F111 cells. Expression of the polyomavirus middle T antigen alone resulted in cell lines that were highly tumorigenic, whereas expression of the polyomavirus large T resulted in cell lines that were highly tumorigenic, whereas expression of the polyomavirus large T resulted in cell lines that were unaltered by the criteria of morphology, anchorage-independent growth, and tumorigenicity. More surprisingly, SV40 large T-expressing cell lines were not tumorigenic despite the fact that they contained elevated levels of cellular p53 and had a high plating efficiency in soft agar. These results suggest that the SV40 large T antigen is not an acute transforming gene like the polyomavirus middle T antigen but is similar to the establishment genes such as myc and adenovirus EIa.

Transfection of a rat cell line with the v-Ki-ras oncogene is associated with enhanced susceptibility to natural killer cell lysis

Transfection of the v-Ki-ras oncogene into rat-1 fibroblasts resulted in the establishment of cell lines that were transformed, tumorigenic, and sensitive to lysis by natural killer (NK) cells. Characterization of effectors indicated that the killing was not related to Lyt-1+ or Lyt-2+ cells (T cells) but was associated with cells bearing NK markers (asialo GM1, NK-1.2+, and NK-2.1+). Transfected targets were also killed by cloned NK lines. The transformation determinants on rat-1 transfectants cross-competed with YAC 1.2 lymphoma cells, suggesting a common target structure on these two diverse cell types. The results indicate that the NK surveillance system can recognize and kill cells newly transformed by a member of the ras oncogene family.

Location of sequences in polyomavirus DNA that are required for early gene expression in vivo and in vitro

To define the DNA sequences required for the expression of the polyomavirus early transcription unit, we cloned part of the viral genome in a plasmid vector, isolated mutants bearing lesions introduced in vitro within DNA sequences upstream of the transcriptional start site, and measured the capacity of these various mutant genomes to transform cells and to function as templates for transcription in vitro by comparison with wild-type DNA. One set of mutants bore 5' unidirectional deletions beginning at position -810 and extending downstream to position +4. Another set of mutants bore 3' undirectional deletions starting at position +4 and progressing upstream to position -311. The last set of mutants bore internal deletions between positions -810 and +4. Analyses of the properties of these mutant DNAs led us to conclude that the region between positions -403 and -311 includes an enhancer of gene expression. Deletion of this area from the viral genome reduced gene expression in vivo to 1 to 2% of wild-type levels, as measured by transformation assays. Moreover, this region increased the frequency of transformation of thymidine kinase-negative Rat-2 cells by the herpes simplex virus thymidine kinase (tk) gene from 5- to 20-fold. This occurred only if the polyomavirus sequences were covalently linked to the tk gene and then occurred independently of their orientation or position relative to the tk gene. A second transcriptional element is located downstream of the enhancer between positions -311 and -213. This element together with the enhancer was sufficient to bring about transformation of Rat-1 cells at nearly wild-type frequencies, and together these elements constitute the minimal sequences required for gene expression in vivo. The sequences making up the second element may be functionally duplicated downstream of position -165 (between positions -165 and -60). This was revealed by the characterization of mutant genomes with deletions between positions -349 and -60. The role of these redundant elements is not known; however, they may be analogous to the 21-base-pair repeats of simian virus 40. Finally, sequences between positions -57 and -1 were required for accurate and efficient transcription in vitro. However, this DNA stretch, which includes the TATA box and major transcriptional start sites, was not absolutely required for gene expression in vivo. We conclude that the polyomavirus promoter comprises multiple functional elements which are distributed across a DNA stretch of about 400 base pairs.

Isolation of large T antigen-producing mouse cell lines capable of supporting replication of polyomavirus-plasmid recombinants

Construction of polyomavirus vectors, analysis of mutant viruses, and rescue of integrated polyomavirus genomes would be considerably aided by the availability of transformed, permissive mouse cell lines capable of producing the viral tumor antigens. To isolate such cell lines, we constructed a hybrid transcription unit composed of the simian virus 40 early promoter fused to the coding region for the polyomavirus tumor antigens. This hybrid transcription unit was used to transform NIH 3T3 cells. Independent foci of transformed cells were isolated, recloned, and characterized. Among 10 lines initially analyzed, 7 supported the replication of origin-bearing plasmid DNAs. Three cell lines were characterized in greater detail. Each line contained one or two independent insertions of polyomavirus DNA and synthesized all three viral tumor antigens. Moreover, the large tumor antigen in two of three lines bound with specificity to sequences about the polyomavirus origin and early promoter. These cell lines should prove useful for studying not only the replication of polyomavirus but also the expression of foreign genes in a mouse cell environment.

