Amplification and excision of integrated polyoma DNA sequences require a functional origin of replication

Does a new polyomavirus contribute to Merkel cell carcinoma?

A new polyomavirus has been discovered in Merkel cell carcinomas, but does it contribute to carcinogenesis?

A new technique designed to hunt for non-human transcripts has identified a novel SV40-like virus present in the majority of Merkel cell carcinomas. Here we examine what it will take to determine whether or not this virus contributes to carcinogenesis.

Polyomavirus large T antigen mutants affected in viral DNA replication

We have characterized two polyomavirus large T antigen mutants with different properties in viral DNA replication. dl-97, a mutant active in immortalization, exerts a dominant negative effect in viral DNA replication. 13val, which is defective in both immortalization and viral DNA replication, has a lesion in the putative DnaJ domain affecting the block of Rb function.

Site-specific in situ amplification of the integrated polyomavirus genome: a case for a context-specific over-replication model of gene amplification

The fate of the genome of the polyoma (Py) tumor virus following integration in the chromosomes of transformed rat FR3T3 cells was re-examined. The viral sequences were integrated at a single transformant-specific chromosomal site in each of 22 transformants tested. In situ amplification of the viral sequences was observed in 24 of 34 transformants analyzed. Large T antigen, the unique viral function involved in initiating DNA replication from the viral origin, was essential for the amplification process. There was an absolute requirement for a reiteration of viral sequences and the extent of the reiteration affected the degree of amplification. The reiteration may be important for homologous recombination-mediated resolution of in situ amplified sequences. Among 11 transformants harboring a 1 to 2 kb repeat, the degree of amplification was transformant-specific and varied over a wide range. At the high end of the spectrum, the genome copy number increased 1300-fold at steady state, while at the low end, amplification was below twofold. Some aspect of the host chromatin at the site integration that affected viral gene expression, also directly or indirectly modulated the amplification. Use of high-resolution electrophoresis for the analysis of the integrated amplified sequences revealed a recurring novel pattern, consisting of a ladder with numerous bands separated by a constant distance approximately the size of the Py genome. We suggest that this pattern was generated by conversion of the amplified viral genomes to head to tail linear arrays with cell to cell variations in the number of genome repeats at single, transformant-specific, chromosomal sites. In light of the known "out of schedule" firing of the Py origin, we propose an "onion skin" structure intermediate and present a homologous recombination model for the conversion from onion skins to linear arrays. The relevance of the in situ amplification of the Py genome to cellular gene amplification is discussed. Finally, these results clarify our understanding of the integration of the Py genome in rat cells. They suggest that, in most cases, the multiple bands previously described in Py-transformants are likely to reflect genome amplification rather than multiple independent integration events, as assumed in the past. This interpretation is congruent with the accepted view that the integration of the Py genome is a rare and rate-limiting event in transformation.

Elements of the polyomavirus replication origin required for homologous recombination mediated by large T antigen

We introduced various elements of the polyomavirus origin of DNA replication into the genome of rat cells, and we analyzed their capacity to elicit rearrangements within the integrated sequences when exposed to large T antigen. The cis-acting sequences required for homologous recombination were those that make up a functional replication origin.

Amplification of a circular episome carrying an inverted repeat of the DFR1 locus and adjacent autonomously replicating sequence element of Saccharomyces cerevisiae

Lack of suitable amplification markers has hindered the use of the yeast system for investigating the mechanism of gene amplification in a eukaryote with a simple genome and well defined genetic system. Recently, methotrexate has been used to select for Saccharomyces cerevisiae mutants with de novo amplification of the dihydrofolate reductase gene (DFR1) (Huang, T. (1993) In Vivo Disruption and de Novo Amplification of the DFR1 Gene Encoding Dihydrofolate Reductase in Saccharomyces cerevisiae. Ph. D. thesis, University of Alberta, Edmonton, Canada). We report here the detailed structure of a DFR1 episome amplified in methotrexate-resistant strain 25-1. The extrachromosomal DNA is found predominantly as a single 11-kilobase circular molecule. It consists of a 5.5-kilobase inverted duplication that contains the DFR1 locus and adjacent ARS (autonomously replicating sequence) element. This molecular configuration mimics the inferred structure of double minute chromosomes observed in a number of mammalian amplification systems and suggests that mechanisms that generate amplified DNAs are conserved from yeast to mammals.

