The gene encoding the major viral structural protein stimulates recombination in polyomavirus DNA

RmI is a chimeric DNA molecule consisting of a polyoma genome in which a partly duplicated VP1-coding region brackets an insert of murine DNA (Ins); when transfected into mouse cells, RmI recombines intramolecularly to yield infectious, unit-length, polyoma DNA. We report here that RmI encodes a polypeptide of 337 amino acids (designated VmP1) which includes the N-terminal 328 amino acids of VP1 and 9 amino acids specified by Ins. Mutating the VmP1-coding sequence strongly reduces the ability of RmI to yield polyoma DNA. In contrast, mutating the portion of the VP1-coding sequence which is not part of the VmP1-coding sequence has little or no impact on the ability of RmI to yield polyoma DNA, even though it renders such DNA noninfectious. Thus, release of polyoma DNA from RmI involves a function of VP1 distinct from that ensuring virus assembly and propagation; since VP1 can arise only after recombination has occurred, VmP1, but not VP1, could carry such a function. We suggest that VmP1 acts in concert with VP2, which we have already reported to stimulate recombination in RmI.

Involvement of minor structural proteins in recombination of polyoma virus DNA

We have previously observed that a polyoma-mouse chimeric DNA molecule (RmI) in which the murine DNA insert is flanked by directly repeated viral sequences is effectively converted into unit-length polyoma DNA upon transfection of permissive mouse cells. This intramolecular recombination event appears to be dependent on VmP1, a protein encoded by RmI which includes the 328 N-terminal amino acids of polyoma VP1, and nine amino acids of murine origin carrying the C-terminus of the protein. We report here that introducing mutations into the VP2/VP3 coding sequence reduces the ability of RmI to generate polyoma DNA, even though the same mutations seem to exert little or no effect on the ability of polyoma DNA to either replicate or accumulate inside transfected cells. A mutation affecting VP2 alone being as effective as one that affects both VP2 and VP3, VP2 appears to be playing a critical role in recombination.

Rescue of polyomavirus DNA after co-transfection of recombinant plasmids with viral DNA fragments

Plasmid DNA bearing a single copy of the mouse polyomavirus (Py) genome (template A) was transfected into murine cells together with another DNA (template B) carrying intact the viral sequence interrupted in template A. Rescue of unit-length Py DNA including markers from both templates was observed as long as the viral DNA in B overlapped that split in A by one kbp or more. Such rescue was not detectably enhanced by linearizing either or both template(s), and occurred in the absence of template replication. These findings are suggestive of an intermolecular recombination process taking place soon after transfection and starting with homologous pairing between A and B. Such pairing would facilitate removal of vector DNA from one template (A), followed by closure of the resulting break or gap through recombination with the other template (B). Since B may consist of a PCR-synthesized DNA fragment, these observations could conceivably serve as the basis for a method of generating mutant viral genomes.

p53-mediated DNA renaturation can mimic strand exchange

The process of strand exchange is considered to be the hallmark of DNA recombination. Proteins known to carry out such exchange are believed to operate via one or the other of two mechanisms. RecA-like proteins promote the formation of a three-stranded or triplex synaptic intermediate in which strand exchange occurs, whereas other proteins would allow the coordinated exonucleolytic degradation of one strand in the duplex DNA and its replacement by an invading strand of similar sequence and polarity. In view of properties ascribed to it, we have attempted to determine whether p53 belongs to one or the other of these groups of proteins. The in vitro assay used relies on a double-stranded (ds) oligonucleotide (oligo 1+2) and a single-stranded (ss) oligonucleotide (oligo 3), part of which is complementary to oligo 1. The data collected suggest that, under the conditions of the assay, oligo 1+2 undergoes partial denaturation; p53 then catalyzes renaturation of oligo 1 with oligo 3, rather than true strand exchange. Since p53 is not known for being able to 'melt' DNA, it would seem unlikely that this protein would effect strand exchange in vivo without assistance from another, denaturing, protein.