Location of sequences in polyomavirus DNA that are required for early gene expression in vivo and in vitro

To define the DNA sequences required for the expression of the polyomavirus early transcription unit, we cloned part of the viral genome in a plasmid vector, isolated mutants bearing lesions introduced in vitro within DNA sequences upstream of the transcriptional start site, and measured the capacity of these various mutant genomes to transform cells and to function as templates for transcription in vitro by comparison with wild-type DNA. One set of mutants bore 5' unidirectional deletions beginning at position -810 and extending downstream to position +4. Another set of mutants bore 3' undirectional deletions starting at position +4 and progressing upstream to position -311. The last set of mutants bore internal deletions between positions -810 and +4. Analyses of the properties of these mutant DNAs led us to conclude that the region between positions -403 and -311 includes an enhancer of gene expression. Deletion of this area from the viral genome reduced gene expression in vivo to 1 to 2% of wild-type levels, as measured by transformation assays. Moreover, this region increased the frequency of transformation of thymidine kinase-negative Rat-2 cells by the herpes simplex virus thymidine kinase (tk) gene from 5- to 20-fold. This occurred only if the polyomavirus sequences were covalently linked to the tk gene and then occurred independently of their orientation or position relative to the tk gene. A second transcriptional element is located downstream of the enhancer between positions -311 and -213. This element together with the enhancer was sufficient to bring about transformation of Rat-1 cells at nearly wild-type frequencies, and together these elements constitute the minimal sequences required for gene expression in vivo. The sequences making up the second element may be functionally duplicated downstream of position -165 (between positions -165 and -60). This was revealed by the characterization of mutant genomes with deletions between positions -349 and -60. The role of these redundant elements is not known; however, they may be analogous to the 21-base-pair repeats of simian virus 40. Finally, sequences between positions -57 and -1 were required for accurate and efficient transcription in vitro. However, this DNA stretch, which includes the TATA box and major transcriptional start sites, was not absolutely required for gene expression in vivo. We conclude that the polyomavirus promoter comprises multiple functional elements which are distributed across a DNA stretch of about 400 base pairs.

Isolation of large T antigen-producing mouse cell lines capable of supporting replication of polyomavirus-plasmid recombinants

Construction of polyomavirus vectors, analysis of mutant viruses, and rescue of integrated polyomavirus genomes would be considerably aided by the availability of transformed, permissive mouse cell lines capable of producing the viral tumor antigens. To isolate such cell lines, we constructed a hybrid transcription unit composed of the simian virus 40 early promoter fused to the coding region for the polyomavirus tumor antigens. This hybrid transcription unit was used to transform NIH 3T3 cells. Independent foci of transformed cells were isolated, recloned, and characterized. Among 10 lines initially analyzed, 7 supported the replication of origin-bearing plasmid DNAs. Three cell lines were characterized in greater detail. Each line contained one or two independent insertions of polyomavirus DNA and synthesized all three viral tumor antigens. Moreover, the large tumor antigen in two of three lines bound with specificity to sequences about the polyomavirus origin and early promoter. These cell lines should prove useful for studying not only the replication of polyomavirus but also the expression of foreign genes in a mouse cell environment.

A plasmid vehicle suitable for the molecular cloning and characterization of mammalian promoters

We have constructed a plasmid, pPSG4, that carries only the coding sequences for polyomavirus (Py) small, middle and truncated large T-antigens. A unique HindIII site allows the introduction of foreign promoters directly in front of viral coding sequences. The simian virus 40 (SV40) early and late, adenovirus-2 (Ad-2) major late and herpes simplex virus-1 (HSV-1) thymidine kinase (TK) promoters all confer on pPSG4 the ability to transform rat embryonic fibroblasts with high efficiency. Sequential deletion of the 72 bp repeats, the 21 bp repeats and the TATA box from the SV40 early region in pPSG4 produced a 50, then 30 and then a further 5 to 10-fold decrease in transformation efficiency, respectively. Thus pPSG4 is a convenient vector for the cloning and characterization of mammalian promoters.

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.

Polyomavirus and simian virus 40 large T antigens bind to common DNA sequences

The large T antigens of polyomavirus and simian virus 40 (SV40) recognize and bind to specific, noncoding DNA sequences which are located between the beginning of the early and late transcription units in their respective genomes. Each large T antigen binds to multiple sites within this intergenic DNA stretch. Polyomavirus large T antigen binds to at least two sites within its DNA, and SV40 large T antigen binds to three sites within SV40 DNA. Comparison of the DNA sequences which comprise the binding sites in polyomavirus DNA or those which make up the binding sites in SV40 DNA has led to recognition of a common sequence, -GAGGC-, which is repeated within each large-T-antigen-binding site. We tested the hypothesis that repeats of this pentanucleotide form the recognition-binding site for polyomavirus and SV40 large T antigen. This was accomplished by measuring the binding of each large T antigen to both polyomavirus and SV40 DNA and to synthetic DNA substrates which did or did not contain repeats of the -GAGGC- sequence. Polyomavirus large T antigen bound to specific fragments of SV40 DNA, and SV40 large T antigen bound with specificity to polyomavirus DNA. In each case, the DNA fragments bound by the heterologous large T antigen were the same as those bound by the homologous large T antigen. Moreover, polyomavirus and SV40 large T antigen only bound to synthetic DNA substrates which contained repeats of the pentameric sequence. This synthetic DNA also competed effectively with native polyomavirus or SV40 DNA as a substrate in binding reactions with one or the other large T antigen. These results led us to conclude that repeats of the -GAGGC- sequence form the recognition-binding site for both polyomavirus and SV40 large T antigen.

