Formation and structure of infectious DNA of spleen necrosis virus.

The kinetics of formation and the structure of infectious DNA of spleen necrosis virus were determined. Nonintegrated infectious viral DNA first appeared 18 to 24 h after infection of dividing cells and persisted for more than 14 days. The nonintegrated infectious viral DNA was in the form of either a double-stranded linear DNA with a molecular weight of 6 X 10(6), detected in both the cytoplasm and nucleus, or a closed circular DNA of the same molecular weight, detected primarily in the nucleus. Integrated infectious viral DNA appeared soon after the nonintegrated infectious viral DNA and was the predominant form of infectious viral DNA late after infection. Integration of the spleen necrosis virus DNA into the chicken cell genome was demonstrated by three independent criteria. Nucleic acid hybridization indicated that the linear infectious viral DNA had a 5- to 10-fold higher specific infectivity than either the closed circular or integrated infectious viral DNA. Infectious viral DNA did not appear in infected stationary cells, indicating some cellular influence on the formation of infectious viral DNA.     

Restriction endonuclease cleavage of linear and closed circular murine leukemia viral DNAs: discovery of a smaller circular form.

Both linear (form III) and closed circular (form I) viral DNAs obtained from mouse cells infected with Moloney murine leukemia virus were cleaved by Sal I, Sma I, Bam HI and Pst I restriction endonucleases. DNA fragments generated by these cleavages were ordered with respect to the 5' and 3' ends of the RNA genome by several techniques, including comparisons of the DNA fragments from cleavages of the linear and closed circular forms, double digestions using different combinations of enzymes and the use of an RNA probe specific for the 3' end. DNA from Hirt extractions of infected cells yielded a discrete species of linear viral DNA whose size was determined by agarose gel electrophoresis to be 5.7 x 10(6) daltons. In the course of characterizing the closed circular DNA, we observed two form I DNA molecules. The larger molecule was the same size as the linear DNA. The second molecule migrated faster on agarose gels and was the predominant species of the two closed circular DNAs. Using the restriction endonuclease maps which we derived, we demonstrate that this novel form I DNA is a smaller homogeneous species of viral DNA, missing about 600 nucleotides found in the linear and larger closed circular DNA molecules. We have localized the site of this missing DNA piece to be at either one or both ends of the linear viral DNA.     

Virus-specific DNA in the cytoplasm of avian sarcoma virus-infected cells is a precursor to covalently closed circular viral DNA in the nucleus.

Three principal forms of viral DNA have been identified in cells infected with avian sarcoma virus: (i) a linear duplex molecule synthesized in the cytoplasm, (ii) a covalently closed circular molecule found in the nucleus, and (iii) proviral DNA covalently linked to high-molecular-weight cell DNA. To define precursor product relationships among these forms of viral DNA, we performed pulsechase experiments using 5-bromodeoxyuridine to label by density the linear species of viral DNA in the cytoplasm during the first 4 h after infection. After a 4-to 8-h chase with thymidine, a portion of the density-labeled viral DNA was transported to the nucleus and converted to a covalently closed circular form. We conclude that linear viral DNA, synthesized in the cytoplasm, is the precursor to closed circular DNA observed in the nucleus.     

Physical map of biologically active Harvey sarcoma virus unintegrated linear DNA.

BALB/c JLS V9 cells recently infected with Harvey sarcoma virus-murine leukemia virus (HSV-MuLV) complex contained unintegrated HSV linear DNA of 6.0-kilobase pair mass. The cells also contained two HSV closed circular DNA species along with MuLV-encoded linear and closed circular DNA species. HSV 6.0-kilobase pair linear DNA induced focal transformation upon transfection of NIH 3T3 mouse fibroblasts, and the biological activity of HSV DNA did not require helper MuLV functions. A physical map of restriction endonuclease cleavage sites along HSV 6.0-kilobase pair linear DNA was derived. Comparison of this map with one for Moloney MuLV DNA showed that the HSV and Moloney MuLV genomes are identical near their viral RNA 3' ends.     

Covalently closed circles of human adenovirus DNA are infectious

Replication of the linear adenovirus DNA molecule is thought to result from semiconservative synthesis off linear templates, starting from origins at either end of the genome. Recently, however, it has been shown that in cells infected with adenovirus type 5 (Ad5) a significant fraction of the ends of viral DNA molecules become joined head-to-tail due at least in part to the formation of covalently closed circles. Circular DNA is not present in virions but joining of the ends of viral DNA is detectable shortly after infection, well before the onset of viral DNA replication. To learn more about the structure and possible function of these circular forms of viral DNA, I have cloned Ad5 circles as plasmids replicating in Escherichia coli. Two plasmids have been analyzed in detail and shown to generate infectious virus with an efficiency comparable with that of virion DNA following transfection into human cells. These results suggest that circles are not totally inert or functionless but that, once formed, they are capable of re-entering the pool of replicating molecules to generate linear progeny.     

