Polyoma and cell DNA synthesis in mouse L cells temperature sensitive for the replication of cell DNA.

Polyoma (Py) virus multiplies, at 34 and 38.5 C, in wild-type (WT-4) and in ts A1S9 mouse L cells, which are temperature sensitive for growth and for DNA replication (R. Sheinin, 1976; L. H. Thompson et al., 1970). De novo synthesis of double-stranded, fully covalently closed Py DNA has been shown to proceed by semiconservative replication in WT-4 and ts A1S9 cells at the permissive and nonpermissive temperatures. Cell DNA is made late during infection, by both cell types and at both temperatures. Semiconservative replication of cell DNA proceeds in Py-infected WT-4 cells incubated at 34 or at 38.5 C and in Py-infected ts A1S9 cells incubated at 34 C. In virus-infected ts A1S9 cells incubated at 38.5 C, cell DNA synthesis appears to proceed almost entirely by a process analogous to repair replication. The inability of ts A1S9 cells to produce large-molecular-weight chromosomal DNA strands, at 38.5 C, by the normal mechanism is not overcome by Py infection.     

Integration site of polyoma virus DNA in the inducible LPT line of polyoma-transformed rat cells

The structure of the polyoma virus (Py) integration site in the inducible LPT line of Py-transformed rat cells was determined by biochemical methods of gene mapping. LPT cell DNA was digested with various restriction enzymes. The digestion products were electrophoresed in agarose gels and transferred onto nitrocellulose sheets by Southern blotting. Fragments containing viral or cell DNA sequences, or both, were identified by hybridization with Py DNA or with a cloned flanking cell DNA probe. Cleavage of LPT DNA with enzymes that restrict the Py genome once generated linear Py DNA molecules and two fragments containing both cell and viral DNA sequences. Cleavage of LPT DNA with enzymes which do not restrict Py DNA generated series of fragments whose lengths were found to differ by increments of a whole Py genome; the smallest fragment in each series was found to be longer than the viral genome. These data indicate that LPT cultures contain Py insertions of various lengths integrated into the same chromosomal site in all the cells. The length heterogeneity of the viral insertions is due to the presence of 0, 1, 2, 3. . . Py genomes arranged in a direct tandem repeat within invariable sequences of viral DNA. Double-digestion experiments were also carried out with the above enzymes and with enzymes that cleave the Py genome at multiple sites. The data obtained in these experiments were used to construct a physical map of the integration site. This map showed that the early region of the virus remained intact even in the smallest insertion (which contains no whole duplicated genomes), whereas the late region was partially duplicated and split during integration. The smallest insertion is colinear with the Py physical map over a region including the entire Py genome and at least a part of the duplicated segment. This structure could give rise to nondefective circular viral DNA molecules by single homologous recombination events. Similar recombination events may occur at a higher frequency in the longer insertions, which include longer regions of homology, and may yield many more free viral genomes. The presence of these insertions in LPT cells could thus be one of the factors which account for the high inducibility of the LPT line.     

A size analysis of the adenovirus replicon

The linear double-stranded genome of adenovirus DNA replicates semiconservatively from two origins of replication at either of the two molecular ends. Using an in vitro replication system which is able to initiate de novo DNA synthesis we have mapped the origin of DNA replication within the terminal 19 bp of the viral genome. Our conclusions are based on the use of different natural DNA templates, i.e., adenovirus type 2 and mouse adenovirus Fl DNA. In addition, we have employed linearized plasmid DNA templates which contain cloned terminal restriction enzyme fragments as well as chemically synthesized adenovirus termini of different length.     

The NS-1 polypeptide of minute virus of mice is covalently attached to the 5'' termini of duplex replicative-form DNA and progeny single strands.