Polyomavirus-plasmid recombinants capable of replicating have an enhanced transforming potential

The frequency of transformation of rodent fibroblasts by polyomavirus is enhanced by a viral gene product, large T-antigen. However, this effect of large T-antigen cannot be demonstrated with pBR322-cloned viral DNA. Recently, it was discovered that pBR322 contains cis-acting sequences inhibitory to DNA replication in mammalian cells. Because polyomavirus large T-antigen is required for viral DNA replication, we examined the possibility that our inability to demonstrate a requirement for large T-antigen in transformation with pBR322-cloned viral DNA was due to the failure of the chimeric DNA to replicate in the transfected cells. To this end we constructed polyomavirus recombinant molecules with a plasmid (pML-2) that lacks these "poison" sequences and measured their capacity to transform cells. Here we report that recombinant plasmids capable of replicating in the transfected cells transform these cells at frequencies approximately sixfold greater than their replication-defective counterparts.

Homologous recombination between transfected DNAs

An extensive analysis of the fate and structure of polyomavirus-plasmid recombinant molecules transfected into Rat-1 cells has revealed that the DNA often becomes integrated within transformed cell DNA in a head-to-tail tandem arrangement. This occurs independently of the replicative capacity of the transforming DNA and is facilitated by the use of large quantities of DNA during transfection. These observations have led us to suggest that head-to-tail tandems are formed by homologous recombination between transfected DNAs either before or after integration within cellular DNA. To test this hypothesis, we have measured the transforming activity of pairs of mutant, nontransforming, recombinant plasmid DNAs that carry different lesions in the transforming gene of polyomavirus. The results show that, although the individual mutant DNAs are incapable of transformation, transfection with pairs of mutant DNAs leads to the formation of transformed cells at high frequency. Moreover, there is a direct relationship between the distance between the lesions in pairs of mutant DNAs and their transforming activity. Finally, analyses of the structures of integrated recombinant plasmid DNAs and the viral proteins within independent transformed cells prove that recombination occurs between the mutant genomes to generate a wild-type transforming gene.

A frameshift mutation affecting the carboxyl terminus of the simian virus 40 large tumor antigen results in a replication- and transformation-defective virus

We have constructed a frameshift mutation in the simian virus 40 early region using a novel method of oligonucleotide-directed mutagenesis. The mutated DNA specifies an 84,000-dalton large tumor antigen that consists of approximately equal to 75,000 daltons encoded by the wild-type reading frame and 9,000 daltons, by the alternative reading frame (wild-type large tumor antigen is approximately equal to 82,000 daltons). The frameshifted carboxyl terminus of the protein bears a strong similarity to the same region of polyoma virus middle-sized tumor antigen. We have found that the mutant DNA is unable to replicate when introduced into permissive monkey cells and incapable of transforming nonpermissive mouse cells.

Role of the three polyoma virus early proteins in tumorigenesis

A modified polyoma virus genome which can encode the middle T protein but not the large or small T proteins transforms rat cells in culture with an efficiency about 20% that of the wild-type genome. Although middle T-transformed cells grow as tumors when transplanted into nude mice or syngeneic rats, the middle T gene alone is totally inactive when used in a more stringent and rigorous assay for tumorigenicity such as the injection of DNA into newborn rats. Thus, functions other than those expressed by middle T antigen are required for the elaboration of all the properties associated with tumorigenesis. To assess whether a complementary function could be exerted by the large or the small T antigen, we constructed plasmids containing two modified early regions which independently encoded middle T and one of the two other proteins. Both recombinants were tumorigenic in newborn rats. Cell lines derived by transfer of these plasmids under no special selective conditions did not acquire the property of growth in low-serum medium but exhibited the same tumorigenic properties as wild-type polyoma DNA-transformed cells. Furthermore, a recombinant which encoded the middle and small T antigens, but not the large T antigen, was tumorigenic in newborn rats. Although the small T antigen provides a complementary function for tumorigenicity, it cannot complement the middle T antigen for an efficient induction of transformation of cultured cells. This suggests that the complementary function exerted by the small T antigen is different from that of the N-terminal fragment of the large T protein.

Polyomavirus large T antigen binds independently to multiple, unique regions on the viral genome

To map the polyomavirus large T antigen binding sites on the viral genome we employed a quantitative immunoassay. Defined, radiolabeled fragments of the viral genome were reacted with crude nuclear extracts prepared from lytically infected mouse 3T6 cells, and the fragments bound by large T antigen were immunoprecipitated with anti-T serum and Formalin-fixed Staphylococcus aureus. The immunoprecipitated DNA was then analyzed by gel electrophoresis and autoradiography. By the use of a variety of restriction endonuclease-generated fragments of wild-type and mutant viral DNAs, the region of high-affinity binding was localized to a 153-base-pair stretch between nucleotides 5292 and 152. At least two independent binding sites lie within this region, one upstream and the other downstream of the Bg/I site at nucleotide 87. One of the binding sites is located within sequences required in cis for DNA replication; the other overlaps the TATA box and cap sites of the early transcription unit. The two sites share a common sequence, A/TGAGGC-N4/5-A/TGAGGC, which may serve as the recognition sequence for large T antigen.