Intrachromosomal recombination mediated by the polyomavirus large T antigen

We used a spleen necrosis virus-based retroviral vector to introduce the polyomavirus replication origin into rat cells and developed a system to analyze homologous recombination events that do not reconstitute a selectable marker. Introduction of the gene coding for the polyomavirus large T antigen into the cell lines by DNA transfection promoted high-frequency recombination between the two retroviral LTRs, leading to amplification and excision of DNA sequences. To analyze homology requirements, we constructed cell lines carrying only the replication origin without exogenous repeats. Most of the cell lines sustained high-frequency recombination, presumably by undergoing homologous recombination between repetitive DNA lying in the vicinity of the integrated origin. Our results indicate that homologous recombination promoted by large T antigen does not require recombination hot spots in the viral genome other than the replication origin and they explain the cytotoxicity observed in some cell types when large T antigen is expressed in the presence of a functional origin.

Amplification mediated by polyomavirus large T antigen defective in replication

The polyomavirus large T antigen promotes homologous recombination at high rates when expressed in rat cells carrying the viral replication origin and two repeats of viral DNA sequences stably integrated into the cellular genome. Recombination consists of both reciprocal and nonreciprocal events and is promoted by mutants defective in the initiation of viral DNA synthesis (L. St-Onge, L. Bouchard, and M. Bastin, J. Virol. 67:1788-1795, 1993). We have extended our studies to a rat cell line undergoing amplification of the viral insert. We show that large T antigen promotes amplification independently of its replicative function but that its origin-specific DNA binding activity is not sufficient to promote homologous recombination.

High-frequency recombination mediated by polyomavirus large T antigen defective in replication

We investigated the mechanism by which the large T antigen (T-Ag) of both polyomavirus and simian virus 40 (SV40) promotes homologous recombination in mammalian cells. To this end, we constructed a rat cell line, designated Hy5, that carries two mutated copies of the polyomavirus middle-T-Ag (pmt) oncogene lying as direct repeats on the same chromosome. The structure of the viral insert was devised so that intrachromosomal recombination between the pmt repeats reconstitutes wild-type pmt and yields cell populations amenable to selection for the transformed phenotype. Correction of pmt by gene conversion occurred spontaneously at a rate of ca. 1.7 x 10(-7) per cell generation and was masked by another recombination event that also led to the transformation of the Hy5 cell line. This event was identified as chromosomal inversion and overexpression of the upstream pmt copy as a result of homologous recombination between adjacent pBR322 sequences. Both events were promoted by the polyomavirus large T-Ag by several orders of magnitude, as well as by mutants defective in the initiation of viral DNA synthesis. Large T-Ag also promoted reconstitution of wild-type pmt by unequal exchange between sister chromatids, yielding structures compatible with some of the chromosomal aberrations commonly observed in transformed cells. Our data indicate that large T-Ag has a recombination-promoting activity that can be dissociated from its replicative function.

Amplification of polyomavirus DNA sequences stably integrated in rat cells

To investigate the mechanism by which the polyomavirus large T antigen (T-Ag) promotes amplification of integrated viral sequences, we constructed a rat cell line, Hy2-ts5, carrying two different inserts of polyomavirus DNA. The first insert, designated the middle T (pmt) locus, was devised to analyze homologous recombination between two defective copies of pmt lying 3.3 kb apart on the same chromosome. Reconstitution of a functional pmt by spontaneous recombination occurred at a rate of about 2 x 10(-7) per cell generation. The second locus contained the polyomavirus large T (plt) gene carrying a temperature-sensitive mutation and producing a nonfunctional large T-Ag at 39 degrees C. A shift to the permissive temperature for as little as 24 h induced the production of a functional large T-Ag which, in turn, promoted homologous recombination in the pmt locus at a rate close to 1.0 per cell generation. The particularity of this system is that it allowed recombination products to be analyzed as early as a single cell doubling following the initial recombinational event. Amplification occurred by successive duplications of a discrete sequence in the viral insert. Unequal sister chromatid exchange was ruled out as the recombination mechanism promoted by large T-Ag. Instead, we proposed a model of nonconservative recombination involving mispairing between homologous sequences.