When A9 cells are infected with minute virus of mice, a small proportion of the virally coded NS-1 polypeptide becomes covalently attached to newly synthesized viral DNA. Antisera directed against NS-1 will specifically precipitate two forms of monomer duplex replicative-form DNA, multimeric duplex intermediates and progeny single strands, and restriction analysis of the duplex forms in these precipitates reveals that NS-1 is exclusively associated with extended-form conformers of the genomic termini. Pulse-labeled viral DNA, harvested at various times in a highly synchronized infection, can be almost quantitatively precipitated with any one of a series of antisera directed against different protein domains distributed throughout the NS-1 molecule but not with antibodies directed against other viral proteins. In each case the interaction with NS-1 can be shown to involve both termini of duplex DNA and single-strand forms, suggesting that in each case a full-length (83-kilodalton) copy of NS-1 is present. Precipitation of the replicating viral DNA with an antibody directed against a synthetic 16-amino-acid peptide containing the sequence at the extreme carboxy terminus of NS-1 can be quantitatively and specifically inhibited with the immunizing peptide in its unconjugated form, showing that the antibodies responsible for precipitating viral DNA are directed against the NS-1 sequence itself and not against a trace contaminant. Exonuclease digestion studies show that the association effectively blocks the 5' ends of the DNA molecules. Very little (less than 0.1%) of the newly synthesized [35S]methionine-labeled NS-1 made in highly synchronized cells during a 15-min pulse early in infection (6.25 to 6.5 h into the S phase) becomes associated with viral DNA immediately. However, pulse-chase experiments show that later in infection (10 to 13 h into the S phase), when viral DNA replication is reaching its peak, a few percent of the molecules in these preexisting pools of NS-1 do become covalently attached to the newly replicated DNA. Isolated viral DNA-protein complexes labeled with [35S]methionine in this way can be obtained by fractionation of the immunoprecipitated complexes on Sepharose CL4B in sodium dodecyl sulfate. Digestion of the purified complexes with nuclease releases an 83-kilodalton molecule which exactly comigrates with authentic NS-1 in sodium dodecyl sulfate-polyacrylamide gels.     

Evidence for supercoiled hepatitis B virus DNA in chimpanzee liver and serum Dane particles: possible implications in persistent HBV infection

In chimpanzee hepatitis B virus (HBV) carriers, the mechanism of viral persistence has been examined by analyzing viral DNA molecules in liver and serum. Chimpanzee liver DNA contained two extrachromosomal HBV DNA molecules migrating on hybridization blots at 4.0 kb and 2.3 kb. There was no evidence for integration of HBV DNA into the host genome. The extrachromosomal molecules were distinct from Dane particle DNA and were converted to linear 3.25 kb full-length double-stranded HBV DNA on digestion with Eco RI. Nucleases S1 and Bal 31 converted "2.3 kb" HBV DNA to 3.25 kb via an intermediate of "4.0 kb" apparent length. The HBV DNA molecule that migrated at 2.3 kb represents a supercoiled form I of the HBV genome, and the molecule that migrated at 4.0 kb represents a full-length "nicked," relaxed circular form II. Evidence for supercoiled HBV DNA in serum Dane particles was obtained by production of form II molecules upon digestion with nuclease S1 or Bal 31. It is proposed that most Dane particles represent interfering noninfectious virus containing partially double-stranded DNA circles and that particles containing supercoiled HBV DNA may represent infectious hepatitis B virus.     

Replication of the Parvovirus MVM II. Isolation and Characterization of Intermediates in the Replication of the Viral Deoxyribonucleic Acid

The time course of the appearance of intracellular viral DNA has been studied in mouse L cells infected with the single-stranded DNA virus MVM (minute virus of mice) by using a selective extraction procedure. Approximately half of this DNA elutes from hydroxyapatite as single-stranded DNA. It is sensitive to Escherichia coli exonuclease I and shows a sedimentation profile similar to DNA from the virus, suggesting that it is progeny viral DNA. The remainder of the selectively extracted DNA elutes from hydroxyapatite in the position of double-stranded DNA and is resistant to exonuclease I. Most of this DNA has a sedimentation coefficient of 14 to 16S, indicating that its molecular weight is twice that of the viral DNA. Denaturation renders the majority of the double-stranded DNA sensitive to exonuclease I, but a significant fraction renatures spontaneously in a monomolecular fashion, indicating that it has a cross-linked or hairpin structure. Chromatography of the double-stranded DNA on benzoylated diethylaminoethyl cellulose resolves two components, one with duplex structure and one which contains single-stranded regions. A short pulse label late in infection predominantly labels the latter class of DNA, suggesting that it contains replicating intermediates. The possible roles of these various forms of DNA in the replication of the viral genome are discussed.     

Simian Virus 40 Deoxyribonucleic Acid Synthesis: the Viral Replicon

Three temperature-sensitive (ts) mutants of simian virus 40 (SV40) in complementation group A (tsA7, tsA28, tsA30) have been isolated and characterized in permissive and restrictive host cells. At 41 C in the AH line of African green monkey kidney cells, the mutants are deficient in an early function required to produce infectious viral deoxyribonucleic acid (DNA). Temperature-shift experiments and analysis of SV40 viral DNA replication by gel electrophoresis have provided strong evidence that the ts gene product of the three mutants is directly required to initiate each new round of viral DNA replication but is not required to complete a cycle which has already begun. The synthesis of mutant DNA molecules themselves can be initiated by a nonmutant gene product in viral complementation studies at 41 C. The cell, however, cannot substitute a host function to provide the initiator required for the replication of free viral DNA. The viral initiator is also required to establish the stable transformation of 3T3 cells.     