Polyomavirus origin for DNA replication comprises multiple genetic elements

To define the minimal cis-acting sequences required for polyomavirus DNA replication (ori), we constructed a number of polyomavirus-plasmid recombinants and measured their replicative capacity after transfection of a permissive mouse cell line capable of providing polyomavirus large T antigen in trans (MOP cells). Recombinant plasmids containing a 251-base-pair fragment of noncoding viral DNA replicate efficiently in MOP cells. Mutational analyses of these viral sequences revealed that they can be physically separated into two genetic elements. One of these elements, termed the core, contains an adenine-thymine-rich area, a 32-base-pair guanine-cytosine-rich palindrome, and a large T antigen binding site, and likely includes the site from which bidirectional DNA replication initiates. The other, termed beta, is located adjacent to the core near the late region and is devoid of outstanding sequence features. Surprisingly, another sequence element named alpha, located adjacent to beta but outside the borders of the 251-base-pair fragment, can functionally substitute for beta. This sequence too contains no readily recognized sequence features and possesses no obvious homology to the beta element. The three elements together occupy a contiguous noncoding stretch of DNA no more than 345 base pairs in length in the order alpha, beta, and core. These results indicate that the polyomavirus origin for DNA replication comprises multiple genetic elements.

Homologous recombination between transfected DNAs

An extensive analysis of the fate and structure of polyomavirus-plasmid recombinant molecules transfected into Rat-1 cells has revealed that the DNA often becomes integrated within transformed cell DNA in a head-to-tail tandem arrangement. This occurs independently of the replicative capacity of the transforming DNA and is facilitated by the use of large quantities of DNA during transfection. These observations have led us to suggest that head-to-tail tandems are formed by homologous recombination between transfected DNAs either before or after integration within cellular DNA. To test this hypothesis, we have measured the transforming activity of pairs of mutant, nontransforming, recombinant plasmid DNAs that carry different lesions in the transforming gene of polyomavirus. The results show that, although the individual mutant DNAs are incapable of transformation, transfection with pairs of mutant DNAs leads to the formation of transformed cells at high frequency. Moreover, there is a direct relationship between the distance between the lesions in pairs of mutant DNAs and their transforming activity. Finally, analyses of the structures of integrated recombinant plasmid DNAs and the viral proteins within independent transformed cells prove that recombination occurs between the mutant genomes to generate a wild-type transforming gene.

Polyomavirus-plasmid recombinants capable of replicating have an enhanced transforming potential

The frequency of transformation of rodent fibroblasts by polyomavirus is enhanced by a viral gene product, large T-antigen. However, this effect of large T-antigen cannot be demonstrated with pBR322-cloned viral DNA. Recently, it was discovered that pBR322 contains cis-acting sequences inhibitory to DNA replication in mammalian cells. Because polyomavirus large T-antigen is required for viral DNA replication, we examined the possibility that our inability to demonstrate a requirement for large T-antigen in transformation with pBR322-cloned viral DNA was due to the failure of the chimeric DNA to replicate in the transfected cells. To this end we constructed polyomavirus recombinant molecules with a plasmid (pML-2) that lacks these "poison" sequences and measured their capacity to transform cells. Here we report that recombinant plasmids capable of replicating in the transfected cells transform these cells at frequencies approximately sixfold greater than their replication-defective counterparts.

Role of the three polyoma virus early proteins in tumorigenesis

A modified polyoma virus genome which can encode the middle T protein but not the large or small T proteins transforms rat cells in culture with an efficiency about 20% that of the wild-type genome. Although middle T-transformed cells grow as tumors when transplanted into nude mice or syngeneic rats, the middle T gene alone is totally inactive when used in a more stringent and rigorous assay for tumorigenicity such as the injection of DNA into newborn rats. Thus, functions other than those expressed by middle T antigen are required for the elaboration of all the properties associated with tumorigenesis. To assess whether a complementary function could be exerted by the large or the small T antigen, we constructed plasmids containing two modified early regions which independently encoded middle T and one of the two other proteins. Both recombinants were tumorigenic in newborn rats. Cell lines derived by transfer of these plasmids under no special selective conditions did not acquire the property of growth in low-serum medium but exhibited the same tumorigenic properties as wild-type polyoma DNA-transformed cells. Furthermore, a recombinant which encoded the middle and small T antigens, but not the large T antigen, was tumorigenic in newborn rats. Although the small T antigen provides a complementary function for tumorigenicity, it cannot complement the middle T antigen for an efficient induction of transformation of cultured cells. This suggests that the complementary function exerted by the small T antigen is different from that of the N-terminal fragment of the large T protein.