Recombination resulting in unusual features in the polyomavirus genome isolated from a murine tumor cell line

Polyomavirus-induced tumor formation in the adult natural mouse host has been investigated. Tumors were produced in nude mice with the transformation-defective mutant strain NG18 after a long latency period by apparent activation of a cryptic endogenous transforming viral function. A tumor cell line, designated ScB, was established and characterized. Cells from this morphologically distinct line were unusual in that they grew in soft agar but did not form foci. They were highly tumorigenic. They had a 3.1-kilobase major viral transcript that hybridized to probes derived from regions encoding both the T antigens and the structural proteins. ScB cells expressed polyomavirus small T antigen, a slightly altered middle T antigen, and a truncated large T antigen but no capsid proteins. Middle T antigen preserved its interactions with host proteins of 60 and 37 kilodaltons and with c-src. Analysis of cDNA and genomic clones indicated that the stable viral insert in the ScB genome contained multiple copies of the viral B-enhancer. The genome contained two intragenic inversions which created novel early- to late-strand switches. A simple model for the generation of one inversion is proposed that involves the juxtaposition of two stem-loop structures at an illegitimate recombination site; the location of the inverted segment within the integrated sequence permits use of the viral late polyadenylation signal in early-region transcripts, as confirmed by DNA sequence. A repetitive sequence may facilitate recombination at the other inversion site. Both the biological consequences of the observed rearrangements and the structure of the integrated viral DNA suggest that the recombination events are nonrandom.

Intrachromosomal recombination mediated by papovavirus large T antigens

To investigate the mechanism by which the large T antigen (T-Ag) of polyomavirus and simian virus 40 can promote recombination in mammalian cells, we analyzed homologous recombination events occurring between two defective copies of the polyomavirus middle T (pmt) oncogene lying in close proximity on the same chromosome in a rat cell line. Reconstitution of a functional pmt gene by spontaneous recombination occurred at a rate of about 2 x 10(-7) per cell generation. Introduction of the polyomavirus large T (plt) oncogene into the cell line by DNA transfection promoted recombination very efficiently, with rates in the range of 10(-1) to 10(-2) per cell generation. Recombination was independent of any amplification of viral sequences and could even be promoted by the large T-Ag from simian virus 40, which cannot activate polyomavirus DNA replication. To explain the role of large T-Ag, we propose a novel mechanism of nonconservative recombination involving slipped-strand mispairing between the two viral repeats followed by gap repair synthesis.

Preferred crossover sites on polyomavirus DNA

RmI is a hybrid replicon consisting of polyomavirus (Py) and mouse sequences that yields unit-length polyomavirus DNA via recombination between two directly repeated viral sequences of 182 base pairs (S repeats). To define the contribution of the S repeats in this intramolecular recombination, we derived from RmI a series of replicons containing the original S repeats as well as additional direct viral repeats which were 1 to 2 kilobases in length (L repeats). After mouse 3T6 cells were transfected with these constructs, recombination products that displayed the physical properties of homologous recombinants were detected. The structures of these recombinants indicated that whereas repeat length influences the likelihood of recombination, crossover occurs preferentially near the S repeats, provided that one of them is proximal to the viral origin of replication. This finding suggests that recombination near the S repeats depends on a process initiated near the viral origin of replication.

Chimerasome-mediated gene transfer in vitro and in vivo

Proteoliposome delivery vesicles can be prepared by the protein-cochleate method [Gould-Fogerite and Mannino, Anal. Biochem. 148 (1985) 15-25; Mannino and Gould-Fogerite, Biotechniques 6 (1988) 682-690]. Proteins which mediate the entry of enveloped viruses into cells are integrated in the lipid bilayer, and materials are encapsulated at high efficiency within the aqueous interior of these vesicles. We describe proteoliposome-mediated delivery of proteins and drugs into entire populations of cells in culture. Material can be delivered gradually by Sendai-virus-glycoprotein-containing proteoliposomes. Alternatively, synchronous delivery to a population can be achieved by exposing cell-bound influenza glycoprotein vesicles briefly to low pH buffer. When DNA is encapsulated, chimeric proteoliposome gene-transfer vesicles (chimerasomes), which mediate high-efficiency gene transfer in vitro and in vivo, are produced. Stable expression of a bovine papilloma virus-based plasmid in tissue-cultured cells, at 100,000 times greater efficiency than Ca.phosphate precipitation of DNA, with respect to the quantity of DNA used, has been achieved. Stable gene transfer and expression in mice has been obtained by subcutaneous injection of chimerasomes containing a plasmid expressing the early region of polyoma virus. In one experimental group, 50% of the mice developed tumors which were shown to express polyoma virus early proteins and contain the transferred DNA. This is the first report of stable gene transfer in animals mediated by a liposome- or proteoliposome-based system.