An enhancer of recombination in polyomavirus DNA

Previous work from this laboratory has indicated that intramolecular homologous recombination of polyomavirus (Py) DNA is dependent upon promoter structure or function. In this report, we demonstrate that Py DNA contains not two but three binding sites for transcription factor YY1, all located on the late side of viral origin of replication (ori) and the third well within the VP1 coding sequence. This third site (Y3), which may or may not play a role in transcription regulation, is immediately adjacent to a previously described recombination hot spot (S1/S2). We found that Py replicons carrying an altered Y3 site recombined in a manner suggesting partial inactivation of the S1/S hot spot. Point mutations precluding the binding of YY1 to Y3 in vitro depressed hot spot activity in vivo; however, of the two reciprocal products reflecting recombination at this spot, only that carrying the mutated Y3 site arose at a reduced rate. These results are interpreted in light of a model assuming that recombination occurs within a transcriptionally active viral chromatin tethered to the nuclear matrix by YY1.

Quantitation of Chlamydia trachomatis by culture, direct immunofluorescence and competitive polymerase chain reaction

OBJECTIVES

Methods to quantitate Chlamydia trachomatis have never been compared although it would be relevant to periodically evaluate the sensitivity of a detection system. We compared the sensitivity and reproducibility of culture, direct immunofluorescence and the polymerase chain reaction (PCR) to quantitate C trachomatis.

METHODS

A competitive semiquantitative PCR procedure was developed. The number of inclusions in culture, particles by direct immunofluorescence and DNA copies by PCR were measured for 12 patient specimens. Variation was determined by measuring a sample 10 times for each method.

RESULTS

Patient C trachomatis major outer membrane protein gene DNA was measured semiquantitatively by amplifying together with reference DNA. DNA molecules, particles and infectious units were quantitated in clinical samples with, on average, 595 DNA molecules and 87 immunofluorescent particles observed per inclusion-forming-unit. Similar coefficients of variation (47-52%) were observed for the 3 procedures.

CONCLUSION

Competitive PCR and counting immunofluorescent particles provide reproducible and sensitive methods of quantitating C trachomatis.

Topoisomerase activity associated with polyoma virus large tumor antigen

Polyomavirus (Py) large tumor antigen (LT) was produced in mammalian or insect cells infected with a suitable viral expression vector, and purified by a procedure combining immunoprecipitation with ion-exchange chromatography. Fractions containing the bulk of LT displayed a DNA-relaxing activity (LT-topo) which could be attributed neither to topoisomerase II (topo II) nor to topoisomerase I (topo I) encoded by the cell or the viral vector. On the one hand, LT-topo relaxed pBR322 DNA in a reaction which, unlike that characteristic of topo II, was ATP-independent and inhibited by camptothecin. On the other hand, serum from scleroderma patients which strongly inhibited calf thymus topo I had no effect on LT-topo, which absolutely required Mg2+ ions to relax DNA. Thus, LT-topo is either inherent to LT or belongs to a LT-bound enzyme similar to, but distinct from, topo I.

A hotspot for promoter-dependent recombination in polyomavirus DNA

We have engineered polyomavirus (Py) DNA molecules carrying two large direct repeats within the late coding region, as well as a deletion encompassing the TATA box in the early promoter. Such constructs recombine less readily than a construct containing the same duplication of late sequences, but an intact early promoter. Furthermore, residual recombination in the molecules with a deletion occurs between homologous sites which differ from those used in the molecule without deletion. These findings are consistent with recombination being stimulated by transcription originating from the early promoter, rather than facilitated by the "openness" of viral chromatin undergoing transcription.

Variation outside variable segments of the major outer membrane protein distinguishes trachoma from urogenital isolates of the same serovar of Chlamydia trachomatis

OBJECTIVES--Whereas serovars A, B, Ba and C of Chlamydia trachomatis are usually associated with trachoma, two of these serovars (Ba and C) are occasionally observed in urogenital infections. Variation in the gene encoding the major outer membrane protein (MOMP) was explored to distinguish urogenital from trachoma specimens of the same serovar. METHODS--A large portion of the MOMP gene was amplified by nested PCR directly from clinical samples from trachoma or urogenital infection and the serovar of the infecting C trachomatis was determined by restriction fragment length polymorphism (RFLP). Amplified DNA from trachoma serovars B, Ba and C and from urogenital serovars Ba, C, D and E was sequenced by the dideoxy chain termination method. RESULTS--While almost identical in variable segment (VS)I, three urogenital Ba samples differed from all trachoma B and Ba samples at eight nucleotides including two sites which changed amino acids in the constant region upstream of VSI. An identical sequence in this region was observed for the reference urogenital D serovar. Variation in this same region upstream of VSI also distinguished 40% of serovar D samples from prototype D including three that were sequenced. Two urogenital C differed from trachoma C samples at four sites that changed the MOMP amino acid sequence including two changes in the constant region between VSII and III and single changes in VSII and III. On the basis of these sequence determinations, RFLP was predicted which allowed extension of these observations to 20 other urogenital Ba, 12 trachoma B or Ba, seven variant D, 12 D, four urogenital C and three trachoma C samples without further sequencing. CONCLUSION--Urogenital Ba and C samples have VSI or II and III sequences identical or very similar to trachoma strains of the same serovar, but resemble more closely other serovars in the constant regions. Urogenital serovar D samples can also be divided into two genotypes on the basis of sequence differences in the constant region preceding VSI.