Expression and stabilization of microinjected plasmids containing the herpes simplex virus thymidine kinase gene and polyoma virus DNA in mouse cells

To observe the effects of polyoma virus DNA on the expression of the herpes simplex virus (HSV) thymidine kinase (TK) gene early after transfer into TK-deficient mouse cells and the subsequent development of stable TK-positive transformants, we constructed a series of recombinant plasmids containing the herpes simplex virus TK gene joined with various segments of the polyoma virus genome and microinjected them into the nuclei or cytoplasm of LTK-A cells (TK(-), APRT(-)). The frequency of nucleus-injected cells expressing TK after 1 day, measured by autoradiography of cells incubated with [(3)H]thymidine, increased approximately 30-fold when the plasmids contained the polyoma virus origin of replication. The origin includes sequences with homology to the simian virus 40 origin of replication and adjoining sequences, including a recently defined transcription-enhancing sequence. After microinjection of a single origin-containing plasmid molecule per cell, TK expression was detected in approximately 50% of the injected cells. When a larger number of origin-containing plasmid molecules were injected per cell, all cells showed early TK activity. When the entire polyoma virus early region was present, neighboring uninjected cells became TK positive. When plasmids were injected into the cell cytoplasm, approximately 400 times as many molecules per cell were needed to cause early TK activity. The frequency of stable transformation observed 2 weeks after nuclear injection of 10 to 20 polyoma virus origin-containing plasmid molecules per cell was at least 2 orders of magnitude greater than with plasmids containing the TK gene alone. The greatest enhancement of stable TK transformation was obtained with plasmids containing the origin alone, when the maximum frequency of stable transformation was 5%. The addition of the coding regions for the small and medium T antigens or the entire early region significantly decreased TK transformation frequency in a copy-dependent fashion. The timing of stabilization of TK-positive transformation was analyzed by releasing hypoxanthine-aminopterin-thymidine selection pressure at various times after microinjection, culturing the cells in nonselective medium, and assaying for TK activity. Stabilization was found to occur between 3 and 6 days after nuclear injection. Cells injected with a plasmid containing the origin and the early region were examined for expression of the large T antigen with polyoma virus antitumor serum and immunofluorescent staining. The expression of the large T antigen was clearly associated with a cytopathic effect. TK-positive clones observed 2 weeks after injection of the plasmid were uniformly T antigen negative. Cytotoxicity may be the result of plasmid replication and toxic levels of T antigen or TK. In addition, expression of the large T antigen may block stabilization by preventing the integration of origin-containing plasmid molecules.

Transformation of rodent cells by DNA extracted from transformation-defective adenovirus mutants

Complementation group II host range mutants of adenovirus type 5 which map in early region 1B (E1B, 4.5 to 11.0 map units) have been shown to be defective for the synthesis of the E1B 58,000-dalton (58K) antigen in infections of HeLa or KB cells (Lassam et al., Cell 18:781-791, 1979) and unable to transform cultured rodent cells (Graham et al., Virology 86:10-21, 1978). In this report we show that DNA extracted from group II mutants hr6 and hr50 can transform rat cells with the same efficiency as wild-type DNA. Furthermore, group II mutant-transformed hamster cells were shown to contain no detectable E1B 58K tumor antigen but were capable of inducing tumors in newborn hamsters. Hamster cell lines 1019-3 and 1019-C3, transformed by hr50 DNA, produced no detectable quantities of either the E1B 58K or 19K antigen but nonetheless exhibited a fully transformed oncogenic phenotype. Our results show that the E1B 58K antigen is not absolutely required for oncogenic transformation and suggest that even cells lacking the 19K protein can be oncogenic.

Neoplastic transformation by a cloned human cytomegalovirus DNA fragment uniquely homologous to one of the transforming regions of herpes simplex virus type 2

Specific DNA fragments of human cytomegalovirus strain Towne exhibited sequence homology to the transforming regions of herpes simplex virus type 2 (HSV-2) when examined by nitrocellulose filter hybridization under nonstringent conditions. Cloned Towne Xba I fragments B and C were homologous to both Bgl II transforming fragments N and C of HSV-2 DNA, whereas cloned Towne Xba I fragment E was uniquely homologous to HSV-2 Bgl II fragment C. Furthermore, Towne Xba I fragment E exhibited homology to a unique fragment of cytomegalovirus strain AD169 but lacked homology to the recently identified Xba I transforming (focus-forming) fragment N. Normal diploid Syrian hamster embryo cells transfected with cloned Towne Xba I fragment E displayed colonies of refractile, rapidly dividing cells which escaped senescence to form immortal cell lines. At early passages, these lines exhibited growth in 2% serum and formed small (less than 0.1 mm) colonies in 0.3% agarose. Serial passaging resulted in the appearance of large (greater than 0.25 mm) colonies in agarose, indicating the involvement of more than one step in Towne Xba I fragment E-induced transformation of the diploid hamster embryo cells. NIH 3T3 cells transfected with Towne Xba I fragment E rapidly displayed large colonies in agarose and tumors in vivo.