Cis-acting sequences from mouse rDNA promote plasmid DNA amplification and persistence in mouse cells: implication of HMG-I in their function

Searching for amplification promoting sequences within the murine rDNA cistrons, we isolated two elements from the nontranscribed spacer region. These 370 bp and 423 bp long cis-acting elements, referred to as muNTS1 and muNTS2, are localized 4.1 kb and 4.6 kb upstream the RNA polymerase I transcriptional start site. They contain ca. 50 bp long AT-rich sequences that strongly interact with a protein from nuclear extracts. The protein could be purified and identified as HMG-I. A synthetic oligonucleotide encompassing the AT-rich stretch from muNTS1 is able to substitute for the muNTS elements. A similar sequence from the nontranscribed spacer of rat has previously been reported to be important for the function of the RNA polymerase I enhancer (1). Therefore the interaction of HMG I with the muNTS elements may play a role both in the stimulation of DNA amplification and transcription.

Construction of an EBNA-producing line of well-differentiated human hepatoma cells and of appropriate Epstein-Barr virus-based shuttle vectors

Using cloned Epstein-Barr nuclear antigen 1 (EBNA) and oriP elements from the Epstein-Barr virus (EBV) in conjunction with liver-specific growth media, we have constructed an EBNA-producing line of well-differentiated human hepatoma cells (Hep-EBNA-2) and appropriate EBV-oriP vectors. These vectors, pBEDC1 and pBEUG1, were maintained as free extrachromosomal elements only in cells that expressed the trans-acting EBNA protein. They were readily rescued from transfected Hep-EBNA-2 cells upon transformation of recA- Escherichia coli with cellular low-Mr DNA. They are true shuttle vectors in that they can propagate as free closed circular elements in both human Hep-EBNA-2 cells and E. coli. Finally, we have demonstrated the vector capability of our shuttle system by inserting into the SV40 expression cassette of pBEUG1 a large full-length cDNA encoding coagulation factor VIII. Our data clearly show that EBV-oriP episomes are able to stably propagate in an hepatic background and that neither high levels of EBNA protein nor multiple copy episomes significantly interfere with the expression of the set of hepatic functions that have been analyzed. These results are discussed in terms of gene amplification and cloning of genes that program liver differentiation.

Distinct mouse DNA sequences enable establishment and persistence of plasmid DNA polymers in mouse cells

Distinct elements isolated from mouse genomic DNA confer on plasmid DNA the ability to persist at high copy numbers in mouse L fibroblasts (1). Field inversion gel electrophoresis demonstrated that - in contrast to our previous assumption - the persisting plasmid DNA does not exist extrachromosomally but as clusters of tandem repeats integrated into genomic DNA. Digestion with restriction endonucleases that do not cut within the plasmid DNA results in fragments of 50-300 kb in length indicating reiteration of 10-50 plasmid DNA molecules. Restriction with several enzymes that cut once or twice within the plasmid sequences lead to fragment(s) indicative for head-to-tail tandem repeats. In situ hybridization revealed signals for a long homogeneously staining region (HSR) in one or two chromosomes per cell nucleus. Possibilities how these elements could act in the establishment and/or maintenance of the head-to-tail polymers of plasmid DNA in mouse cells are discussed.

Expression and amplification in transgenic mice of a polyoma virus mutant regulatory region

Two hybrid gene constructs consisting of wild-type and mutant polyoma regulatory regions fused to a bacterial reporter gene were inserted in the mouse germline. Both transgenes were expressed in a large number of different organs. However, marker gene expression controlled by the polyoma wild-type regulatory region was not detectable in the early embryo and remained low throughout the life of the animal while expression controlled by the polyoma F9-1 mutation was detectable in blastocysts and was significantly higher at later stages of development. The F9-1 hybrid gene was also amplifiable when large T-antigen was supplied in trans to mice or to kidney cells derived from these transgenic mice. Amplification resulted in the appearance of several hundred copies of episomal transgenes and a marked increase of marker gene RNA and protein. Our results suggest that the F9-1 mutation does not alter the target spectrum of gene expression in vivo but does create a more efficient enhancer element in the polyoma early control region. Transgene amplification based upon use of the polyoma regulatory elements may be a means of increasing expression of genes in transgenic mice.

Multiple insertions and tandem repeats of origin-minus simian virus 40 DNA in transformed rat and mouse cells

Stable simian virus 40 (SV40) transformation requires integration and expression of the early region of the SV40 genome. We have examined the amount and state of integrated viral DNA of SV40-transformed NIH 3T3 mouse and F2408 rat fibroblast lines generated by transfection with either wild-type or origin-defective SV40 DNA. A functional SV40 replication origin was not required for multiple inserts and partial-repeat structures to form in NIH 3T3 mouse transformants. In contrast, partial repeats in F2408 rat transformants were rare when the SV40 replication origin was intact and not detected at all when it was defective.