Integration of SV40 DNA into the cell genome and viral mutagenesis

Integration of DNA of a temperature-sensitive SV40 mutant (tsA239) into the cell genome was studied. The viral A gene (the oncogene) encodes the tumour T antigen which is ts in the mutant and is devoid of mutagenic and transforming activity under non-permissive conditions (40 degrees C). Clones of Chinese hamster cells infected by tsA239 mutant were analysed. Those infected by wild-type SV40 served as controls. As shown by dot-hybridization, SV40 DNA was detected in cells of 14 out of 18 clones infected by tsA mutant and incubated at 40.5 degrees C, and in all 20 clones infected by tsA mutant and incubated under permissive conditions (33 degrees C), the difference between the two groups being insignificant (p greater than 0.05). By means of blot-hybridization it was established that viral DNA was integrated into the cell genome of all 12 clones analysed, belonging to the three experimental series: infection by tsA mutant, incubation at 40.5 and 33 degrees C, infection by wt SV40, incubation at 40.5 degrees C. The number of integration sites ranged from one to four in different clones. Integration of SV40 DNA in tandems was observed. The data presented allow to conclude that integration per se does not play a crucial role in determining the mutagenic and transforming effect of the virus. Obviously, what matters is the activity of viral oncogene product - the T antigen.     

Segregation of viral double-stranded and single-stranded DNA molecules in nuclei of adenovirus infected cells as revealed by electron microscope in situ hybridization.

Formation of progeny viruses in the nuclei of HeLa cells infected with adenovirus type 5 was studied at the ultrastructural level by in situ hybridization techniques allowing specific detection of either viral double-stranded DNA (dsDNA) or single-stranded DNA (ssDNA). Prior to the initiation of replication of viral genomes, infective DNA molecules which entered the nucleus of the target cell were randomly distributed among host chromatin fibers including nucleolus-associated chromatin. They were double-stranded, that is, without single-strand breaks. Such association of viral DNA with host condensed chromatin also occurred in mitosis. The initiation of viral genome replication occurred simultaneously with the appearance in the nucleoplasm of small fibrillar regions containing intermingled viral dsDNA and ssDNA. Later, at the intermediate stage of nuclear transformation, viral dsDNA and ssDNA molecules were almost entirely separated into two contiguous substructures. At this stage, viruses were observed occasionally in the vicinity of viral ssDNA accumulation sites. Still later, an additional substructure developed in the centre of the nucleus which consisted of large quantities of viral dsDNA, traces of viral ssDNA and abundant viruses. Portions of viral ssDNA were attached to some viruses even at late stage of nuclear transformation, an association which strongly suggests the occurrence of encapsidation of at least some of the viral genomes while they are still engaged in replication.     

Presence of protein at the termini of intracellular adenovirus type 5 DNA.

Adenovirus type 5 contains linear double-stranded DNA with protein covalently attached to the ends of the molecules. The presence of protein at the termini of intracellular viral DNA in adenovirus type 5-infected cells was investigated at different stages during the replication process. The intracellular viral DNA was isolated from the nuclei by lysis in 4 M guanidine hydrochloride. Electrophoresis on agarose gels of HsuI restriction enzyme fragments and sucrose gradient centrifugation were used to detect protein on intracellular viral DNA. After uncoating parental DNA still contains protein attached to the termini of the viral genome. Replicating and mature progeny viral DNA can also be isolated in the form of DNA-protein complexes. These complexes exhibit the same properties as the DNA-protein complex isolated from purified virions. These results suggest that the protein at the termini of intracellular viral DNA is identical to the protein attached to the 5'-ends of the DNA extracted from virions and that it is possibly involved in the replication of viral DNA.     

Tomato Yellow Leaf Curl Virus DNA Forms in the Viral Capside, in Infected Plants and in the Insect Vector

Tomato yellow leaf curl virus (TYLCV) DNA was used as a probe to identify and analyze virus-related DNAs in the viral capside, in infected tomato plants and in the virus vector, the whitefly. In addition to the single-stranded viral genomic DNA, double-stranded virus-related DNA molecules were detected in infected plants. Not all of the virus-related DNA forms are present simultaneously in the infected plant. The double-stranded molecules, which are probably the replicative form of the viral genome, have been purified from an infected tomato plant. In the viruliferous whitefly, only the single-stranded unit-size viral genome was detected.     