Expression and stabilization of microinjected plasmids containing the herpes simplex virus thymidine kinase gene and polyoma virus DNA in mouse cells

To observe the effects of polyoma virus DNA on the expression of the herpes simplex virus (HSV) thymidine kinase (TK) gene early after transfer into TK-deficient mouse cells and the subsequent development of stable TK-positive transformants, we constructed a series of recombinant plasmids containing the herpes simplex virus TK gene joined with various segments of the polyoma virus genome and microinjected them into the nuclei or cytoplasm of LTK-A cells (TK(-), APRT(-)). The frequency of nucleus-injected cells expressing TK after 1 day, measured by autoradiography of cells incubated with [(3)H]thymidine, increased approximately 30-fold when the plasmids contained the polyoma virus origin of replication. The origin includes sequences with homology to the simian virus 40 origin of replication and adjoining sequences, including a recently defined transcription-enhancing sequence. After microinjection of a single origin-containing plasmid molecule per cell, TK expression was detected in approximately 50% of the injected cells. When a larger number of origin-containing plasmid molecules were injected per cell, all cells showed early TK activity. When the entire polyoma virus early region was present, neighboring uninjected cells became TK positive. When plasmids were injected into the cell cytoplasm, approximately 400 times as many molecules per cell were needed to cause early TK activity. The frequency of stable transformation observed 2 weeks after nuclear injection of 10 to 20 polyoma virus origin-containing plasmid molecules per cell was at least 2 orders of magnitude greater than with plasmids containing the TK gene alone. The greatest enhancement of stable TK transformation was obtained with plasmids containing the origin alone, when the maximum frequency of stable transformation was 5%. The addition of the coding regions for the small and medium T antigens or the entire early region significantly decreased TK transformation frequency in a copy-dependent fashion. The timing of stabilization of TK-positive transformation was analyzed by releasing hypoxanthine-aminopterin-thymidine selection pressure at various times after microinjection, culturing the cells in nonselective medium, and assaying for TK activity. Stabilization was found to occur between 3 and 6 days after nuclear injection. Cells injected with a plasmid containing the origin and the early region were examined for expression of the large T antigen with polyoma virus antitumor serum and immunofluorescent staining. The expression of the large T antigen was clearly associated with a cytopathic effect. TK-positive clones observed 2 weeks after injection of the plasmid were uniformly T antigen negative. Cytotoxicity may be the result of plasmid replication and toxic levels of T antigen or TK. In addition, expression of the large T antigen may block stabilization by preventing the integration of origin-containing plasmid molecules.

Transformation of rat cells by cyt mutants of adenovirus type 12 and mutants of adenovirus type 5

Several mutants with much reduced oncogenicity (spontaneous mutants H12 cyt 52 and H12 cyt 70 and UV-induced mutants H12 cyt 61, H12 cyt 62, and H12 cyt 68) of the highly oncogenic adenovirus type 12 (Ad12) were studied for their ability to transform primary baby rat kidney cells. Four of the mutants showed much reduced capacity to transform cells in vitro, while H12 cyt 61 transformed cells as efficiently as the wild-type virus. Viral gene expression in several cell lines established from cultures infected by cyt mutants was studied, and it was found that viral sequences belonging to the left 16% of Ad12 were always transcribed. These results suggest that the function of the transformed state is not defective in the cyt mutants studied. Heterotypic complementation studies showed that the defect(s) in a cyt mutant can be corrected by an Ad7 function. Ad5 dl 313, with a deletion between 3.5 and 10.5 map units, transformed rat cells only at high multiplicity. These results suggest that the region E1B of adenoviruses may be required for efficient transformation of rat cells.

The roles of individual polyoma virus early proteins in oncogenic transformation

The expression in normal rat cells of modified polyoma virus genomes, separately encoding large T, middle T or small T antigens, has allowed the investigation of the roles of these proteins in oncogenic transformation. Middle T is sufficient to transform cells of established lines but the transformants are serum dependent. Large T lacks intrinsic oncogenic potential but can relieve the serum dependence of normal and transformed cells. Middle T alone cannot transform primary rat embryo fibroblasts.

Functional analysis of a simian virus 40 super T-antigen

The SV3T3 C120 line of simian virus 40-transformed mouse cells synthesizes no large T-antigen of molecular weight 94,000 but instead a super T-antigen of molecular weight 145,000. In the accompanying paper (Lovett et al., J. Virol. 44:963-973, 1982), we showed that the integrated viral DNA segment SV3T3-20-K contains a perfect, in-phase, tandem duplication of 1.212 kilobases within the large T-antigen coding sequences. Our data suggested that this integrated template encodes mRNAs of 3.9 and 3.6 kilobases, the smaller of which directs the synthesis of the super T-antigen of molecular weight 145,000. We transfected the DNA segment SV3T3-20-K into nonpermissive rat cells and into TK- mouse L cells and analyzed the T-antigens and viral mRNAs in the transfectants; these data prove directly the coding assignments suggested previously. The super T-antigen retained the ability to induce morphological transformation, and may even transform better than the wild-type protein. It also retained the ability to bind to the cell-coded p53 protein. Transfection into permissive CV-1 cells showed that the super T-antigen encoded by SV3T3-20-K was incapable of initiating DNA replication at the viral origin. The duplication in SV3T3-20-K thus defines a mutation which separates the transformation and DNA replication functions of large T-antigen. We discuss why such mutations may be selected in transformed cells.

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.