A reiterated leader sequence is present in polyomavirus late transcripts produced by a transformed rat cell line

In cells transformed by polyomavirus, the viral genome is integrated into the host DNA, and in the absence of excision, viral gene expression is limited to the early region. We report here that the ability of a unique transformed rat cell line, designated SS1A, to produce readily detectable levels of late mRNAs is due to rearrangements of the integrated viral sequences. The structure of the SS1A insertion, resulting from amplification and deletion events, allows for the formation of a primary late transcript that can subsequently be spliced to generate a reiterated leader attached to the body of the late mRNA coding sequences. The presence of transcripts containing such a leader was confirmed by sequencing the 5' end of cDNA copies of late mRNAs isolated from a library constructed with SS1A mRNA. These results suggest that a reiterated leader sequence is necessary to stabilize late mRNA.

Isolation of a rearranged human transforming gene following transfection of Kaposi sarcoma DNA

By transfecting high molecular weight DNA from a Kaposi sarcoma lesion into murine NIH 3T3 cells, we have identified and molecularly cloned a set of human DNA sequences capable of inducing focus formation, growth in agar, and tumorigenicity in these cells. The human DNA sequences present in primary, secondary, and tertiary NIH 3T3 transformants encompass about 32 kilobases (kb) and contain four rearrangements with respect to normal human DNA and a portion of the c-fms protooncogene (FMS in human gene nomenclature). However, the minimal transforming region (6.6 kb) identified in our cloned DNA borders on the c-fms DNA region but does not contain c-fms coding sequences. The fms sequences are also not represented in the two transcripts (approximately equal to 1.2 and 3.5 kb) detected in NIH 3T3 transformants; however, they might provide elements regulating expression. Hybridization to several known oncogene probes and preliminary sequencing data indicate that we have identified a previously unrecognized "activated" oncogene. Since the rearrangements present in our cloned DNA sequences are not detectable in the original Kaposi tumor DNA used for transfection, it is possible that this oncogene was generated during gene transfer.

Characterization of an episome produced in hamster cells that amplify a transfected CAD gene at high frequency: functional evidence for a mammalian replication origin

In a previous study (G. M. Wahl, B. Robert de Saint Vincent, and M. L. De Rose, Nature (London) 307:516-520, 1984), we used gene transfer of a CAD cosmid to demonstrate that gene position profoundly affects amplification frequency. One transformant, T5, amplified the donated CAD genes at a frequency at least 100-fold higher than did the other transformants analyzed. The CAD genes in T5 and two drug-resistant derivatives were chromosomally located. In this report, we show that a subclone of T5 gives rise to an extrachromosomal molecule (CAD episome) containing the donated CAD genes. Gel electrophoresis indicated that the CAD episome is approximately 250 to 300 kilobase pairs, and a variety of methods showed that it is a covalently closed circle. We show that the CAD episome replicates semiconservatively and approximately once per cell cycle. Since the CAD cosmid, which comprises most of the CAD episome, does not replicate autonomously when transfected into cells, our results indicate that either the process which generated the episome resulted in a cellular origin of DNA replication being linked to the CAD sequences or specific rearrangements within the episome generated a functional origin. The implications of these results for mechanisms of gene amplification and the genesis of minute chromosomes are discussed.

Characterization of an episome produced in hamster cells that amplify a transfected CAD gene at high frequency: functional evidence for a mammalian replication origin

In a previous study (G. M. Wahl, B. Robert de Saint Vincent, and M. L. De Rose, Nature (London) 307:516-520, 1984), we used gene transfer of a CAD cosmid to demonstrate that gene position profoundly affects amplification frequency. One transformant, T5, amplified the donated CAD genes at a frequency at least 100-fold higher than did the other transformants analyzed. The CAD genes in T5 and two drug-resistant derivatives were chromosomally located. In this report, we show that a subclone of T5 gives rise to an extrachromosomal molecule (CAD episome) containing the donated CAD genes. Gel electrophoresis indicated that the CAD episome is approximately 250 to 300 kilobase pairs, and a variety of methods showed that it is a covalently closed circle. We show that the CAD episome replicates semiconservatively and approximately once per cell cycle. Since the CAD cosmid, which comprises most of the CAD episome, does not replicate autonomously when transfected into cells, our results indicate that either the process which generated the episome resulted in a cellular origin of DNA replication being linked to the CAD sequences or specific rearrangements within the episome generated a functional origin. The implications of these results for mechanisms of gene amplification and the genesis of minute chromosomes are discussed.