Replication Process of the Parvovirus H-1 III. Factors Affecting H-1 RF DNA Synthesis

Replication of the single-stranded DNA parvovirus H-1 involves the synthesis of a double-stranded DNA replicative form (RF). In this study, the metabolism of RF DNA was examined in parasynchronous hamster embryo cells. The initiation of RF DNA replication was found to occur late in S phase, as was the synthesis of the DNA upon which subsequent viral hemagglutinin synthesis is dependent. Evidence is presented which indicates that initiation of RF replication requires proteins synthesized in late S phase, but that concomittant protein synthesis is not required for the continuation of RF replication. The data also suggest a requirement for viral protein(s) for progeny strand synthesis. Incorporation of 5-bromo-2'-deoxyuridine (BUdR) into viral DNA resulted in an "all-or-none" inhibition of viral hemagglutinin and viral antigen synthesis. BUdR inactivation of viral protein function was used to explore the time of synthesis of viral DNA serving as template for viral RNA synthesis and the effect of viral protein on RF replication and progeny strand synthesis. Results of this study suggest that parental RF DNA is synthesized shortly after infection, and that viral mRNA is transcribed from only a few copies of the viral genome in each cell. They also support the conclusion that viral protein is inhibitory to RF DNA replication. Density labeling of RF DNA with BUdR, allowing separation of viral strand DNA (V) from viral complementary strand (C), provided additional data in support of the above findings.     

Defined oligomeric SV40 DNA: A sensitive probe of general recombination in somatic cells

We have constructed well defined oligomeric molecules of simian virus 40 (SV40) DNA as probes for investigating mechanisms by which cultured somatic cells recombine DNA. Restriction enzyme fragments from different temperature-sensitive mutants were joined in a head-to-tail orientation to create partial dimers 1.84 genome lengths in size. These molecules are too large to fit into a viral capsid. Therefore an assay that depends on production of progeny virus after infection with oligomeric DNA is a selective measure of precise conversion of oligomers to monomers. By constructing oligomers from appropriate combinations of temperature-sensitive DNAs, we have been able to study the conversion process in several defined regions of the SV40 genome. Our results indicate that conversion of oligomers to monomers occurs uniformly throughout the genome and is not dependent on normal viral DNA replication. These data indicate that conversion occurs primarily by general, homology-dependent recombination. At least one secondary mechanism that generates a low level of wild-type progeny was also detected. Studies with heteroduplex molecules indicate that repair of mismatched bases may be the secondary mechanism.     

Some properties of chromatin synthesized by mouse-L-cells temperature-sensitive in DNA replication

When ts A1S9 mouse L-cells are incubated at the nonpermissive temperature (38.5 degrees) DNA synthesis proceeds at the normal rate for 6 to 8 h; it then declines to attain 1 to 5% of this rate after 24 h. General protein synthesis from precursor leucine is relatively unaffected by the high temperature. In contrast, protein formation from lysine (and arginine) remains unchanged for 12 to 15 h after temperature upshift. It then drops and plateaus at about 25% of the initial rate after 32 h. The chromatin protein and DNA are fully conserved in ts A1S9 cells incubated at 38.5 degrees for at least 24 h after full expression of the ts defect. Temperature inactivation of the ts A1S9 gene product results in inhibition of de novo formation of chromatin. This is evidenced by coordinate suppression of incorporation of dThd and of lysine and arginine into chromatin-bound DNA and histone, respectively.     

Cloned single- and double-stranded DNA copies of potato spindle tuber viroid (PSTV) RNA and co-inoculated subgenomic DNA fragments are infectious

A set of monomeric and oligomeric potato spindle tuber viroid (PSTV) specific DNA forms representing complete DNA copies of the circular PSTV RNA genome were constructed and cloned in plasmid pBR322 and bacteriophage M13. Both single- and double-stranded PSTV DNAs are capable of initiating viroid replication in mechanically inoculated tomato plants where it normally proceeds via the RNA-RNA pathway without DNA being involved. All dimeric and higher multimeric forms were infectious irrespective of their polarity in the case of single-stranded DNA and regardless of their orientation in the vector DNA in the case of double-stranded DNA. The vector-inserted monomeric PSTV DNA units were also found to be infectious but of low specific infectivity which was increased when these monomers had been excised. Even two subgenomic DNA fragments, representing together the 359 nucleotides of the PSTV RNA genome, initiated the synthesis of viroid RNA progeny when co-inoculated although each fragment by itself is non-infectious. These results are discussed with respect to the infectivity previously observed with certain cloned DNAs of conventional RNA and DNA viruses.     