Effect of Fv-1 gene product on synthesis of linear and supercoiled viral DNA in cells infected with murine leukemia virus.

Levels of unintegrated viral DNA made in Fv-1b/b (SIM.R, JLS-V9) and Fv-1n/n (NIH/3T3) cell lines after infection with N- or B-tropic murine leukemia virus (MuLV) have been measured. Different forms of viral DNA were sedimented on neutral sucrose or ethidium bromide-cesium chloride density gradients and detected by hybridization with complementary DNA. It was found that the major viral DNA species made in Fv-1 permissive or resistant cells was sedimenting at 20S on neutral sucrose gradient. Levels of this 20S viral DNA species were not significantly different in both systems. However levels of closed circular (form I) viral DNA separated on ethidium bromide-cesium chloride gradients were found to be decreased in Fv-1 resistant cells. Various species of viral DNA were also analyzed by the agarose gel-DNA transfer procedure of Southern. The major viral DNA species was found to migrate as a double-stranded linear DNA of 5.7 x 10(6) daltons. The molecular weight of linear viral DNA molecules extracted from Fv-1 permissive or resistant cells appeared to be the same. Levels of this linear viral DNA were almost identical in both systems except in B-tropic MuLV-infected resistant NIH/3T3 cells in which a moderate decrease has been measured. Two closed circular viral DNA species were observed by this technique. Their levels were markedly decreased in Fv-1 resistant cells. Our results indicate that the Fv-1 restriction does not grossly affect the formation of linear double-stranded viral DNA, but prevents the accumulation of closed circular viral DNA. Therefore the Fv-1 gene product could allow the synthesis of a normal linear viral DNA but interfere with the formation of supercoiled viral DNA. Alternatively, it could promote the synthesis of a faulty linear viral DNA whose defect (yet undetected) would prevent its circularization. In any case, the Fv-1 restriction mechanism appears to occur before the integration event itself.     

In vitro synthesis of a 9 kbp terminally redundant DNA carrying the infectivity of Moloney murine leukemia virus.

Detergent-disrupted virions of Moloney murine leukemia virus synthesize a 9 kbp double-stranded infectious DNA. It contains mainly full-length, single-stranded DNA, and its infectivity and size are insensitive to digestion by the single-strand-specific S1 nuclease. Analysis of fragmentation of the DNA using restriction endonucleases has shown that it is indistinguishable from the linear double-stranded DNA synthesized in infected cells. On the basis of the positions of the cleavage sites for a number of enzymes, the 9 kbp DNA has a 575 base direct terminal repetition. It is longer than the viral RNA at both ends, evidently due to repetitive copying of segments of the RNA. Virions also synthesize an 8.4 kbp double-stranded circular DNA that lacks one copy of the terminal repetition, as well as viral DNA longer than 9 kbp. The enzymatic machinery in the virions of retroviruses therefore appears to be responsible for all the steps involved in making fully double-stranded linear and one form of circular DNA.     

Physical map of infectious baboon type C viral DNA and sites of integration in infected cells.

Three species of unintegrated viral DNAs were found in permissive cells infected with baboon type C virus. The major species was a 9.0-kilobase (kb) linear DNA that was infectious. A restriction endonuclease map of this DNA was constructed and oriented with respect to the viral RNA. The linear DNA had a 0.6-kb sequence repeated at each terminus. These terminal repeat sequences were required for infectivity of the viral DNA. The minor species of the unintegrated viral DNAs were covalently closed circles of 9.0 and 8.4 kb. The smaller circle was in two- to threefold excess over the larger circle. The difference appeared to be that the smaller circle lacked one of the two 0.6-kb repeat sequences found in the larger circle. Restriction endonuclease maps of the integrated viral DNAs were constructed, and the sequences on both viral DNA and cellular DNA that are involved in integration were determined. The integrated viral DNA map was identical to that of the unintegrated infectious 9.0-kb linear DNA. Therefore, a specific site in the terminal repeat sequence of the viral DNA was used to integrate with the host cell DNA. The sizes of the cellular DNA fragments were different from clone to clone but stable with cell passage. Therefore, many sites in the cell DNA can recombine with the viral DNA.     

Circular Herpesvirus sylvilagus DNA in spleen cells of experimentally infected cottontail rabbits.

