Nonlytic simian virus 40-specific 100K phosphoprotein is associated with anchorage-independent growth in simian virus 40-transformed and revertant mouse cell lines

Homologous SV40 RNA trans-splicing: a new mechanism for diversification of viral sequences and phenotypes

Simian Virus 40 (SV40) is a polyomavirus found in both monkeys and humans, which causes cancer in some animal models. In humans, SV40 has been reported to be associated with cancers but causality has not been proven yet. The transforming activity of SV40 is mainly due to its 94-kD large T antigen, which binds to the retinoblastoma (pRb) and p53 tumor suppressor proteins, and thereby perturbs their functions. Here we describe a 100 kD super T antigen harboring a duplication of the pRB binding domain that was associated with unusual high cell transformation activity and that was generated by a novel mechanism involving homologous RNA trans-splicing of SV40 early transcripts in transformed rodent cells. Enhanced trans-splice activity was observed in clones carrying a single point mutation in the large T antigen 5' donor splice site (ss). This mutation impaired cis-splicing in favor of an alternative trans-splice reaction via a cryptic 5'ss within a second cis-spliced SV40 pre-mRNA molecule and enabled detectable gene expression. Next to the cryptic 5'ss we identified additional trans-splice helper functions, including putative dimerization domains and a splice enhancer sequence. Our findings suggest RNA trans-splicing as a SV40-intrinsic mechanism that supports the diversification of viral RNA and phenotypes.

Identification and biochemical analysis of DNA replication-defective large T antigens from SV40-transformed cells

Nine commonly studied Simian virus 40 (SV40)-transformed rodent cell lines were screened for tumor (T) antigens defective in SV40 DNA replication using a simple polyethylene glycol-mediated cell fusion assay. Each line contained a functional origin of SV40 DNA replication, as shown by fusion with Cos 1 cells. Fusion with uninfected monkey cells revealed that T antigens from two lines lacked detectable replicative activity, while T antigens from five other lines exhibited only very weak replicative activity. One line, and a tumor cell line derived from it, expressed T antigen with wild-type replication activity. Biochemical analysis of these proteins revealed defects in DNA binding activity and ATPase activity. One line expressed large T antigen defective in both activities. All of the lines contained complexes of T antigen with the cellular protein p53 and all of the T antigens exhibited nucleotide-binding activity. The results indicate that some of these lines may constitute a useful source of new replication-defective T antigens.

Genetic and biochemical analysis of transformation-competent, replication-defective simian virus 40 large T antigen mutants

To study the role of the biochemical and physiological activities of simian virus 40 (SV40) large T antigen in the lytic and transformation processes, we have analyzed DNA replication-defective, transformation-competent T-antigen mutants. Here we describe two such mutants, C8/SV40 and T22/SV40, and also summarize the properties of all of the mutants in this collection. C8/SV40 and T22/SV40 were isolated from C8 and T22 cells (simian cell lines transformed with UV-irradiated SV40). Early regions encoding the defective T antigens were cloned into a plasmid vector to generate pC8 and pT22. The mutations responsible for the defects in viral DNA replication were localized by marker rescue, and subsequent DNA sequencing revealed missense and one nonsense mutation. The T22 mutation predicts a change of histidine to glutamine at residue 203. C8 has two mutations, one predicts lysine224 to glutamamic acid and the other changes the codon for glutamic acid660 to a stop codon; therefore, C8 T antigen lacks the 49 carboxy-terminal amino acids. pC8A and pC8B were constructed to contain the C8 mutations separately. Plasmids pT22, pC8, pC8A, and pC8B were able to transform primary rodent cell cultures. T22 T antigen is defective in binding to the SV40 origin. C8B (49-amino-acid truncation) is a host-range mutant defective in a late function in CV-1 but not BSC cells. Analysis of T antigens in mutant SV40-transformed mouse cells suggests that the replicative function of T antigen is important in generating SV40 DNA rearrangements that allow the expression of "100K" variant T antigens in the transformants.

