Characterization of a metastable, partially replicated dimeric intermediate of minute virus of mice

Intracellular, replicative-form DNA of minute virus of mice was characterized by agarose gel electrophoresis, velocity sedimentation, electron microscopy, restriction endonuclease digestion, and sensitivity to the single-stranded nuclease S1. This analysis demonstrated the presence in murine cells infected with minute virus of mice of a 10.0-kilobase pair dimer replicative form, a 5-kilobase pair monomer replicative form, as well as a 5-kilobase viral single-stranded DNA species. Two additional viral DNA species that migrated in 0.5% agarose gels with apparent sizes of 8.0 and 5.5 kilobase pairs were also observed. Further investigation indicated that the 8.0-kilobase pair DNA represents a novel class of metastable, partially replicated, dimeric intermediates. This finding has important implications for the mechanism of parvovirus DNA replication.     

Unidirectional replication as visualized by two-dimensional agarose gel electrophoresis

Two-dimensional (2D) agarose gel electrophoresis is progressively replacing electron microscopy as the technique of choice to map the initiation and termination sites for DNA replication. Two different versions were originally developed to analyze the replication of the yeast 2 microns plasmid. Neutral/Neutral (N/N) 2D agarose gel electrophoresis has subsequently been used to study the replication of other eukaryotic plasmids, viruses and chromosomal DNAs. In some cases, however, the results do not conform to the expected 2D gel patterns. In order to better understand this technique, we employed it to study the replication of the colE1-like plasmid, pBR322. This was the first time replicative intermediates from a unidirectionally replicated plasmid have been analyzed by means of N/N 2D agarose gel electrophoresis. The patterns obtained were significantly different from those obtained in the case of bidirectional replication. We showed that identification of a complete are corresponding to molecules containing an internal bubble is not sufficient to distinguish a symmetrically located bidirectional origin from an asymmetrically located unidirectional origin. We also showed that unidirectionally replicated fragments containing a stalled fork can produce a pattern with an inflection point. Finally, replication appeared to initiate at only some of the potential origins in each multimer of pBR322 DNA.     

Size distribution of DNA replicative intermediates in bacteriophage P4 and in Escherichia coli.

We have tested the hypothesis that Okazaki fragment replicative intermediates have defined termini using as a model system the in vivo DNA replication of the tiny bacteriophage P4. The kinetics of formation of intermediates in P4 DNA replication have been investigated. P4 DNA replication in DNA polymerase I-deficient mutants generates Okazaki fragments with a size distribution similar to that in uninfected cells. When P4-derived Okazaki fragments are resolved by agarose gel electrophoresis, no discrete size classes appear. This finding is incompatible with sequence-specific models of Okazaki fragment formation but supports the view that these replication intermediates are initiated and terminated at random locations on the P4 chromosome.     

The Epstein-Barr virus origin of plasmid replication, oriP, contains both the initiation and termination sites of DNA replication

Epstein-Barr virus (EBV) oriP contains two components, a dyad symmetry element and a direct repeat element, that, in the presence of EBV nuclear antigen 1, are necessary and sufficient for plasmid replication. We have examined the replicative forms generated by EBV oriP using 2D gel electrophoresis. The patterns obtained from an oriP plasmid in a transfected cell line indicate that the site of initiation of DNA replication is at or very near the dyad symmetry element, while the direct repeats contain a replication fork barrier and the termination site. Thus, replication from oriP proceeds in a predominantly undirectional manner. The patterns obtained from cells immortalized by EBV suggest that replication from oriP proceeds similarly in the viral genome.     

Branched structures in the intracellular DNA of herpes simplex virus type 1.

