Simian Virus 40 Minichromosomes Research Articles

SV40 virion formation functions as a novel epigenetic switch controlling early and late transcription

Simian Virus 40 (SV40) is a small double‐strand DNA virus, which exists in the form of chromatin throughout its lifecycle. Because of its chromatin structure, the virus is expected to undergo the typical forms of epigenetic regulation, including differential nucleosome location and histone modifications. In order to characterize the epigenetic changes occurring during the formation of virions from late‐stage SV40 minichromosomes (encapsidation), we have compared the location of nucleosomes containing acetylated or methylated lysines from the histone tails of H3 and H4 present in the chromatin from late‐stage minichromosomes, encapsidation intermediates, and disrupted virions. In late‐stage minichromosomes, we found that nucleosomes carrying histone modifications were primarily found in the SV40 regulatory region within the enhancer and at the early and late transcription start sites. Significantly, the nucleosome containing modified histones within the enhancer would be expected to repress early transcription by overlying regulatory sequences in the SP1 and enhancer regions required for early transcription while still allowing for late transcription. In contrast, in chromatin from virions the nucleosome found in the enhancer has been shifted approximately 70 base‐pairs toward the late region uncovering the regulatory sequences necessary for early transcription and likely repressing late transcription. This encapsidation‐dependent epigenetic switch was associated with the final stages of virion formation.Support or Funding InformationThis work was funded by grants from the National Institutes of Health, AI094441 (to B.M.) and GM098328 (to L.B.) and P20 GM113123 (to Epigenetics Core)This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

Directed Nucleosome Sliding during the Formation of the Simian Virus 40 Particle Exposes DNA Sequences Required for Early Transcription.

Simian virus 40 (SV40) exists as chromatin throughout its life cycle and undergoes typical epigenetic regulation mediated by changes in nucleosome location and associated histone modifications. In order to investigate the role of epigenetic regulation during the encapsidation of late-stage minichromosomes into virions, we mapped the locations of nucleosomes containing acetylated or methylated lysines in the histone tails of H3 and H4 present in the chromatin from 48-h-postinfection minichromosomes and disrupted virions. In minichromosomes obtained late in infection, nucleosomes were found carrying various histone modifications primarily in the regulatory region, with a major nucleosome located within the enhancer and other nucleosomes at the early and late transcriptional start sites. The nucleosome found in the enhancer would be expected to repress early transcription by blocking access to part of the SP1 binding sites and the left side of the enhancer in late-stage minichromosomes while also allowing late transcription. In chromatin from virions, the principal nucleosome located in the enhancer was shifted ∼70 bases in the late direction from what was found in minichromosomes, and the level of modified histones was increased throughout the genome. The shifting of the enhancer-associated nucleosome to the late side would effectively serve as a switch to relieve the repression of early transcription found in late minichromosomes while likely also repressing late transcription by blocking access to necessary regulatory sequences. This epigenetic switch appeared to occur during the final stage of virion formation.IMPORTANCE For a virus to complete infection, it must produce a new virus particle in which the genome is able to support a new infection. This is particularly important for viruses like simian virus 40 (SV40), which exist as chromatin throughout their life cycles, since chromatin structure plays a major role in the regulation of the life cycle. In order to determine the role of SV40 chromatin structure late in infection, we mapped the locations of nucleosomes and their histone tail modifications in SV40 minichromosomes and in the SV40 chromatin found in virions using chromatin immunoprecipitation-DNA sequencing (ChIP-Seq). We have identified a novel viral transcriptional control mechanism in which a nucleosome found in the regulatory region of the SV40 minichromosome is directed to slide during the formation of the virus particle, exposing transcription factor binding sites required for early transcription that were previously blocked by the presence of the nucleosome.