Cottontail rabbits (Sylvilagus floridanus) were infected with Herpesvirus sylvilagus, and spleen cells were analyzed for the presence of virus-specific, covalently closed circular, and linear DNA molecules by a simple electrophoretic technique, followed by transfer to nitrocellulose filters and hybridization with cloned viral DNA (Gardella et al., J. Virol. 50:248-254, 1984). Approximately 0.2 copies per cell of circular DNA and 0.2 copies per cell of linear DNA were detected by hybridization with a cloned viral DNA fragment. The size of the viral DNA was estimated at ca. 158 kilobase pairs. Restriction endonuclease patterns suggested structural similarities to cottontail herpesvirus DNA.     

The circular intracellular form of Epstein-Barr virus DNA is amplified by the virus-associated DNA polymerase.

Selective DNA extraction and hybridization procedures were used to estimate the relative number of covalently closed circular viral genomes in cultures of Epstein-Barr virus (EBV)-transformed cells. In virus-producing P3HR-1 cultures that were exposed for 11 days to phosphonoacetic acid or to acyclovir, the content of covalently closed circular EBV DNA was reduced ca. 70% relative to a control culture without drug. The EBV plasmid content of Raji, a virus nonproducer cell line, was not reduced by exposure to these compounds. When P3HR-1 cultures were exposed to 12-O-tetradecanoylphorbol-13-acetate, the number of circular genomes per cell increased. These findings indicate that two enzyme activities synthesize circular EBV DNA and that the virus-associated DNA polymerase synthesizes most of the circular EBV DNA in a virus producer culture. It is suggested that the circular genomes synthesized by the viral enzyme are intermediates in the syntheses of linear virus DNA.     

Covalently closed circular duplex DNA of Epstein-Barr virus in a human lymphoid cell line.

A non-integrated form of Epstein-Barr virus DNA was purified from the Burkitt lymphoma-derived human lymphoid cell line Raji by CsCl density gradient centrifugation and neutral glycerol gradient centrifugation. This intracellular form of the virus DNA sediments at a rate typical of a covalently closed circular DNA molecule of the size of the virus genome in both neutral and alkaline solution. Treatment with low doses of X-rays leads to a discontinuous conversion of the molecules to a form with the sedimentation properties of open circular DNA (a circular duplex molecule containing one or more single-strand breaks). The direct observation of large circular DNA molecules by electron microscopy further confirms the covalently closed circular duplex structure of part of the intracellular viral DNA. Such circular molecules were not detected in corresponding DNA fractions from Epstein-Barr virus-negative human lymphoid cell lines. In ethidium bromide/CsCl density gradient centrifugation experiments, the purified non-integrated virus DNA behaves as twisted, covalently closed DNA circles with the same initial superhelix density as polyoma virus DNA. The latter additional purification technique permits the isolation of intracellular Epstein-Barr virus DNA in > 90% pure form from non-producer cells. The molecular weight of the circular virus DNA from Raji cells, determined by contour length measurements, is the same within experimental error as that of the linear DNA from virus particles.     

Fate of Unintegrated Viral DNA in Fv-1 Permissive and Resistant Mouse Cells Infected with Murine Leukemia Virus

We have found that levels of unintegrated linear viral DNA were nearly identical in several Fv-1 resistant cell lines, whereas levels of closed circular viral DNA are markedly reduced in these resistant cells, to the same extent as virus production (P. Jolicoeur and E. Rassart, J. Virol. 33:183-195, 1980). To determine the fate of linear viral DNA made in resistant cells we performed pulse-chase experiments, labeling viral DNA with 5-bromodeoxyuridine and following it with a thymidine chase. 5-Bromodeoxyuridine-labeled viral DNA (HH) recovered by banding on cesium chloride gradients was sedimented on neutral sucrose density gradients or separated by the agarose gel-DNA transfer procedure and detected by hybridization with complementary DNA. Levels of linear viral DNA made in Fv-1^b/b (JLS-V9 and SIM.R) and Fv-1^n/n (NIH/3T3 and SIM) cells were found to decrease during the chase period at about the same rate in permissive and nonpermissive conditions, indicating that linear viral DNA is not specifically degraded in Fv-1 resistant cells. Levels of the two species of closed circular viral DNA made in Fv-1 permissive cells increased relative to the levels of linear DNA during the chase period. This confirmed the precursor-product relationship between linear DNA and the two species of circular DNA. In Fv-1 resistant cells, this apparent conversion of linear viral DNA into circular forms was not seen, and no supercoiled viral DNA could be detected. To determine whether the transport of linear viral DNA from the cytoplasm into the nucleus was prevented by the Fv-1 gene product, SIM.R cells were fractionated into cytoplasmic and nuclear fractions, and viral DNA was detected in each fraction by the agarose gel-DNA transfer procedure. Levels of linear viral DNA were nearly identical in both cytoplasmic and nuclear fractions of permissive or resistant cells. Circular viral DNA could be detected in the nuclear fraction of permissive cells, but not in that of resistant cells. A pulse-chase experiment was also performed with SIM.R cells. During the thymidine chase period, linear viral DNA was seen to accumulate in nuclei of both permissive and resistant cells, whereas supercoiled viral DNA accumulated only in nuclei of permissive cells. These results indicate that the Fv-1 gene product does not interfere with the transport of linear viral DNA into the nucleus. Our data also suggest that the Fv-1 restriction does not operate through a degradation process. Therefore, the Fv-1 gene product could either block the circularization of linear viral DNA directly or promote the synthesis of a faulty linear viral DNA whose defect (yet undetected) would prevent its circularization.     