Herpes simplex virus type 1 (HSV-1) replication produces large intracellular DNA molecules that appear to be in a head-to-tail concatemeric arrangement. We have previously suggested (A. Severini, A.R. Morgan, D.R. Tovell, and D.L.J. Tyrrell, Virology 200:428-435, 1994) that these DNA species may have a complex branched structure. We now provide direct evidence for the presence of branches in the high-molecular-weight DNA produced during HSV-1 replication. On neutral agarose two-dimensional gel electrophoresis, a technique that allows separation of branched restriction fragments from linear fragments, intracellular HSV-1 DNA produces arches characteristic of Y junctions (such as replication forks) and X junctions (such as merging replication forks or recombination intermediates). Branched structures were resolved by T7 phage endonuclease I (gene 3 endonuclease), an enzyme that specifically linearizes Y and X structures. Resolution was detected by the disappearance of the arches on two-dimensional gel electrophoresis. Branched structures were also visualized by electron microscopy. Molecules with a single Y junction were observed, as well as large tangles containing two or more consecutive Y junctions. We had previously shown that a restriction enzyme which cuts the HSV-1 genome once does not resolve the large structure of HSV-1 intracellular DNA on pulsed-field gel electrophoresis. We have confirmed that result by using sucrose gradient sedimentation, in which both undigested and digested replicative intermediates sediment to the bottom of the gradient. Taken together, our experiments show that the intracellular HSV-1 DNA is held together in a large complex by frequent branches that create a network of replicating molecules. The fact that most of these branches are Y structures suggests that the network is held together by frequent replication forks and that it resembles the replicative intermediates of bacteriophage T4. Our findings add complexity to the simple model of rolling-circle DNA replication, and they pose interesting questions as to how the network is formed and how it is resolved for packaging into progeny virions.     

Structural organization of human simian virus 40 chromosomes. I. Heterogeneity and composition of nuclear DNA-protein complexes at different stages of lytic infection

Extraction of the purified nuclei of SV40 infected cells reveals a heterogeneous set of viral DNA-protein complexes. Earlier, the authors have shown the possibility of nuclear particles extraction being indistinguishable from mature SV40 virions. In the present work, structural intermediates of virus maturation from free minichromosomes through replicative complexes to immature virion particles have been analyzed. The fractionation of viral complexes by non-denaturing agarose gel electrophoresis has been employed. The protein composition of the complexes as determined by two-dimensional gel electrophoresis indicates that five histone fractions including H1 are present during minichromosome maturation to the chromosome of the mature virion.     

Mitochondrial DNA recombination in Brassica campestris

The structure of the mitochondrial genome in plants is unclear, but appears to consist of mostly linear DNA with some other structures, including branched molecules and subgenomic circles. Mitochondrial DNA (mtDNA) recombination was analyzed in Brassica campestris, which has one of the smallest mitochondrial genomes (218 kb) in higher plants. Field-inversion gel electrophoresis (FIGE) separated mtDNA into discrete populations that each represents the entire genome. Electron microscopy revealed large, mostly linear molecules trapped in the wells, slower migrating populations with mostly linear DNA and a low level of circular and networked mtDNA molecules of 10–140 kbp, and a fast migrating population of 10–50 kbp linear mtDNA. Some smaller than genome size circular molecules and circles with tails were observed, and may represent recombination or rolling circle replication intermediates. Hybridization of end-labeled mtDNA suggests there may be specific ends (or recombination hotspots) for some linear molecules. Analysis of mtDNA enriched by BND-cellulose and separated by two-dimensional agarose gel electrophoresis shows the presence of complex recombination structures and the presence of significant single-stranded regions in mtDNA. These findings provide further evidence that DNA recombination contributes to the complex structure of mtDNA in plants.     

Bi-directional replication and random termination

Two-dimensional (2D) agarose gel electrophoresis was used to study termination of DNA replication in a shuttle vector, YRp7′, when it replicated in Escherichia coli, Saccharomyces cerevisiae and Xenopus egg extracts. In E.coli, the 2D gel patterns obtained were consistent with uni-directional replication initiated at a specific site, the ColE1 origin. In consequence, termination also occurred precisely at the ColE1 origin. In Xenopus egg extracts, the particular shape of the bubble arc as well as the triangular smear detected to the left of the simple-Y pattern indicated random initiation and termination. In S.cerevisiae, initiation occurred at the ARS1 origin and replication proceeded in a bi-directional manner. However, termination did not always occur at a specific site 180° across from the origin, but almost all along the south hemisphere of the plasmid. Inversion, deletion or replacement of DNA sequences located throughout this hemisphere did not eliminate random termination. Analysis of the replication intermediates of another yeast plasmid bearing a different origin, ARS305, also exhibited random termination. We propose that the random termination events observed in S.cerevisiae could be due to an asynchronous departure of both forks from the bi-directional origin in addition to differences in the rate of fork progression. These observations could be extended to all bi-directional origins.     