Intramolecular recombination in polyomavirus DNA is a nonconservative process directed from the viral intergenic region

Previously, we have studied intramolecular homologous recombination in polyomavirus replicons under conditions allowing only one amplifiable recombination product to be generated from a single precursor molecule. In order to detect putative reciprocal product(s), we have now constructed precursor polyomavirus replicons which contain two copies, instead of one copy, of the viral intergenic region, including the origin of replication as well as both promoters. Upon transfection of mouse cells, constructs containing directly repeated intergenic regions yielded distinct amplifiable products, in number depending upon the functional integrity of both intergenic regions. Our data indicate that of two possible reciprocal products, a given precursor molecule would yield either one or the other but never both at the same time. Most striking, however, is the observation that promoter function is required for recombination, while the origin of replication function may be needed only for amplification of the recombination product once it has been formed. The data reported here confirm and extend previous data suggesting that (i) transcription is instrumental in recombination between direct repeats and (ii) nonconservative recombination involving direct repeats relies upon two promoters of opposing polarities.

Intramolecular recombination in polyomavirus DNA is controlled by promoter elements

We show here that intramolecular homologous recombination in polyomavirus (Py) DNA depends upon discrete sequence elements of the viral regulatory region which are believed to regulate transcription initiation and exert little or no cis-control over replication. Either deleting the viral early promoter (EP) or inverting the viral late promoter (LP) strongly impairs viral DNA recombination under conditions allowing viral DNA replication to proceed undisturbed. These findings suggest that bi-directional transcription proceeding from the intergenic region favors intramolecular recombination.

Topoisomerase activity associated with SV40 large tumor antigen

Purified preparations of simian virus 40 (SV40) large tumor antigen (LT) from three different sources, including LT expressed from a recombinant baculovirus, were found to relax negatively supercoiled cyclic DNA molecules, whether or not they contained SV40 sequences. Relaxation was stimulated by MgCl2 but not by ATP, and inhibited by camptothecin, suggesting the involvement of an enzymatic activity similar to that of topoisomerase I (topo I). However, the pH requirements for relaxation by respectively LT and topo I are different. Also, antibodies reacting with LT inhibited relaxation by preparations of LT but not topo I, whereas antibodies inhibiting relaxation by topo I had no effect on relaxation by LT. Reconstruction experiments suggested that both procedures used to purify LT, immunoaffinity chromatography and DEAE-Sepharose chromatography, separate topo I from LT. Finally, relaxing activity was found in over 40 preparations of LT, and in the few instances where activity could not be found, it probably had been lost during storage, rather than absent from the start. Whereas these results seem to exclude that the activity being detected is that of a contaminant of LT, they would be consistent with this activity being that of a stable topo-LT complex, or else intrinsic to LT itself.

Crossover site selection during recombination of polyomavirus replicons

Two hybrid replicons containing polyomavirus (Py) genomes with large duplications of the viral late coding sequences were transfected into various permissive mouse cell lines. In all cell lines, either replicon yielded the sole amplifiable product expected from intramolecular homologous recombination, unit-length Py DNA (P155). In normal and in Py-transformed cells, such recombination was highly effective and involved sequences previously found to act as recombination hot spots (S repeats). In cells transformed by simian virus 40, however, these hot spots were inoperative in the generation of P155, which occurred with a reduced efficiency. These data confirm and extend earlier data indicating that the nature of products arising from recombination in Py replicons is tightly controlled by both cis- and trans-acting factors.