Replication‐dependent repression of SV40 early transcription occurs by placement of a nucleosome over early regulatory elements

We have previously shown that during the Simian Virus 40 (SV40) life‐cycle, DNA replication serves as an epigenetic switch by introducing H3K9me1 into newly replicated SV40 minichromosomes in order to repress early transcription in these newly‐replicated minichromosomes. While these studies demonstrated that epigenetics played a critical role in regulation of SV40 transcription, they did not directly address the exact mechanism of how the introduction of H3K9me1 repressed early transcription. We have now analyzed the location of nucleosomes in SV40 wild‐type 776 and the repression‐defective mutant cs1085 using a ChIP‐Seq like approach and confirmed that there is a significant increase in minichromosomes lacking a nucleosome over the early regulatory region in the cs1085 repression‐defective mutant minchromosomes compared to the wild‐type minichromosomes. In addition, we have shown that nucleosomes containing H3K9me1 are preferentially found within the early regulatory region in the wild‐type minichromosomes. These results suggest replication‐dependent repression of early transcription occurs by a mechanism in which nucleosomes specifically containing H3K9me1 are targeted to locations within the early regulatory region including the binding site of TBP and RNA Polymerase II. These specifically located nucleosomes would serve as a physical barrier to prevent the binding of the factors necessary for initiation of early transcription.

Transcription and replication result in distinct epigenetic marks following repression of early gene expression

Simian virus 40 (SV40) early transcription is repressed when the product of early transcription, T-antigen, binds to its cognate regulatory sequence, Site I, in the promoter of the SV40 minichromosome. Because SV40 minichromosomes undergo replication and transcription potentially repression could occur during active transcription or during DNA replication. Since repression is frequently epigenetically marked by the introduction of specific forms of methylated histone H3, we characterized the methylation of H3 tails during transcription and replication in wild-type SV40 minichromosomes and mutant minichromosomes which did not repress T-antigen expression. While repressed minichromosomes following replication were clearly marked with H3K9me1 and H3K4me1, minichromosomes repressed during early transcription were not similarly marked. Instead repression of early transcription was marked by a significant reduction in the level of H3K9me2. The replication dependent introduction of H3K9me1 and H3K4me1 into wild-type SV40 minichromosomes was also observed when replication was inhibited with aphidicolin. The results indicate that the histone modifications associated with repression can differ significantly depending upon whether the chromatin being repressed is undergoing transcription or replication.

Histone Hyperacetylation during SV40 Transcription Is Regulated by p300 and RNA Polymerase II Translocation

The effects of the RNA polymerase II (RNAPII) translocation inhibitors alpha amanitin and 5,6-dichloro-1-beta-D-ribobenzimidazole (DRB) and an siRNA targeting p300 on the presence of RNAPII, p300, hyperacetylated H4 and H3 and unmodified H4 and H3 in transcribing simian virus 40 (SV40) minichromosomes were determined. Following treatment with alpha amanitin we observed a profound reduction in the occupancy of the promoter by RNAPII, the loss of p300 from chromatin fragments containing RNAPII, and an increase in the amount of unmodified H4 and H3 associated with the RNAPII. Treatment with DRB had little effect on the presence of RNAPII or p300 but also resulted in a significant increase in the amount of unmodified H4 and H3 present in chromatin fragments associated with RNAPII. Following treatment with a p300 small interfering RNA (siRNA), we observed a significant decrease in late transcription and a corresponding reduction in the amounts of p300 and hyperacetylated histones associated with the transcribing SV40 minichromosomes. We conclude that in transcribing SV40 minichromosomes histone hyperacetylation and deacetylation is dependent upon the presence of p300 and an as yet unknown histone deacetylase associated with the RNAPII complex that occurs coordinately as the RNAPII complex moves through a nucleosome.

Characterization of simian virus 40 on its infectious entry pathway in cells using fluorescence correlation spectroscopy

SV40 (simian virus 40) is a double-stranded DNA virus and is strongly oncogenic in experimental animals. SV40 enters cells by atypical endocytosis mediated by caveolae, transporting the virus to its usual destination, namely the endoplasmic reticulum. The cellular mechanisms of capsid disassembly (uncoating) and deliverance of the viral genome into the cellular nucleus remain unknown. Here, we study (i) the formation of caveolae after viral infection and the diffusion of caveosome vesicles in the cytoplasm and (ii) the capsid disassembly and the mobility of the viral genome on its way to the nucleus, using fluorescence correlation spectroscopy. To follow the viral genome and capsids separately, the histone components of SV40 minichromosomes were labelled with enhanced yellow fluorescent protein and the capsid was labelled with a fluorescent red dye, Alexa568. We characterized the diffusion of caveosomes, the capsid disassembly process in the cytoplasm and the mobility of the viral genome in the nucleus, using two kinds of permissive cells.