Herpes simplex virus infection generates large tandemly reiterated simian virus 40 DNA molecules in a transformed hamster cell line

When the simian virus 40 (SV40)-transformed Syrian hamster cell line Elona is infected with herpes simplex virus type 1, an excessive amplification of SV40-specific DNA sequences occurs. Analysis of total DNA from herpes simplex virus-infected cells revealed that amplified DNA sequences were present predominantly in a high-molecular-weight form, consisting of a tandem array of many unit-length SV40 DNA molecules. Repeat units of amplified DNA were found to be very similar to standard SV40 DNA as was shown by restriction analyses, except for a small deletion close to the origin of replication, which could also be detected in the chromosomal DNA of uninfected cells. A procedure, devised for selective enrichment of amplified SV40 DNA molecules from the bulk of cellular and herpesviral DNA, allowed molecular cloning of single repeat units and nucleotide sequence analysis of the relative genomic region.

Genetic alterations of integrated avian sarcoma virus DNA sequences in transformed rat cells

Clones and subclones of Schmidt-Ruppin-RSV-D-(SRD-) infected rat cells that were isolated in soft agar have shown differences in their morphology. Some of the subclones were round or spindle-shaped cells with lower anchorage dependence and high growth rate, while others were more fibroblast-like and failed to overgrow one another. In correlation to their morphology, subclones with high degree of phenotypic transformation contained amplified amounts of full length proviral DNA or proviral fragments. The amplification affected the proviral DNA elements together with host cellular DNA sequences. We have also shown a relationship between the copy number of the proviruses in the cells, the level of expression of viral RNA, and between those two parameters and the various degrees of phenotypic transformation.

Common regulatory elements control gene expression from polyoma early and late promoters in cells transformed by chimeric plasmids

In a previous report we showed that transcripts initiating from the late promoter of integrated polyoma plasmids could be detected at significant levels when neomycin resistance (neo) coding sequences were linked to this promoter. In this report we used chimeric plasmids that contain either a limited portion of the polyoma genome or deletions within the polyoma noncoding regulatory region to determine the sequence requirements for late promoter activity in this system. We observed no absolute requirement for either the polyoma early coding region or the origin of DNA replication for Neo-r colony formation. We were therefore able to independently assess the effects of deletions in the polyoma enhancer region on gene activity in both the early and late directions. We measured the ability of cells transfected with plasmids containing deletions in this region to form colonies in either semisolid or G418-containing medium under nonreplicative conditions. Our results indicate that either the PvuII 4 fragment, which contains the simian virus 40 core enhancer sequence, or a region from nucleotides 5099 to 5142, which contains the adenovirus type 5 E1A core enhancer sequence, can be deleted without significantly affecting gene expression in either direction. However, a deletion of nucleotides 5099 to 5172 reduced activities to similar extents in both directions, and a plasmid containing a larger deletion of nucleotides 5055 to 5182 showed a further reduction in activity. Although having no effect by itself, a second origin region deletion of nucleotides 5246 to 127 when present in these mutant backgrounds caused either a further reduction or elimination, respectively, of both G418 and agar colony-forming ability, suggesting the presence of an additional common regulatory element within this region. A comparison of 5' ends of neo transcripts present in cells transformed by these plasmids suggested that the reduction in activity was due to deletion of regulatory rather than structural elements of the late promoter. Our results indicate that the noncoding region of polyoma contains multiple complementing regulatory elements that control the level of both early and late gene expression.

A polyoma-derived plasmid vector maintained episomally in both E. coli and mouse hepatoma cells

We describe a recombinant plasmid, pBBPY1, containing polyoma virus sequences which persists episomally in mouse hepatoma (MH) cells and can be shuttled between these cells and bacteria. This plasmid is composed of a subgenomic fragment of a polyoma virus mutant that includes two origins of replication; sequences of plasmid pML2; the xanthine-guanine phosphoribosyltransferase gene of Escherichia coli (Ecogpt) under the control of SV40 early-region promoter and RNA processing signals, providing a dominant selectable marker for mammalian transfection. MH cells from colonies growing in HAT medium (hypoxanthine, aminopterin and thymidine) were found to contain vector DNA molecules in an episomal state, the majority of them unrearranged. When HAT-selective pressure was applied for only 3 days, the resulting cells contained up to 50-100 copies of intact plasmid, i.e. 20-fold more than cells grown under standard selection conditions with continuous HAT-selective pressure. Contrary to standard conditions, transient selection does not alter the epithelial morphology nor ability of transfected hepatoma cells to produce albumin.