The same mammalian replicon yields distinct recombination products in different cell lines

We have observed previously that some chimeric replicons inclusive of a partly duplicated polyomavirus (Py) genome yield unit-length Py DNA (P155) at high frequency when transfected into normal or Py-transformed mouse cells. We demonstrate here that one such replicon generates either P155 or illegitimate recombination products in other mouse cells, transformed by simian virus 40. Use of the polymerase chain reaction indicates that each of the illegitimate products carried a different deletion, but that all deletions mapped within a rather well defined portion of the precursor replicon. Thus, these products were organized as if two hotspots for recombination existed in the Py late-coding region, one being located within or near one of the duplicated sequences characteristic of the chimeric replicon. Since this particular hotspot has already been shown to be involved in the generation of P155, the data reported here could indicate that a single recombination mechanism can yield either homologous (P155) or illegitimate products. How the DNA interacts with certain proteins, such as papovavirus large tumor antigen, could explain why one or the other type of product is formed.

DNA nicking favors PCR recombination

We attempted to use the polymerase chain reaction (PCR) to monitor in vitro recombination in a plasmid containing directly repeated sequences. Some of the plasmid preparations which had not been exposed to recombination conditions were however found to behave in the PCR test as if they had undergone homologous recombination. We show here that such false positives are attributable to a small degree of nicking and/or breaking of the DNA template. Presumably, such damage allows the formation of hybrid parental duplexes containing at least one truncated strand, the 3' end of which maps within the homology; extension of this 3' end by the polymerase then results in a linkage of sequences identical to that arising from homologous recombination.

Alternative homologous and nonhomologous products arising from intramolecular recombination

RmI, a chimeric DNA molecule containing polyomavirus (Py) and mouse sequences, generates unit-length Py DNA via intramolecular recombination between two directly repeated viral sequences of 182 base pairs (S repeats). To analyze the contribution of the S repeats in this process, we produced mutants of RmI carrying deletions in either one or both S repeats and tested them for their ability to recombine in mouse 3T6 cells. Mutant DNAs were found to yield unit-length Py DNA as long as they carried a minimal internal homology of 40 to 50 base pairs. Unlike RmI itself, however, the mutants also gave rise to nonhomologous recombination products. These results suggest that when the generation of homologous products is hampered by a limiting homology, nonhomologous products may arise instead of homologous ones. Therefore, the initial step(s) in the mechanisms yielding the two kinds of products could be identical.

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.

A substitution in a nonconserved region of polyomavirus large T antigen which causes a thermosensitive mutation

The temperature-sensitive defect of the tsP155 mutant of polyomavirus (Py) maps in the large T antigen (LT) coding sequence of a viral DNA diverging markedly from that of extensively characterized wild-types (WTs) such as A2 and CSP. We have sequenced about 600 base pairs (bp) "early" DNA encompassing the mutated site in tsP155, as well as the corresponding DNA segment from a revertant virus (RtsP155). As expected, tsP155 was found to be more closely related to CSP than to A2. Out of 3 single bp differences between tsP155 and CSP, 2 were common to tsP155 and RtsP155. The only substitution exclusive to tsP155 was a G----C transversion at bp 2658 which canceled the HaeIII site at bp 2657. Heteroduplexes inclusive of tsP155 DNA and of a 312-bp-long fragment of RtsP155 DNA yielded recombinant viruses growing under restrictive conditions whose DNAs had all regained the HaeIII site at bp 2657. These findings clearly identify the ts mutation with the tranversion at bp 2658, which is expected to change Ala 701 for a Pro in LT. We discuss this substitution in relation to the phenotype of tsP155.

Major rearrangement of cellular DNA in the vicinity of integrated polyomavirus DNA

The Cyp cell line was produced by transforming mouse embryo cells at the restrictive temperature with an early thermosensitive mutant of polyomavirus (Py). Transfer of Cyp cells to the nonrestrictive temperature causes excision to occur at a single chromosomal site carrying viral DNA, and leads to the production of infectious virus. We have attempted to elucidate the recombination event that occurred during the integration of Py DNA in this inducible line. Physical characterization of two recombinant DNAs-one selected from a genomic library of normal mouse DNA and the other constructed from the unoccupied allele of the Cyp integration site-indicates that generation of the Cyp line has involved the joining of not only viral DNA to a cellular alpha site, but also the cellular alpha site to a cellular alpha site to cellular beta site. Hence, previously described hybrid excision products from the Cyp line were made of mouse DNA segments representing two distinct cellular sites. The alpha-beta joining may play a role in the expression of integrated Py DNA.