Cellular transcription factor Sp1 recruits simian virus 40 capsid proteins to the viral packaging signal, ses.

Simian virus 40 (SV40) capsid assembly occurs in the nucleus. All three capsid proteins bind DNA nonspecifically, raising the dilemma of how they attain specificity to the SV40 minichromosome in the presence of a large excess of genomic DNA. The SV40 packaging signal, ses, which is required for assembly, is composed of multiple DNA elements that bind transcription factor Sp1. Our previous studies showed that Sp1 participates in SV40 assembly and that it cooperates in DNA binding with VP2/3. We hypothesized that Sp1 recruits the capsid proteins to the viral minichromosome, conferring upon them specific DNA recognition. Here, we have tested the hypothesis. Computer analysis showed that the combination of six tandem GC boxes at ses is not found at cellular promoters and therefore is unique to SV40. Cooperativity in DNA binding between Sp1 and VP2/3 was not abolished at even a 1,000-fold excess of cellular DNA, providing strong support for the recruitment hypothesis. Sp1 also binds VP1 and cooperates with VP1 in DNA binding. VP1 pentamers (VP1(5)) avidly interact with VP2/3, utilizing the same VP2/3 domain as described for polyomavirus. We conclude that VP1(5)-VP2/3 building blocks are recruited by Sp1 to ses, where they form the nucleation center for capsid assembly. By this mechanism the virus ensures that capsid formation is initiated at a single site around its minichromosome. Sp1 enhances the formation of SV40 pseudovirions in vitro, providing additional support for the model. Analyses of Sp1 and VP3 deletion mutants showed that Sp1 and VP2/3 bind one another and cooperate in DNA binding through their DNA-binding domains, with additional contacts outside these domains. VP1 contacts Sp1 at residues outside the Sp1 DNA-binding domain. These and additional data allowed us to propose a molecular model for the VP1(5)-VP2/3-DNA-Sp1 complex.

Re-oxygenation of hypoxic simian virus 40 (SV40)-infected CV1 cells causes distinct changes of SV40 minichromosome-associated replication proteins.

Hypoxia interrupts the initiation of simian virus 40 (SV40) replication in vivo at a stage situated before unwinding of the origin region. After re-oxygenation, unwinding followed by a synchronous round of viral replication takes place. To further characterize the hypoxia-induced inhibition of unwinding, we analysed the binding of several replication proteins to the viral minichromosome before and after re-oxygenation. T antigen, the 34-kDa subunit of replication protein A (RPA), topoisomerase I, the 48-kDa subunit of primase, the 125-kDa subunit of polymerase delta, and the 37-kDa subunit of replication factor C (RFC) were present at the viral chromatin already under hypoxia. The 70-kDa subunit of RPA, the 180-kDa subunit of polymerase alpha, and proliferating cell nuclear antigen (PCNA) were barely detectable at the SV40 chromatin under hypoxia and significantly increased after re-oxygenation. Immunoprecipitation of minichromosomes with T antigen-specific antibody and subsequent digestion with micrococcus nuclease revealed that most of the minichromosome-bound T antigen was associated with the viral origin in hypoxic and in re-oxygenated cells. T antigen-catalysed unwinding of the SV40 origin occurred, however, only after re-oxygenation as indicated by (a) increased sensitivity of re-oxygenated minichromosomes against digestion with single-stranded DNA-specific nuclease P1; (b) stabilization of RPA-34 binding at the SV40 minichromosome; and (c) additional phosphorylations of RPA-34 after re-oxygenation, probably catalysed by DNA-dependent protein kinase. The results presented suggest that the subunits of the proteins necessary for unwinding, primer synthesis and primer elongation first assemble at the SV40 origin in form of stable, active complexes directly before they start to work.

The SV40 capsid protein VP3 cooperates with the cellular transcription factor Sp1 in DNA-binding and in regulating viral promoter activity

Chromatin structure and protein-protein interactions play an important role in eukaryotic gene function. Nucleosomal rearrangement at the simian virus 40 (SV40) regulatory region occurs at the late stages of the viral life cycle preceding viral assembly. The SV40 capsid proteins are required for this nucleosomal rearrangement suggesting that they participate in turning-off the viral promoters. In aiming to elucidate the role of the capsid proteins in gene regulation, we studied the interaction between VP3, an internal capsid protein, and the cellular transcription factor Sp1, a major regulator of both the early and late viral promoters. Our results showed that VP3 repressed transcription from the viral early promoter in vitro. We found significant cooperativity between Sp1 and VP3 in specific DNA-binding to the Sp1 binding site. In addition, protein-protein interactions between VP3 and Sp1 in the absence of DNA were observed. These findings have led us to conclude that the novel host-viral Sp1-VP3 complex down regulates viral transcription and further suggest that Sp1 participates in recruiting VP3 to the SV40 minichromosome in SV40 assembly.