Germ line transmission of autonomous genetic elements in transgenic mouse strains

Upon microinjection into fertilized mouse eggs of circular molecules of plasmid pPyLT1 carrying the gene encoding the large T protein of polyoma virus within bacterial vector sequences, autonomous circular plasmids were stably maintained in low copy numbers in transgenic strains. These plasmids could be rescued in E. coli by transfection. Integrated forms could be detected neither in somatic tissues, nor in spermatozoa. Efficiency of paternal or maternal transmission was close to 100%. The plasmids had lost or had extensively rearranged the polyoma sequences. In addition, they had acquired defined segments of genomic mouse DNA, which might be responsible for correct segregation of daughter copies at both mitosis and meiosis (centromeric function).

Mapping of phosphorylation sites in polyomavirus large T antigen

The phosphorylation sites of polyomavirus large T antigen from infected or transformed cells were investigated. Tryptic digestion of large T antigen from infected, 32Pi-labeled cells revealed seven major phosphopeptides. Five of these were phosphorylated only at serine residues, and two were phosphorylated at serine and threonine residues. The overall ratio of phosphoserine to phosphothreonine was 6:1. The transformed cell line B4 expressed two polyomavirus-specific phosphoproteins: large T antigen, which was only weakly phosphorylated, and a truncated form of large T antigen of 34,000 molecular weight which was heavily phosphorylated. Both showed phosphorylation patterns similar to that of large T antigen from infected cells. Peptide analyses of large T antigens encoded by the deletion mutants dl8 and dl23 or of specific fragments of wild-type large T antigen indicated that the phosphorylation sites are located in an amino-terminal region upstream of residue 194. The amino acid composition of the phosphopeptides as revealed by differential labeling with various amino acids indicated that several phosphopeptides contain overlapping sequences and that all phosphorylation sites are located in four tryptic peptides derived from a region between Met71 and Arg191. Two of the potential phosphorylation sites were identified as Ser81 and Thr187. The possible role of this modification of large T antigen is discussed.

Superinfection rescue of an integrated defective polyomavirus genome

We have characterized the viral sequences integrated in a polyomavirus-transformed mouse cell line, Py-3T3 (clone Py-6), and followed their excision and packaging upon superinfection. The polyomavirus sequences contained in Py-6 cells are present as a single insert of nonidentical tandem copies which includes, in addition to a normal middle T-antigen-coding region, some very rearranged sequences. Infection of Py-6 cells with polyomavirus strains encoding a normal large T antigen leads to the reproducible recovery in the resulting viral stock of specific defective viral genomes. The defective genomes contain a wild-type coding region for middle and small T antigens and intact viral origin and enhancer sequences. The remainder of the viral genome is rearranged or lost, so that there is no capacity to code for large T antigen or viral capsid proteins. The recovered defective sequences are also found integrated in Py-6 genomic DNA. Presumably, in infections of Py-6 cells, large T antigen, provided by the superinfecting virus, amplifies and excises the integrated viral sequences. The superinfecting helper virus must also produce viral capsids for packaging of the defective viral DNA and thus provides a means to shuttle the defective sequences from the mouse cells into other hosts, such as rat cells. In the latter host, the defective sequences are able to induce transformation.

An inducible eukaryotic host-vector expression system: amplification of genes under the control of the polyoma late promoter in a cell line producing a thermolabile large T antigen

We have taken advantage of the inherent instability of integrated polyoma (Py) DNA sequences in the presence of a functional viral large T antigen (LT) to develop a eukaryotic host-vector system where copy number is controlled by temperature. A mouse cell line WOP32-4, that constitutively expresses a temperature sensitive (ts) LT, was transfected with plasmids containing the Py origin of DNA replication (ori) and either a neomycin-resistance gene (neo) or chloramphenicol acetyl transferase gene (cat) linked to the Py late promoter. Stable transformants were selected at 39 degrees C, the non-permissive temperature for the ts LT function. Upon shift to 33 degrees C, the resident Py sequences present in the WOP32-4 cells cannot excise due to an ori deletion. However, excision of the transfected plasmid molecules and subsequent extrachromosomal replication occur at high rates leading in some cases to the production of 1000-2000 copies per cell (average) of the plasmid. Proportional increases in either neo-specific mRNA or CAT activity were also observed. In situ hybridization for one cell line indicated that about 20% of temperature-shifted cells contained amplified plasmid DNA.

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.