Fragments of the simian virus 40 transforming gene facilitate transformation of rat embryo cells

Segments of the simian virus 40 (SV40) genome that encode only fragments of large tumor antigen can facilitate immortalization of secondary rat embryo cells. The phenotypes of the immortalized cells range from nearly "normal" to fully transformed. All of the cell lines contain SV40 sequences and express unstable NH2-terminal fragments of large tumor antigen. SV40 small tumor antigen does not appear to be essential for either immortalization or transformation.

Use of a cellular polyadenylation signal by viral transcripts in polyoma virus transformed cells

The DNA sequences at and around the junctions between viral and cellular DNA in the polyoma virus transformed mouse cell line, TS-A-3T3, have been determined. No common sequence specificity or structural features at the joins have been observed. The sequence indicates that the 94K truncated large T antigen found in TS-A-3T3 cells is a hybrid protein in which the carboxy-terminal 19 amino acids are encoded by adjacent host sequences. Moreover, the three early region transcripts initiated in viral sequences are also hybrid in nature and appear to utilize a host polyadenylation signal associated with the hexanucleotide, AATAAA, found 100 bp beyond a viral-host join.

Construction and characterization of viable deletion mutants of simian virus 40 lacking sequences near the 3' end of the early region

Five viable deletion mutants of simian virus 40 (SV40) were prepared and characterized. These mutants lack 15 to 60 base pairs between map positions 0.198 and 0.218, near the 3' end of the early region of SV40 and extend further into the body of the A gene, encoding the large T antigen, than previously described deletion mutants. These mutants were isolated after transfection of monkey kidney CV-1p cells with full-sized linear DNA prepared by partial digestion of form I SV40 DNA with restriction endonucleases HinfI or MboII, followed by removal of approximately 25 base pairs of DNA from the 5' termini using lambda-5'-exonuclease and purification of the DNA in agarose gels. Based on camparisons of the DNA sequence of SV40 and polyoma virus, these mutations map in the 19% of the SV40 A gene that shares no homology with the A gene of polyoma virus. The mutations exist in two different genetic backgrounds: the original set of mutants (dl2401 through dl2405) was prepared, using as a parent SV40 mutant dl862, which has a deletion at the single HpaII site (0.725 map unit). A second set (dl2491 through dl2495) contains the same deletions in a wild-type SV40 (strain SV-S) background. Relative to wild-type SV40, the original mutants showed reduced rates of growth, lower yields of progeny virus and viral DNA, and smaller plaque size; in these properties the mutants resembled parental dl862, although mutant progeny yields were usually lower than yields of dl862, suggesting a possible interaction between the two deletions. The second set of mutants had growth properties and progeny yields similar to those of wild-type SV40; however, Southern blotting experiments indicated that viral DNA replication proceeds at a slightly reduced rate. All of the mutants transformed mouse NIH/3T3 cells and mouse embryo fibroblasts at the same frequency as wild-type SV40. Mutants dl2402, dl2492, and dl2405 consistently produced denser and larger foci in both types of cells. All mutants directed the synthesis of shortened large T antigens. Adenovirus helper function was retained by all mutants.

Carboxy terminus of polyoma middle-sized tumor antigen is required for attachment to membranes, associated protein kinase activities, and cell transformation

We have constructed a transformation-defective polyoma virus mutant (Py 1387-T) that directs the synthesis of a normal small tumor antigen, a functional large tumor antigen, and a truncated (51,000-dalton) middle-sized tumor (mT) antigen that lacks 37 amino acids at its COOH terminus. The shortened mT polypeptide is missing the hydrophobic "tail" thought to be responsible for the anchorage of this protein into the plasma membrane and is in fact in cytosol fractions. This truncated mT polypeptide is inactive in an in vitro protein kinase assay and is altered in its phosphorylation in vivo. Mutant 1387-T differs from wild-type virus in having a T.A base pair instead of a C.G base at nucleotide position 1387. This change was introduced into viral DNA by using a synthetic undecanucleotide as a specific mutagen. Wild-type polyoma DNA was rendered single stranded by molecular cloning into coliphage M13. The oligonucleotide, which hybridizes with a mismatch at the site to be altered, was used to prime the synthesis of double-stranded closed circular DNA. Progeny recombinant phage were screened by DNA sequence analysis for the desired base change. The polyoma mutant was reconstructed from recombinant phage replicative form DNA molecules containing the mutation.

Polyoma viral middle T-antigen is required for transformation

To determine whether small or middle T-antigen (or both) of polyoma virus is required for transformation, we constructed mutants of recombinant plasmids which bear the viral oncogene and measured the capacity of these mutants to transform rat cells in culture. Insertion and deletion mutations in sequences encoding small and middle T-antigens (79.7, 81.3, and 82.9 map units) rendered the DNA incapable of causing transformation by the focus assay. Similar mutations in sequences that encoded middle but not small T-antigen (89.7, 92.1, and 96.5 map units) generally abolished the transforming activity of the DNA. However, two mutants (pPdl1-4 and PPd12-7) that carried deletions at 92.1 map units retained the capacity to transform cells; pPdl1-4 did so at frequencies equal to those of the parental plasmid, whereas pPdl2-7 transformed at 10% the frequency of its antecedent. From these studies we conclude that small T-antigen alone is insufficient to cause transformation and that middle T-antigen is required for transformation, either in combination with small T-antigen or by itself.