Type I DNA topoisomerases from mammalian cell nuclei interlock strains and promote renaturation of denatured closed circular PM2 DNA

Type I DNA topoisomerases from mouse ascites cell nuclei and from rat liver cell nuclei act on denatured viral closed circular PM2 DNA to produce molecules with a highly contracted structure as well as fully duplex non-supercoiled covalently closed circular molecules. Highly contracted DNA molecules contain a novel type of topological linkage in which a strand in one region of the double-stranded molecule passes between the strands in another region of the circular molecule one or more times. Since it is also found that the action of the topoisomerase promotes renaturation of complementary strands in denatured closed circular DNA, it is suggested that formation of contracted DNA structures proceeds through renatured, duplex intermediates with highly negative superhelix densities that contain small single-stranded regions.     

Restriction endonuclease mapping of unintegrated viral DNA of B- and N-tropic BALB/c murine leukemia virus.

Unintegrated linear and closed circular DNAs of B- and N-tropic endogenous BALB/c murine leukemia virus (MuLV) were extracted from newly infected mouse cells and cleaved with EcoRI, XhoI, PvuI, HindIII, SalI, XbaI, KpnI, SmaI, and PstI restriction endonucleases. The DNA fragments were separated by electrophoresis and analyzed by the Southern blot hybridization procedure. EcoRI did not cleave the two genomes. A physical map of 15 cleavage sites on B- and N-tropic genomes was constructed with the other restriction endonucleases. Identical cleavage sites of B- and N-tropic MuLV DNAs were found with all these enzymes. However, the N-tropic linear genome was found to lack about 75 base pairs at each end of the molecule. PstI, KpnI, and SmaI recognize a cleavage site at both ends of the linear molecules. And sequences derived from the 5' end of the RNA genome were found in the third left end of the linear DNA and at its extreme right-end terminus, suggesting the presence of redundant sequences. Two species of closed circular viral DNA were observed. The larger species has the same size as the linear molecule and appears to be a circularized form of linear DNA. The smaller species contains sequences common to both the linear and the larger circular viral DNA but seems to be deleted from sequences present at either one or both ends of the linear DNA. Therefore, the general structure of the linear and circular DNA species of these B- and N-tropic endogenous BALB/c MuLV appears analogous to the structure found with other retroviruses.     

Covalently closed circular DNAs of murine type C retrovirus: depressed formation in cells treated with cycloheximide early after infection.

Formation of viral closed circular supercoiled DNA duplexes and production of progeny virus were both inhibited in cultured mouse cells treated with cycloheximide in the first 4 h of type C retrovirus infection. With different doses of cycloheximide to cause different degrees of inhibition, the number of viral supercoiled DNA duplexes detected in the cells at 11 h showed an apparent correlation with the amount of progeny virus produced in the 12- to 22-h period of infection. A slight accumulation of the full-genome linear duplex and an open circular duplex of viral DNA intermediate was observed in the cycloheximide-treated cells. Cycloheximide given to the cells during the time of conversion of viral DNA from linear to supercoiled duplex forms (6 to 11 h after virus inoculation) did not inhibit the conversion. These kinetic data suggest that a cycloheximide-sensitive metabolic process, probably early viral protein synthesis, is required for retrovirus replication and supercoiled viral DNA formation in the cell.     

DNA replication in bacteriophage-infected Staphylococcus aureus.