Resolution of a polyomavirus-mouse hybrid replicon: viral function required for recombination

RmI, a circular chimera made of the polyomavirus (Py) genome with an insertion of mouse DNA (Ins), effectively undergoes intramolecular recombination in normal mouse cells, as indicated by the conversion of cloned RmI (RmIc) into unit-length Py DNA in transfected cultures. To follow the fate of the cellular component of RmI after recombination, the origin of simian virus 40 (SV40) DNA was inserted into the Ins region of RmIc, generating a new molecular species designated SV-RmIc. The recombination of SV-RmIc in simian cells synthesizing SV40 large T antigen gave rise to a molecule containing the SV40 origin, the reciprocal of unit-length Py DNA. However, SV-RmIc failed to yield unit-length Py DNA in murine cells unless Py large T antigen was provided in trans. In murine cells synthesizing SV40 large T antigen, the only detectable product from SV-RmIc contained only Py sequences, but was heterogeneous in size. These results and others also reported here strongly suggest that Py large T antigen plays a direct role in the resolution of RmI in murine cells.

Resolution of a polyomavirus-mouse hybrid replicon: release of genomic viral DNA

RmI is a circular chimera containing 1.03 copies of polyomavirus DNA and 1,628 base pairs of mouse DNA, joined through direct and inverted repeat sequences. It is excised from the chromosome of a transformed cell via a site-specific recombination event that is dependent on the activation of the viral gene coding for large T antigen. RmI is shown here to be highly infectious for normal mouse cells. This infectivity reflects the ability of RmI to effectively yield unit-length viral DNA via intramolecular recombination. The effectiveness with which infectious viral DNA is produced from RmI is consistent with the idea that the underlying recombination event is site specific, rather than homologous or illegitimate.

The MT family of mouse DNA is made of short interspersed repeated elements

In certain mouse cells transformed by polyomavirus (Py), viral DNA is excised from the chromosome together with a defined mouse component, which has been designated Ins [Bourgaux et al., Virology 122 (1982) 84-97]. Ins carries a sequence which anneals with the DNA at many sites in the mouse genome, while displaying no detectable homology with well-characterized SINEs and LINEs [Sylla et al., Gene 29 (1984) 343-350]. Recently, others have reported that this sequence belongs to a newly discovered family of repetitive mouse DNA, designated MT for Mouse Transcript [Heinlein et al., Nucl. Acids Res. 14 (1986) 6403-6416]. We demonstrate here that the MT family consists of short interspersed repetitive sequences (SINEs) with structural features of retroposons. Using cloned fragments of Ins as probes, we have identified recombinants carrying MT sequences in a genomic library of mouse DNA. Regions of homology to the probes were subcloned twice from the DNA of lambda phage using plasmids pAT153 and pUC13, and characterized in detail by heteroduplex mapping and by sequencing. The three distinct elements thus studied were highly homologous over 400 bp, terminated in 3' with a short sequence rich in A residues, and were flanked by a short direct repeat. On the basis of these complete elements, a 400-bp consensus sequence was established for the MT family.

An excision event that may depend on patchy homology for site specificity

In mouse cells transformed by a mutant polyomavirus genome, recombination between integrated viral DNA and flanking cellular DNA resulted in the excision of two readily amplifiable chimeras, designated RmI and RmII. The crossing-over that generated RmII was unique in that it involved a simple cellular sequence in which the triplet 5'-CTG-3' was repeated many times. We show that the sequence across the junction resulting from excision was identical in several molecules of RmII, as if the cross-over generating this junction always involved exactly the same two sites on the viral and cellular DNA. We also show that the cellular site mapped where the replacement of a G by an A in one of many successive 5'-CTG-3' triplets generated a homology of five nucleotides (5'-CTACT-3') with the viral site. Oligonucleotides on both sides of these sites are probably involved in matching the two DNAs prior to recombination.