Accessibility to topoisomerases I and II regulates the replication efficiency of simian virus 40 minichromosomes.

We determined the effects of chromatin structure on template accessibility to replication factors and used three different templates as substrates for simian virus 40 (SV40) DNA replication in vitro: native and salt-treated SV40 minichromosomes and protein-free SV40 DNA. Native minichromosomes contain histone H1 and numerous nonhistone proteins in addition to the core histones, whereas salt-treated minichromosomes carry essentially only core histones. We reasoned that the less densely packed salt-treated minichromosomes should be more effective replication templates due to their more extended configuration. However, contrary to this expectation, we found that native minichromosomes replicated with significantly higher efficiency than salt-treated minichromosomes, while protein-free DNA was most active as a replication template. The higher replication efficiency of native minichromosomes was due to two activities bound to the chromatin, which were identified as DNA topoisomerases I and II. By using chromatin substrates of different general configurations, we also showed that the overall chromatin structure determines accessibility to topoisomerases I and II and thereby the efficiency of replicative chain elongation.

Measurement of the linking number change in transcribing chromatin

The in vivo-initiated, transcribing simian virus 40 (SV40) minichromosome was analyzed to determine its DNA linking number change, i.e. the difference between the linking number of the minichromosomal DNA and that of relaxed bare DNA. As part of this measurement, the linking number change due to the in vivo-initiated RNA polymerase II was determined, the first time a value for this quantity has been reported. The topological contribution of the polymerase was combined with values determined for constrained and non-constrained linking number contributions from the native transcription complex chromatin to yield the linking number change for the complex. The linking number change of the native non-transcribed SV40 minichromosome was independently determined and was found to be virtually the same as that for the chromatin of the transcription complex. This indicates that there is little difference between the two structures. The plausibility of several current models for the contribution of chromatin structure to transcription regulation is discussed in light of this finding.

Topological Complexity of SV40 Minichromosomes

During attempts to measure the extent to which the proteins of simian virus 40 (SV40) minichromosomes restrain the ability of SV40 DNA to alter its twist in response to temperature changes, we found that temperature- shift-induced linking number changes are not reversible for isolated minichromosomes, suggesting that such changes, both in isolated minichromosomes and in cells, may be a consequence of structural alterations in chromatin proteins rather than of simple changes in DNA twist. We also found that the SV40 minichromosome pool is composed of subpopulations that display different responses to temperature shifts. For example, the linking number of DNA in newly replicated minichromo somes is more responsive to in vivotemperature changes than is the linking number of DNA in bulk minichromosomes. In addition, the linking number profiles of both isolated and intracellular minichromosomes change during the course of infection. These observations emphasize the topological complexity of SV40 minichromosomes and encourage caution in the interpretation of experiments carried out on bulk minichromosomes.

Elements in the immunoglobulin heavy-chain enhancer directly regulate simian virus 40 ori-dependent DNA replication.

In a previous study, we showed that the immunoglobulin heavy-chain (IgH) enhancer (IgHe) is near or in an initiation zone of chromosomal DNA replication, which is preferentially active in B cells (K. Ariizumi, Z. Wang, and P. W. Tucker, Proc. Natl. Acad. Sci. USA 90:3695-3699, 1993). This suggests the existence of a functional relationship between IgHe-mediated transcription and DNA replication. To test this theory, we utilized simian virus 40 (SV40) DNA replication as a model of chromosomal replication. IgHe or its operationally divisible domains (5'-En, core, and 3'-En) were introduced into SV40 minichromosomes (IgHe-SV40). Results of replication assays with IgHe-SV40 replicons indicated that the 5'-En and 3'-En activated or suppressed SV40 DNA replication regardless of the presence of SV40 enhancers or promoters in these replicons. The activity did not reside in IgHe core sequences. The results suggested that the 5'- and 3'-En regulated SV40 replication through direct interaction with the origin, not through suppression at the SV40 enhancer and/or promoter. In an effort to identify elements within the 5'-En motif that contributed to this effect, we found that the E site, but not microE5 and microE2 boxes, upregulated DNA replication. Our results provide another possible regulatory function for the 5'-En and 3'-En domains besides transcriptional suppression of IgHe.