Common regulatory elements control gene expression from polyoma early and late promoters in cells transformed by chimeric plasmids

In a previous report we showed that transcripts initiating from the late promoter of integrated polyoma plasmids could be detected at significant levels when neomycin resistance (neo) coding sequences were linked to this promoter. In this report we used chimeric plasmids that contain either a limited portion of the polyoma genome or deletions within the polyoma noncoding regulatory region to determine the sequence requirements for late promoter activity in this system. We observed no absolute requirement for either the polyoma early coding region or the origin of DNA replication for Neo-r colony formation. We were therefore able to independently assess the effects of deletions in the polyoma enhancer region on gene activity in both the early and late directions. We measured the ability of cells transfected with plasmids containing deletions in this region to form colonies in either semisolid or G418-containing medium under nonreplicative conditions. Our results indicate that either the PvuII 4 fragment, which contains the simian virus 40 core enhancer sequence, or a region from nucleotides 5099 to 5142, which contains the adenovirus type 5 E1A core enhancer sequence, can be deleted without significantly affecting gene expression in either direction. However, a deletion of nucleotides 5099 to 5172 reduced activities to similar extents in both directions, and a plasmid containing a larger deletion of nucleotides 5055 to 5182 showed a further reduction in activity. Although having no effect by itself, a second origin region deletion of nucleotides 5246 to 127 when present in these mutant backgrounds caused either a further reduction or elimination, respectively, of both G418 and agar colony-forming ability, suggesting the presence of an additional common regulatory element within this region. A comparison of 5' ends of neo transcripts present in cells transformed by these plasmids suggested that the reduction in activity was due to deletion of regulatory rather than structural elements of the late promoter. Our results indicate that the noncoding region of polyoma contains multiple complementing regulatory elements that control the level of both early and late gene expression.

Sequences in the polyomavirus DNA regulatory region involved in viral DNA replication and early gene expression

We constructed and analyzed a series of deletion mutants in the noncoding regulatory region of tsa polyomavirus DNA to identify some of the sequences critical to the DNA replication origin and to the expression of the viral early genes in vivo. By using both transient and long-term assays under conditions where the influence of large T antigen (T-Ag) in replication or autoregulation was minimized, we observed no more than a 30% reduction in early gene expression upon removal of the CAAT or TATA elements or both. These assays demonstrated a predominant effect of upstream promoter or enhancer elements and indicated that removal of the CAAT or TATA boxes did not significantly affect viral early gene expression. Studies on the replicative ability of these mutants in mouse cells constitutively expressing the polyoma early proteins revealed that the removal of DNA sequences contained within a previously identified T-Ag high-affinity binding site (nucleotides 39 to 64) abolished viral DNA replication, whereas removal of two other high-affinity sites, closer to the early mRNA cap sites, did not. Furthermore, a deletion including this same high-affinity site plus a low-affinity binding site within the 32-base-pair palindrome of the origin core sequences eliminated the ability of the viral large T-Ag to efficiently repress early gene transcription. It is thus possible that the origin-proximal high-affinity T-Ag binding site is involved in both of the functions of large T-Ag, i.e., the initiation of viral DNA replication and the autoregulation of early gene transcription.

Homologous recombination of polyoma virus DNA in mouse cells

We have produced nonviable deletion mutants of polyoma virus in order to study homologous recombination after DNA transfection into mouse cells. The frequency of recombination was determined by the formation of infectious virus. It was dependent on the amount of DNA transfected and the size of the region of homology between the mutations. Recombination frequencies were highest when both mutated genomes were transfected in closed circular form rather than after linearization of one or both of the recombination partners. The system described may be useful for a more detailed analysis of physiological and genetic conditions influencing the frequency of homologous recombination in mouse cells as well as to study enzymes involved and intermediates produced in this process.

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.

Simian virus 40 T antigen is required for viral excision from chromosomes

We describe experiments that show that simian virus 40 (SV40) T antigen is required for viral excision from host chromosomes at some point prior to or during the homologous recombination events that create circular wild-type virus. Two recombinant SV40-pBR322 plasmids were constructed such that homologous recombination across similar-sized but different duplications of SV40 would reconstitute wild-type viral DNA. One plasmid (pSVED) was constructed such that the duplication separates the viral early T-antigen promoter from the coding sequences; the other recombinant (pSVLD) contains a duplication of the late viral sequences and thus maintains a complete T-antigen gene. These plasmids were individually established in Rat 2 cells via cotransformation with the herpes virus Tk gene. Both classes of cell lines contained integrated tandem arrays of the plasmids and yielded equivalent levels of infectious virus after cell fusions with COS-7 cells; however, only the T+ lines yielded virus after cell fusion with CV-1 cells. These results are consistent with the notion that viral excision is initiated by T-antigen-mediated in situ replication of viral DNA as proposed in the "onion skin" model. In contrast, both plasmids yielded infectious virus when transiently introduced via transfection into CV-1 cells. This latter finding is discussed in terms of the possible induction of cellular repair and recombination pathways evoked by the introduction of damaged DNA into the nucleus.

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.