The synthesis of viral and host DNA in phage-infected Staphylococcus aureus was examined. Three intracellular forms of phage 52HJD DNA were demonstrated: covalently closed circular, open circular, and linear DNA species. It was noted that infection of S. aureus-propagating strains 81 and 52 with phage 52HJD inhibited the replication of the bacterial chromosome and a stringently controlled penicillinase plasmid. A small tetracycline plasmid, normally under relaxed replication control, continued to replicate in the postinfection period. No breakdown of the host chromosome into small-molecular-weight fragments or utilization of bacterial DNA material for the synthesis of viral DNA was observed.     

Physical and topological properties of circular DNA

Several types of circular DNA molecules are now known. These are classified as single-stranded rings, covalently closed duplex rings, and weakly bonded duplex rings containing an interruption in one or both strands. Single rings are exemplified by the viral DNA from φX174 bacteriophage. Duplex rings appear to exist in a twisted configuration in neutral salt solutions at room temperature. Examples of such molecules are the DNA''s from the papova group of tumor viruses and certain intracellular forms of φX and λ-DNA. These DNA''s have several common properties which derive from the topological requirement that the winding number in such molecules is invariant. They sediment abnormally rapidly in alkaline (denaturing) solvents because of the topological barrier to unwinding. For the same basic reason these DNA''s are thermodynamically more stable than the strand separable DNA''s in thermal and alkaline melting experiments. The introduction of one single strand scission has a profound effect on the properties of closed circular duplex DNA''s. In neutral solutions a scission appears to generate a swivel in the complementary strand at a site in the helix opposite to the scission. The twists are then released and a slower sedimenting, weakly closed circular duplex is formed. Such circular duplexes exhibit normal melting behavior, and in alkali dissociate to form circular and linear single strands which sediment at different velocities. Weakly closed circular duplexes containing an interruption in each strand are formed by intramolecular cyclization of viral λ-DNA. A third kind of weakly closed circular duplex is formed by reannealing single strands derived from circularly permuted T2 DNA. These reconstituted duplexes again contain an interruption in each strand though not necessarily regularly spaced with respect to each other.     

Separation of closed circular DNA from linear DNA by electrophoresis in two dimensions in agarose gels

A method that provides an easy, rapid, and reproducible way for separating closed circular DNA species from linear DNA and nicked circles is described. The method is based on the difference in mobility of form I (supercoiled) DNA and form II (nicked circles), and the differential mobility of relaxed circular DNA in the presence and absence of ethidium bromide (EtdBr). It can be used for detection or for purification of plasmid, episomal, or viral DNA from the bulk of cellular DNA, or from other DNA mixtures.     

Previously unknown virus infects marine diatom

Diatoms are a major phytoplankton group that play important roles in maintaining oxygen levels in the atmosphere and sustaining the primary nutritional production of the aquatic environment. Among diatoms, the genus Chaetoceros is one of the most abundant and widespread. Temperature, climate, salinity, nutrients, and predators were regarded as important factors controlling the abundance and population dynamics of diatoms. Here we show that a viral infection can occur in the genus Chaetoceros and should therefore be considered as a potential mortality source. Chaetoceros salsugineum nuclear inclusion virus (CsNIV) is a 38-nm icosahedral virus that replicates within the nucleus of C. salsugineum. The latent period was estimated to be between 12 and 24 h, with a burst size of 325 infectious units per host cell. CsNIV has a genome structure unlike that of other viruses that have been described. It consists of a single molecule of covalently closed circular single-stranded DNA (ssDNA; 6,005 nucleotides), as well as a segment of linear ssDNA (997 nucleotides). The linear segment is complementary to a portion of the closed circle creating a partially double-stranded genome. Sequence analysis reveals a low but significant similarity to the replicase of circoviruses that have a covalently closed circular ssDNA genome. This new host-virus system will be useful for investigating the ecological relationships between bloom-forming diatoms and other viruses in the marine system. Our study supports the view that, given the diversity and abundance of plankton, the ocean is a treasury of undiscovered viruses.     

Infectious circular DNA of human adenovirus type 5: regeneration of viral DNA termini from molecules lacking terminal sequences.

A series of plasmids containing the entire human adenovirus genome with viral DNA termini joined 'head to tail' has been isolated. Several plasmids were able to generate infectious virus following transfection of human cells in spite of having small deletions and rearrangements at the junctions of termini. One plasmid has lost 2 bp of DNA from one end of the viral genome and 11 bp from the other end yet produced viruses with complete wild-type sequences at both ends of the genome. We propose a model for replication of viral DNA off circular templates in which regeneration of terminal information involves translocation of primer and polymerase during initiation of DNA replication. The model suggests a novel mechanism for extension of the 5' ends of linear DNA molecules which could be applicable to chromosomal telomeres.