An amplified genome that may have resulted from recombination within bidirectionally replicating DNA

Temperature shift-down of permissive mouse cells transformed by a temperature-sensitive (ts) polyomavirus (Py) genome has been shown to induce the accumulation of free copies of the viral DNA. We report here on an unusual product from such induction. The structure of this product is that expected from the occurrence of recombination between growing points in a bidirectionally replicating Py-mouse DNA molecule. This observation may be relevant to the mechanism of gene amplification in mammalian cells.

Mouse cells surviving polyoma virus infection generally retain the whole viral genome

Permissive mouse 3T6 cells were exposed to polyoma virus--either wild-type or early mutant--at high multiplicities of infection. From colonies arising from surviving cells, so-called lines and clones were derived under conditions precluding superinfection. These lines and clones were examined for the presence of viral genetic information, using a variety of techniques. Two salient findings were made: most lines or clones analyzed had retained viral genetic material; generally, this material was nondefective, as evidenced by the production of virus and/or viral DNA molecules of genomic size. These findings indicate that mouse cells can survive for many generations while carrying a complete, infectious, and potentially cytocidal polyoma virus genome.

Alternative excision products originating from a single integration of polyomavirus DNA

The Cyp cell line consists of mouse cells transformed by a thermosensitive polyomavirus (Py) genome and routinely propagated at 39 degrees C. Cyp cells are readily induced to synthesize free Py DNA by being transferred to 33 degrees C. In one subclone (C12/a1/S48, or S48) of this line, such induction resulted in the intracellular accumulation of three discrete species of cyclic DNA, i.e., genomic Py DNA, RmI, and RmII. RmI and RmII are Py-mouse chimeras, each of which contains a distinct set of sequences originating from the site of integration. Conceivably, genomic Py DNA, RmI, and RmII could persist at 39 degrees C as free replicating plasmids or originate from distinct populations of cells in S48 cultures. The data indicated that all three species arise at 33 degrees C from a genetically homogeneous cell population in which neither RmI nor RmII replicates at 39 degrees C. Examination of the sequence at the viral-cellular junction unique to RmII indicated that this chimera is excised from the host chromosome through a recombination event involving a complex viral sequence and a simple cellular sequence. Therefore, RmII provides another example of precise recombination occurring between nonhomologous sequences in a mammalian cell, as already observed for RmI (B. S. Sylla, D. Huberdeau, D. Bourgaux-Ramoisy, and P. Bourgaux, Cell 37:661-667, 1984).

A mouse DNA sequence that mediates integration and excision of polyoma virus DNA

In mouse cells transformed by a temperature-sensitive polyoma virus (Py) genome, the integrated viral genome recombines with adjacent chromosomal DNA to yield a small cyclic molecule (RmI) with defined viral and cellular components. We have cloned the cellular component (Ins), determined its sequence, and examined its distribution in normal mouse DNA. The sequence of Ins displays several homologies with that surrounding the replication origin (ori) of Py or SV40 DNA.

The temperature-sensitive defect in polyoma virus P155 mutant

P155 is a temperature-sensitive mutant of polyoma virus that transforms normally, but replicates poorly, under restrictive conditions (Eckhart, 1969, 1975). We have observed that the temperature-sensitive character of P155 maps within the portion of the viral DNA coding exclusively for large T antigen, a viral gene product which is thermolabile in P155-infected cells. The phenotype of P155 may indicate that large T antigen fulfills different functions in virus replications and in cell transformation.

Site-specific excision of integrated polyoma DNA

Cyp cells are permissive murine cells carrying a thermosensitive polyoma virus genome that remains integrated at 39 degrees C, but is effectively excised and replicated after transfer to 33 degrees C. In rare subclones of the Cyp line, temperature shift-down yields predominantly homogeneous populations of chimeric molecules that appear to reflect the circularization of defined segments of DNA spanning one of the junctions between the integrated viral genome and the adjacent cellular DNA. Such accurate and frequent excision requires a specific recombination mechanism. We examined both the cellular and the viral sequences that cross-over to generate one of these chimeric molecules, Rm I. The homology at the cross-over site is one of 1 or 2 base pairs at most; patches of homology, amounting in total to 19 or 20 base pairs, are found in perfect register on both sides of this site; and the two stretches of DNA that are joined to form RM I contain similar 12-14 base pair sequences (5'- CTCCTTTACAGAGG -3' and 5'- CTCCTTTCAAGG -3') in opposite orientations.