DNase I sensitivity of integrated simian virus 40 DNA

We undertook an analysis of integrated simian virus 40 (SV40) DNA to learn whether the DNase I-sensitive region is retained in the integrated array of mouse transformants. Our results indicate that full-length integrated SV40 chromatin retains a DNase I-hypersensitive region at the same point as in nonintegrated SV40 chromatin. Thus, the lack of a DNase I-hypersensitive region is not likely to be the reason for nonpermissivity of SV40 in mouse cells. In addition, results reported here indicate that a deletion of about 200 base pairs of DNA in the region of the DNase I-hypersensitive site severely reduces the sensitivity of integrated SV40 chromatin. This result is similar to a previously reported result obtained with deletion mutants of SV40 analyzed in the lytic cycle. It is the first report of a DNA lesion affecting DNase I hypersensitivity of a mammalian chromosome.

A functional simian virus 40 origin of replication is required for the generation of a super T antigen with a molecular weight of 100,000 in transformed mouse cells

We used two recombinant plasmids, one containing wild-type simian virus 40 DNA (pSVR1) and the other containing a simian virus 40 genome with a defective origin of replication (pSVR1-origin-minus) to transfect NIH3T3 cells. Quantitation of T-antigen synthesis by indirect immunofluorescence at 48 h after transfection with either DNA revealed the same percentage of T-positive nuclei. The transformation frequencies observed were also similar with both plasmids. Immunoprecipitation of [35S]methionine-labeled cell extracts showed the expected 94,000-dalton (94K) T and 17K t antigens in all clones examined. In pSVR1-generated transformants, a 100K super T antigen was also detected. Transformants isolated from pSVR1-origin-minus transfection, however, never expressed this 100K super T antigen, and some of these clones originally also showed greatly reduced levels of 94K T antigen. However, after growth in culture for several generations, the levels of 94K T antigen synthesis in these underproducer clones were dramatically increased. A direct correlation between the amounts of T antigen synthesized and the ability to grow independently of anchorage was observed. The mechanism which brings about increasing levels of T-antigen synthesis in some of the clones is not clear, but it appears not to be due to changes in either the copy number or the methylation pattern of the integrated simian virus 40 DNA.

94,000- and 100,000-molecular-weight simian virus 40 T-antigens are associated with the nuclear matrix in transformed and revertant mouse cells

A small fraction of the 94,000-molecular-weight multifunctional large T-antigen of simian virus 40 was associated with the nuclear protein matrix derived from simian virus 40-transformed mouse cells. The interaction between this fraction of T-antigen and the matrix was largely or entirely independent of nuclear DNA. Similar amounts of T-antigen were retained by the nuclei of transformed and revertant cell lines. A 100,000-molecular-weight variant of T-antigen, which has been found to correlate specifically with anchorage-independent growth, was present in the nuclear protein matrix of a transformed cell line. A T-antigen-containing revertant selected for the reacquisition of a high serum requirement and an anchorage requirement for growth retained T-antigen in association with its matrix.

Integration, loss, and reacquisition of defective viral DNA in SV40-transformed mouse cell lines

We have examined the state of viral DNA in a set of SV40-transformed mouse cell lines. Using restriction enzymes which cut SV40 DNA in one place, we demonstrate that anchorage-independent SV40-transformed mouse cells commonly contain one or more detectable defective monomers of integrated viral DNA. The defective viral DNA in one of these cell lines, SV101, was extensively mapped using single and double enzyme digests. The results of this analysis indicate that SV101 contains nondefective viral DNA as well as defective viral DNA of the following sizes: 5.0, 4.3, 3.7, 3.4, and 1.5 kb. Three of these defective monomers (4.3, 3.7, and 1.5 kb) preserve the amino terminal exon of large T antigen, and two monomers (4.3, and 3.7 kb) preserve the little t coding region. Anchorage-dependent subclones of SV101 preferentially lose the defective viral DNA, while retaining an intact SV40 early region and the ability to express lytic-sized large and small T antigens. Despite a considerable amount of viral DNA rearrangement which accompanies subcloning, anchorage-independent subclones of SV101 retain defective viral DNA, especially the 4.3- and 3.7-kb monomers. Also, when an anchorage-independent subclone is selected from an anchorage-dependent revertant of SV101, it reacquires defective viral DNA, although of a size not seen in SV101. We conclude that defective viral DNA plays a role in generating the anchorage-independent phenotype. In earlier studies, we have reported that anchorage-transformed mouse lines contain a variant (100kDa) T antigen. The possible role of defective viral DNA in generating this T antigen is discussed.