Elements in the immunoglobulin heavy-chain enhancer directly regulate simian virus 40 ori-dependent DNA replication.

In a previous study, we showed that the immunoglobulin heavy-chain (IgH) enhancer (IgHe) is near or in an initiation zone of chromosomal DNA replication, which is preferentially active in B cells (K. Ariizumi, Z. Wang, and P. W. Tucker, Proc. Natl. Acad. Sci. USA 90:3695-3699, 1993). This suggests the existence of a functional relationship between IgHe-mediated transcription and DNA replication. To test this theory, we utilized simian virus 40 (SV40) DNA replication as a model of chromosomal replication. IgHe or its operationally divisible domains (5'-En, core, and 3'-En) were introduced into SV40 minichromosomes (IgHe-SV40). Results of replication assays with IgHe-SV40 replicons indicated that the 5'-En and 3'-En activated or suppressed SV40 DNA replication regardless of the presence of SV40 enhancers or promoters in these replicons. The activity did not reside in IgHe core sequences. The results suggested that the 5'- and 3'-En regulated SV40 replication through direct interaction with the origin, not through suppression at the SV40 enhancer and/or promoter. In an effort to identify elements within the 5'-En motif that contributed to this effect, we found that the E site, but not microE5 and microE2 boxes, upregulated DNA replication. Our results provide another possible regulatory function for the 5'-En and 3'-En domains besides transcriptional suppression of IgHe.

Structural requirements for simian virus 40 replication and virion maturation

The nuclear matrix plays an important role in simian virus 40 (SV40) DNA replication in vivo, since functional replication complexes containing large T and replicating SV40 minichromosomes are anchored to this structure (R. Schirmbeck and W. Deppert, J. Virol. 65:2578-2588, 1991). In the present study, we have analyzed the course of events leading from nuclear matrix-associated replicating SV40 minichromosomes to fully replicated minichromosomes and, further, to their encapsidation into mature SV40 virions. Pulse-chase experiments revealed that newly replicated SV40 minichromosomes accumulated at the nuclear matrix and were directly encapsidated into DNase-resistant SV40 virions at this nuclear structure. Alternatively, a small fraction of newly replicated minichromosomes left the nuclear matrix to associate with the cellular chromatin. During the course of infection, progeny virions continuously were released from the nuclear matrix to the cellular chromatin and into the cytoplasm-nucleoplasm. The bulk of SV40 progeny virions, however, remained at the nuclear matrix until virus-induced cell lysis.

Simian virus 40 minichromosomes as targets for retroviral integration in vivo.

We present a method for studying multiple retroviral integration events into a small DNA target in vivo. Episomal simian virus 40 (SV40) genomes established by infection of CV-1 cells served as integration targets during subsequent infection with murine leukemia virus (MLV). Using a PCR-based assay for the abundance and distribution of integration events, nonrandom integration of MLV DNA into SV40 DNA is detectable as early as 4 hr and reaches a maximum level by 8 hr after MLV infection. The level of integration but not the distribution of integration sites is sensitive to the stage in the SV40 life cycle at which MLV infection is performed. Using a temperature-sensitive tumor (T) antigen mutant SV40 strain, we observed that active replication of the target DNA is not required for efficient integration in vivo. The distribution of integration sites in vivo is closely approximately by in vitro reactions with isolated SV40 minichromosomes as integration targets. However, the degree of bias between the most and least favored sites is greater in vivo than in vitro.

Immunoprecipitation of SV40 replicating minichromosomes complexed with bacteriophage T4 gene 32 protein.