Inducible permissive cells transformed by a temperature-sensitive polyoma virus: superinfection does not allow excision of the resident viral genome

After exposure of mouse embryo cells to the early temperature-sensitive mutant tsP155 of polyoma virus (Py), a transformed cell line (Cyp line) that can be readily induced to synthesize Py by transfer to 33 degrees C was isolated at 39 degrees C (7). Virus production and synthesis of free viral DNA occurring after temperature shiftdown or superinfection with wild-type Py or both were studied in several clonal isolates of the Cyp cell line. Measurements of virus yields indicated that, although some could be induced more effectively than others, all cell clones behaved as highly permissive when subjected to superinfection. We analyzed the origin of free viral DNA accumulating in the superinfected cultures, taking advantage of (i) the unique physical properties of the low-molecular-weight DNA which, in the case of one of the Cyp clones, accumulates during temperature shiftdown, and (ii) the differences between resident and superinfecting viral genomes in their susceptibilities towards restriction endonucleases. At 33 degrees C, both viral genomes were found to accumulate in all clones studied whereas in the case of the clones with lower inducibility, the replication of the resident genome appeared to be enhanced by superinfection. At 39 degrees C, however, accumulation of the superinfecting genome was not accompanied by that of the resident genome, unless it had already been initiated before superinfection. These findings demonstrate that, when routinely cultivated at 39 degrees C, Cyp cells contain few viral DNA molecules readily available for autonomous replication and that, upon transfer to 33 degrees C, therefore, excision must first take place before the resident genome can accumulate as free viral DNA. Our findings also suggest that, unlike the P155 gene product provided by the resident viral genome upon induction, the allelic gene product supplied by the superinfecting genome may be less effective in triggering excision than in promoting replication.

Integrated polyoma genomes in inducible permissive transformed cells

Using the approach described by Botchan, Topp, and Sambrook (Cell 9:269-287, 1976), we analyzed the organization of the integrated viral sequences in five clonal isolates from the same permissive, inducible cell line (Cyp line) transformed by the tsP155 mutant of polyoma virus. In all five clones, viral sequences were found that could be assigned to a common integration site, as they were joined to the cellular DNA in the same fashion in every instance. However, the sequences comprised between these points differed markedly from clone to clone, as if cell propagation had been accompanied by amplification or recombination or both within the viral insertion. When the clones were compared, no correlation could be found between the abundance, or the organization, of the integrated viral sequences and the amount, or the nature, of the free viral DNA molecules produced during induction. Altogether, our findings suggest that specific events, occurring during either the excision or the subsequent replication of the integrated viral sequences, are responsible for the predominant production of nondefective viral DNA molecules by permissive transformed cells, such as Cyp cells.

Two classes of replicating molecules of adenovirus type 2 DNA

Replicating DNA of human adenovirus type 2, identified as partly single-stranded viral DNA in which [3H]thymidine is readily incorporated, was found to be separated into two fractions by chromatography on hydroxyapatite. Whereas one of the these fractions was eluted with 180 mM phosphate, the other one was eluted at the same concentration, 240 mM, as fully double-stranded DNA. The physical properties of the 180 and 240 mM fractions, in particular their buoyant densities in solutions of CsCl and Cs2SO4, were compared both before and after treatment by various enzymes such as Neurospora crassa nuclease, pancreatic ribonuclease, ribonuclease H and the Klenow fragment of DNA polymerase I of Escherichia coli, used alone or in various combinations. Unlike the 240 mM fraction, the 180 mM fraction was found to include a substantial amount of single-stranded DNA, some of it being hydrogen-bonded to RNA. Both of these features confer to the 180 mM fraction the high buoyant density in cesium salt solution which was described, for several adenoviruses, as one of the characteristic properties of replicating DNA.

Biological properties of polyoma DNA fragments cloned in plasmid pBR322

The two HindIII fragments of polyoma virus DNA were cloned in the HindIII site of plasmid pBR322, and the biological activity of the recombinant plasmids was tested in tissue culture cells. A mixture of recombinant plasmids containing the HindIII-A and HindIII-B fragments was infectious, but only after cleavage with HindIII. Recombinant plasmids containing the HindIII-A fragment, but not those containing the HindIII-B fragment, induced the transformation of Fischer rat 3T3 cells. These findings indicate that about half of the early region of polyoma virus DNA is not essential for the initiation of the maintenance of transformation.