Resolution of vaccinia virus DNA concatemer junctions requires late-gene expression.

Vaccinia virus replicates in the cytoplasm of infected cells, generating transient replicative intermediates containing the DNA for the terminal sequences as concatemeric junctions. The processing of the terminal sequences for a series of vaccinia virus conditional lethal mutants at the nonpermissive temperature was analyzed by restriction enzyme digestion and Southern blot hybridization of DNA isolated from infected cells. Three phenotypes were observed: DNA replication negative (Rep-), DNA replication positive but concatemer resolution negative (Rep+ Res-), and DNA replication positive and concatemer resolution positive (Rep+ Res+). Interestingly, all six Rep+ Res- mutants from separate complementation groups were defective in late protein synthesis. Isatin beta-thiosemicarbazone, a drug that blocks late protein synthesis, also prevented resolution of concatemers. Orthogonal field gel electrophoresis of the DNA generated by the late defective mutants revealed a distribution of linear genome multimers. The multimers were processed into mature monomers after a shift to the permissive temperature in the presence of cytosine arabinoside for all the Rep+ Res- mutants except ts22, an irreversible mutant which cleaves RNA late in infection (R.F. Pacha and R.C. Condit, J. Virol. 56:395-403, 1985). Genome formation can be divided into two stages: DNA replication, which generates concatemers, and resolution, which processes concatemers into monomers with hairpin termini. Early viral genes are required for the former, and late viral genes are required for the latter.     

Looping‐out mechanism for resolution of replicative stress at telomeres

Repetitive DNA is prone to replication fork stalling, which can lead to genome instability. Here, we find that replication fork stalling at telomeres leads to the formation of t‐circle‐tails, a new extrachromosomal structure that consists of circular telomeric DNA with a single‐stranded tail. Structurally, the t‐circle‐tail resembles cyclized leading or lagging replication intermediates that are excised from the genome by topoisomerase II‐mediated cleavage. We also show that the DNA damage repair machinery NHEJ is required for the formation of t‐circle‐tails and for the resolution of stalled replication forks, suggesting that NHEJ, which is normally constitutively suppressed at telomeres, is activated in the context of replication stress. Inhibition of NHEJ or knockout of DNA‐PKcs impairs telomere replication, leading to multiple‐telomere sites (MTS) and telomere shortening. Collectively, our results support a “looping‐out” mechanism, in which the stalled replication fork is cut out and cyclized to form t‐circle‐tails, and broken DNA is religated. The telomere loss induced by replication stress may serve as a new factor that drives replicative senescence and cell aging.     

Evidence that replication initiates at only some of the potential origins in each oligomeric form of bovine papillomavirus type 1 DNA.

In a subclone of ID13 mouse fibroblasts latently infected with bovine papillomavirus type 1 (BPV-1) DNA, the viral genome occurred as a mixture of extrachromosomal circular monomers and oligomers. Multiple copies were also associated with the host cell genome, predominantly at a single site in a head-to-tail tandem array. We examined the replicative intermediates of extrachromosomal forms of BPV-1 DNA by using two-dimensional gel electrophoresis. The results obtained indicate that initiation of DNA replication occurred near the center of the EcoRI-BamHI 5.6-kilobase fragment. In some molecules, however, this fragment was replicated from one end to the other by means of a single fork initiated elsewhere. Termination also occurred within this fragment. The EcoRI-BamHI 2.3-kilobase fragment replicated as a DNA molecule containing a termination site for DNA replication and also by means of a single fork traversing the fragment from one end to the other. Thus, replication forks proceeded through these fragments in different manners, apparently depending on whether they were part of a monomer, a dimer, a trimer, or higher oligomers. These observations lead to the conclusion that initiation of DNA replication in BPV-1 DNA takes place at or close to plasmid maintenance sequence 1. From this point, replication proceeds bidirectionally and termination occurs approximately 180 degrees opposite the origin. The results obtained are consistent with one or more replication origins being quiescent in BPV-1 DNA oligomers.     