Homologous recombination of adenovirus DNA in mammalian cells: enhanced recombination following UV-irradiation of the virus.

We have used adenovirus as a molecular probe to examine the recombination of viral DNA following infection of mammalian cells. The technique gives a quantitative measure of homologous recombination between adenovirus type 2 (Ad2) and Ad5PyMTR3. Ad5PyMTR3 is an insertion mutant of Ad5 containing polyoma virus (Py) DNA inserted into a deleted E1 region of the Ad5 genome. Cells were coinfected with Ad2 and Ad5PyMTR3 and at an appropriate time after infection, viral DNA was extracted from the infected cells, digested with restriction endonuclease and electrophoresed through an agarose gel. Although Ad2 and Ad5 have more than 99% DNA homology, they differ sufficiently in their restriction endonuclease patterns, such that recombinant viral DNA molecules containing the Py insert could be detected and quantified by Southern blotting and hybridization to a radioactive Py DNA probe. Using this method we are able to detect and quantitate recombinant viral DNA molecules containing the Py insert which are present at frequencies down to at least 1 in 100. Recombination was detected in Chinese hamster ovary cells, monkey kidney cells, human HeLa cells, normal human fibroblasts and SV40 transformed human fibroblasts. In experiments using HeLa cells, the frequency of recombination between the Py insert on Ad5PyMTR3 and a number of unique restriction enzyme sites on Ad2 increased with the distance from the Py insert to the restriction site. Also in HeLa cells, recombination increased with increasing amounts of viral DNA synthesis and with increasing UV dose to the virus. UV-irradiation of both coinfecting viruses with 1500 J/m2 resulted in a more than 100-fold reduction in the amount of viral DNA synthesized and about a 3-fold increase in the frequency of recombination.     

Recombinational-type transfer of viral DNA during bacteriophage 2C replication in Bacillus subtilis.

The Bacillus subtilis phage 2C contains one molecule of double-stranded DNA of about 100 x 10(6) daltons in which thymine is replaced by hydroxymethyluracil; the two strands have different buoyant densities. Parental DNA, labeled with either [3H]uracil of [32P]phosphate, was quite effectively transferred to offspring phage, and the efficiency of transfer was the same for the two strands. Labeled nucleotide compositions of the H and L strands from parental and progeny virions were very close. These data exclude a degradation of the infecting DNA and reutilization of nucleotides. Upon infection of light unlabeled cells with heavy radioactive viruses, no DNA with either heavy or hybrid density was extracted from offspring phage. Instead, an heterogeneous population of DNA molecules of densities ranging from that of almost hybrid to that of fully light species was obtained. Shear degradation of such progeny DNA to fragments of decreasing molecular weight produced a progressive shift to the density of hybrid molecules. Denaturation of sheared DNA segments caused the appearance of labeled and heavy single-stranded segments. These findings indicate that 2C DNA replicates semiconservatively and then undergoes extensive genetic recombination with newly formed viral DNA molecules within the vegatative pool, thus mimicking a dispersive transfer of the infecting viral genome. The pieces of transferred parental DNA have an average size of 10 x 10(6) daltons.     

Tracking adenovirus genomes identifies morphologically distinct late DNA replication compartments

In adenoviral virions, the genome is organized into a chromatin‐like structure by viral basic core proteins. Consequently viral DNAs must be replicated, chromatinized and packed into progeny virions in infected cells. Although viral DNA replication centers can be visualized by virtue of viral and cellular factors, the spatiotemporal regulation of viral genomes during subsequent steps remains to be elucidated. In this study, we used imaging analyses to examine the fate of adenoviral genomes and to track newly replicated viral DNA as well as replication‐related factors. We show de novo formation of a subnuclear domain, which we termed Virus‐induced Post‐Replication (ViPR) body, that emerges concomitantly with or immediately after disintegration of initial replication centers. Using a nucleoside analogue, we show that viral genomes continue being synthesized in morphologically distinct replication compartments at the periphery of ViPR bodies and are then transported inward. In addition, we identified a nucleolar protein Mybbp1a as a molecular marker for ViPR bodies, which specifically associated with viral core protein VII. In conclusion, our work demonstrates the formation of previously uncharacterized viral DNA replication compartments specific for late phases of infection that produce progeny viral genomes accumulating in ViPR bodies.