Induction of virus multiplication in permissive cells transformed by a temperature-sensitive polyoma virus. I. Isolation and partial characterization of survivors

A fibroblastic cell line transformed by ts-P155, an early temperature-sensitive mutant of polyoma virus, has been isolated after infection of secondary mouse embryo cells at the restrictive temperature of 39. These cells, designated Cyp, undergo a massive CPE accompanied by the production of infectious, temperature-sensitive virus when transferred to the nonrestrictive temperature of 33. Several independent clones were established from cells which survived the induction of virus multiplication occurring at 33. When routinely cultured at this temperature, these cells, termed R, displayed the growth properties of transformants and produced variable amounts of infectious, temperature-sensitive virus. This shedding of virus could not be "cured' by the addition to the culture medium of antipolyoma serum which had already been found to effectively suppress virus production in Cyp cell cultures transferred to 33. Moreover, R cells seemed to have developed a resistance to superinfection that the parent Cyp cell line did not exhibit. Therefore, virus production in R cell cultures probably reflects the occasional excision and replication of integrated viral genomes rather than a carrier state.

Further studies on the replication of adenovirus type 2 DNA

Monolayer cultures of KB cells infected with adenovirus type 2 (Ad2) were subjected to short pulses of tritiated thymidine, at the time of maximal viral DNA synthesis. Nascent viral DNA was selectively extracted from the cells, purified, and fractionated into partly single-stranded (or replicating) molecules and double-stranded (or completed) molecules. Completed molecules were cleaved by the restriction endonucleases from either Escherichia coli (EcoRI), Haemophilus influenzae (Hind III), Haemophilus parainfluenzae (Hpa I), or by the latter two enzymes in succession, and the resulting fragments were separated by electrophoresis through agarose–acrylamide slab gels. In the case of replicating molecules, the double-stranded fragments generated after treatment with the same enzymes were first separated from the partly single-stranded fragments by chromatography on benzoylated–naphthoylated DEAE (BND) cellulose before being subjected to electrophoresis. The relative yields of tritium of the various fragments resolved by the gels were then determined. As already described in several reports, the analysis of the completed molecules obtained after the shorter pulses revealed a strong preferential labeling of the fragments derived from the molecular ends, as expected if both of these ends contained termini for replication. The analysis of double-stranded fragments from replicating molecules revealed a predominant labeling of the central portion of the genome which could be reconciled with initiation occurring either centrally or at both molecular ends. In addition, two gradients of labeling, ascending toward each molecular end and encompassing the outer quarters of the molecule, were noted which slowly receded when the pulse length was increased. The latter finding, which is in agreement with our earlier results, could reflect an overrepresentation of molecules in the late stages of replication in the pool of nascent DNA, such as one would expect if replication slows down when it nears the termination site(s). This interpretation is consistent with the kinetics of labeling of the various portions of the genome observed in the pool of completed molecules. Because of this complication, however, the distribution of label in replicating molecules cannot be used to ascertain unambiguously the location of the origin(s) of replication on the Ad2 DNA molecule.

Structures of polyoma virus: on the histone component and virion core

We have observed that purified polyoma virus is able to take up an amount of calf thymus histone equivalent to 10 to 50% of its normal histone content under conditions allowing the binding of considerably lesser amounts of several other proteins. Some of the bound histone could not be released by procedures procedures routinely used for virus purification. We have also found that some of the histone present in purified polyoma virus could be selectively released without major breakdown of virus particles. Possible models for virus structure are discussed in the light of the present and other recent data.

Transformation of human cells by temperature-sensitive mutants of simian virus-40

Conditions necessary for the establishment and maintenance of transformation of human cells by wild type and temperature-sensitive mutants of SV40 were examined. For both early and late mutants, the frequency of transformation was found to be up to 5-fold higher, and virus yield 100-fold lower, at 39 degrees than at 33 degrees. No such effect was observed with the wild type virus under the same conditions. This observation is apparently at variance with previously published work, but may be explained by the semipermissive nature of the cells that we used. Increasing the temperature to 40.5 degrees caused cells transformed by the early mutant, tsA30, to lose T-antigen as detectable by staining, and also to lose the ability to grow to high density, while it produced no effect on cells transformed by wild type virus.