Inactivation of topoisomerase I or II may lead to recombination or to aberrant replication termination on both SV40 and yeast 2 μm DNA

Topoisomerase I is believed to be sufficient for early replication of circular viral genomes such as those of SV40 and of yeast plasmids. Topoisomerase II is required for the decatenation of the daughter genomes and probably also for fork elongation during the later stages of SV40 replication. Using the neutral-neutral two-dimensional gel system, we have followed the progression of replication of both SV40 and the yeast 2μm plasmid under various conditions of topoisomerase inhibition. During SV40 replication, inhibition of topoisomerase II by VP16, VM26 or hypertonic shock (but not by merbarone), and inhibition of topoisomerase I by camptothecin all led to the accumulation of aberrant DNA structures containing two almost completely replicated genomes. These aberrant structures resembled either recombination intermediates or late Cairns structures in which the site of replication termination had shifted and now mapped to a continuum of sites throughout the genome. Replication of the 2 μm plasmid in a topoisomerase II- but not a topoisomerase I-deficient yeast gave rise to very similar structures. The data suggest that inactivation of topoisomerase I or II either stimulates recombination or, by differentially affecting replication fork progression, leads to aberrant replication termination. Edited by: J. Huberman     

Possible mechanism of adenovirus generation from a cloned viral genome tagged with nucleotides at its ends

The entire cloned human adenovirus type 5 (Ad5) genome is known to be able to generate infectious virus after transfection into 293 cells when the both ends of the genome are exposed by digestion with appropriate restriction enzymes. However, when one or both ends of the genome are tagged with nucleotides and are not intact, whether the tagged end of the viral genome was remained tagged or corrected to be intact during the generation of viral clones has been unclear and, if such oligonucleotide removal occurs, how does the virus remove these tagged sequences and thereby restore its proper structure? Here, we show in our semi‐quantitative study that the generation efficiency of virus clones decreases depending on the length of nucleotide tags at the both ends and that both the oligonucleotide tags were precisely removed during virus generation with restoration of the proper terminal sequences. Interestingly the viral genome of which one end was tagged, while the other was attached about 12‐kb sequences, did generate intact viral clones at a reduced but significant efficiency. From these results, we here propose a possible mechanism whereby the terminal‐protein‐deoxycytidine complex enters from the enzyme‐cleaved end and reaches deoxyguanine at the initiating position of DNA synthesis in vivo. A replication origin at one end, embedded deeply in double‐stranded DNA, can be activated by two cycles of one‐directional full‐length DNA synthesis initiated by the other exposed replication origin about 30 kilobases away. We also describe new cassette cosmids which can use not only PacI but also BstBI for construction of an adenovirus vector, without reducing construction efficiency.     

Examination of lactococcal bacteriophage c2 DNA replication using two-dimensional agarose gel electrophoresis.

The ori locus of the prolate-headed lactococcal bacteriophage c2 supports plasmid replication in Lactococcus lactis in the absence of phage infection. To determine whether phage c2 DNA replication is initiated at the ori locus in vivo and to investigate the mechanism of phage DNA replication, replicating intermediates of phage c2 were analyzed using neutral/neutral two-dimensional agarose gel electrophoresis (2D). The 2D data revealed that c2 replicates via a theta mechanism and localized the initiation of theta replication to the ori region of the c2 genome.     

Analysis of Replication Intermediates Indicates That Drosophila melanogaster Mitochondrial DNA Replicates by a Strand-Coupled Theta Mechanism

Mitochondrial DNA synthesis is necessary for the normal function of the organelle and for the eukaryotic organism as a whole. Here we demonstrate, using two-dimensional agarose gel electrophoresis to analyse replication intermediates, that unidirectional, strand-coupled DNA synthesis is the prevalent mode of mtDNA replication in Drosophila melanogaster. Commencing within the single, extended non-coding region (NCR), replication proceeds around the circular genome, manifesting an irregular rate of elongation, and pausing frequently in specific regions. Evidence for a limited contribution of strand-asynchronous DNA synthesis was found in a subset of mtDNA molecules, but confined to the ribosomal RNA gene region, just downstream of the NCR. Our findings imply that strand-coupled replication is widespread amongst metazoans, and should inform future research on mtDNA metabolism in D. melanogaster.