Mutation causing premature termination of the polyoma virus medium T antigen blocks cell transformation

We used site-specific mutagenesis to introduce a termination codon, TGA, into the reading frame for the polyoma virus medium T antigen. We induced this mutation in a region of the polyoma genome in which the overlapping coding regions for the large and medium TE antigens are translated in different reading frames. Therefore, the mutation terminated translation of the medium T antigen, but it caused only a single amino acid substitution in the large T antigen and did not affect the small T antigen. Cells infected by the mutant virus produced normal-size small and large T antigens. The infected cells produced a 28,000-dalton fragment of the 48,000-dalton medium T antigen, whose size and tryptic peptide map were consistent with its being a truncated N-terminal fragment terminating at the new termination codon of the mutant. Immunoprecipitates of mutant-infected cell extracts did not show medium-T-antigen-associated protein kinase activity. The mutant virus replicated normally in mouse 3T6 cells and induced cellular DNA synthesis in resting mouse 3T3 cells, but it failed to transform rat or hamster cells, as judged by focus formation and growth in agar. The mutant complemented a tsA mutant which affects the large T antigen for transformation, implying that the mutant defect for transformation was in the medium T antigen. These results imply that the small T antigen and the large T antigen together are insufficient to cause transformation and support the conclusion that the medium T antigen is essential for cell transformation by polyoma virus.

Transforming genes and gene products of polyoma and SV40

The small DNA-containing viruses, SV40 and polyoma, transform cells in vitro and induce tumors in vivo. For both viruses two genes required for transformation have been found. The genes required for transformation are also involved in productive infection. Although the two viruses are similar in their effects on cells, the organization of the transforming genes and gene products is different. The purpose of this review is to compare what is known about the biology and the biochemistry of the early regions of the two viruses. The genetic and biochemical studies defining the sequences important for transformation will be reviewed. Then, the products of the transforming genes, called T antigens, will be discussed in detail. There is a substantial body of descriptive information on those products, and studies on the function of the T antigens have also begun.

Transformation of hamster kidney cells by fragments of BK virus DNA

Hamster kidney cells were transformed, with comparable efficiency, by circular or linear molecules of complete BK virus (BKV) genome and by agarose gel-purified fragments of BKV DNA obtained by single or double digestions with various restriction endonucleases. Only fragments containing the complete early region of BKV DNA displayed transforming activity. Analysis by blot hybridization of the arrangement of viral DNA sequences in a cloned cell line transformed by a 3.8-kilobase fragment, obtained after sequential digestion of BKV DNA with HhaI and BamHI, showed the presence of seven viral integrations into the cellular DNA. Apparently all of the integrated viral molecules contained the entire early region of BKV DNA. Large T antigen, small t antigen, and the 56,000-dalton nonviral Tau antigen were detected in transformed cells by immunoprecipitation. The pattern of integration of viral sequences in transformed cells was constant over many generations. Likewise, large T antigen was always detected in transformed cells at various passage levels. These results may suggest that all of the sequences of the early region coding for large T antigen are required for transformation by BKV. Alternatively, subgenomic segments of the BKV DNA early region may be unable to transform because the appropriate polyadenylation site, necessary to obtain a complete functional transcriptional unit, is removed by the restriction enzyme cleavage.

Viral gene expression in polyoma virus-transformed rat cells and their cured revertants

We have studied transcription of integrated viral DNA sequences in a variety of ts-a polyoma virus-transformed rat cells and cured revertants (which had undergone excision of variables amounts of integrated viral DNA) to characterize the structure of viral mRNA's produced in these lines under conditions in which integrated DNA is stable. Our results indicate that cells containing intact early region sequences, either in single-copy or tandem insertions, produce mRNA's indistinguishable from those observed early in lytic infections; sequences complementary to the polyoma late region were not transcribed from integrated viral DNA. Cured revertants no longer encoded full-length early mRNA's , but produced viral transcripts whose 3' ends mapped at an alternative early region polyadenylic acid attachment site at 99 map units or extended in to flanking host sequences. The phenotype of these revertant cells correlated with the abundance of these transcripts, suggesting that the transforming function(s) of polyoma virus controls the cellular phenotype in a dose-dependent manner. Unexpected results were obtained from studies of cells containing tandem repeats of defective viral DNA in which the polyadenylic acid attachment signal at 25.8 map units and surrounding sequences were deleted. In these cases, polyadenylated mRNA's were observed that contained sequences complementary to the early strand of the polyoma late region. These mRNA's (some larger than 8 kilobases) originated at the viral early promoter, extended into the late region, and continued into the early region of the contiguous repeat in the tandem. The multimeric mRNA's produced contained defective early regions in tandem with late region sequences. S1 analysis indicated that whereas the 5' early region sequences of readthrough transcripts were spliced in the usual manner, internal early region repeats were either unspliced or used only one of the small early region splices. When deletions in the viral readthrough transcripts were observed. This suggests that sequences nearby the AAUAAA sequence at 26 map units may control transcription termination of the polyoma early region.

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.