Simian Virus 40 (SV40) DNA replication is a useful model to study eukaryotic cell DNA replication because it encodes only one replication protein and its genome has a nucleoprotein structure ('minichromosome') indistinguishable from cellular chromatin. Late after infection SV40 replicating DNA molecules represent about 5% of total viral minichromosomes. Since gene 32 protein (P32) from bacteriophage T4 interacts with single-stranded DNA and SV40 replication complexes are expected to contain single-stranded regions at the replication forks, we asked whether P32 might be used to isolate replicating SV40 minichromosomes. When nuclear extracts from SV40 infected cells were treated sequentially with P32 and anti-P32 antibodies, pulse-labeled minichromosomes were selectively immunoprecipitated. Agarose gel electrophoresis analysis confirmed that immunoprecipitated material corresponded to SV40 replicative intermediates. Protein analysis of the pelleted material revealed several proteins of viral and cellular origin. Among them, T antigen and histones were found to be complexed with at least other three proteins from cellular origin, to the replicative complexes. Additionally, anti-P32 antibodies were able to detect three cellular proteins of approximately 70, 32 and 13 kDa in western blots. These proteins could correspond to those found as part of an eukaryotic multisubunit single-stranded DNA binding protein. The use of P32 and anti-P32 antibodies thus allows the separation of replicating from mature SV40 minichromosomes and can constitute a novel method to enrich and to study replicative active chromatin.

Location of nucleosomes in simian virus 40 chromatin

Over the past decade, the results of numerous indirect mappings analyses have not clarified whether or not nucleosomes occupy preferred positions in simian virus 40 (SV40) chromatin. To address this question more directly, we followed a shotgun cloning approach and determined the nucleotide sequences of over 400 cloned nucleosomal DNA fragments obtained from digestion of SV40 chromatin with micrococcal nuclease. Our results demonstrate and establish that nucleosomes do not occupy unique positions in SV40 minichromosomes and thus indicate the existence of at least several types of chromatin molecules having different nucleosome organization patterns. We developed two types of statistical analysis in order to examine the cloning data in greater detail. One type, overlap analysis, revealed the distribution of the cloned fragments with respect to SV40 DNA. The distribution exhibits an oscillating pattern, dividing the genome into regions of weak or strong nucleosome density. The other analysis determined the distribution of the midpoints of the cloned fragments and revealed potential strong and weak nucleosome location sites, and an early versus late distinction in organization of nucleosomes in SV40 chromatin. The late region appears to contain more strong nucleosome location sites (8) than the early region (4). The strongest nucleosome abuts the late side of the nuclease-hypersensitive region and includes the major transcription initiation site of the late genes. Another strong site precedes this nucleosome and includes sequences implicated in controlling the expression of the SV40 early and late genes. A strong or weak nucleosome location site is not apparent near the early side of the nucleosome-hypersensitive region. Only weak and overlapping nucleosome location sites are found in the region where replication terminates in the SV40 minichromosomes.

Determination of the DNA conformation of the simian virus 40 (SV40) enhancer in SV40 minichromosomes

The simian virus 40 (SV40) enhancer contains three 8-bp purine-pyrimidine alternating sequences which are known to adopt the left-handed Z-DNA conformation in vitro. In this paper, we have undertaken the determination of the DNA conformation adopted by these Z-motifs in the SV40 minichromosome. We have analyzed the presence of Z-DNA through the change in linkage which should accompany formation of this left-handed conformation. Our results indicate that, regardless of the precise moment of the viral lytic cycle at which minichromosomes are harvested and the condition of the transfected DNA, either relaxed or negatively supercoiled, none of the three Z motifs of the SV40 enhancer exist to a significant extent as Z-DNA in SV40 minichromosomes. The SV40 enhancer adopts predominantly a right-handed B-DNA conformation in vivo.

Recombinogenic properties of herpes simplex virus type 1 DNA sequences resident in simian virus 40 minichromosomes

In a previous work, it was demonstrated that the bacterial transposon Tn5 is capable of undergoing sequence inversion via recombination between its duplicated IS50 elements when replicated by the herpes simplex virus type 1 (HSV-1) origin oris but not by the simian virus 40 (SV40) origin orisv. Further analysis of the latter phenomenon indicated that this lack of recombination was the result of topological constraints imposed by the SV40 minichromosome, such that recombination events could be readily detected in Tn5 derivatives in which the IS50 elements were arranged in a direct rather than inverted orientation. With this information, a second set of experiments were carried out to examine how the highly recombinogenic sequences which mediate the inversion of the long (L) and short (S) components of the HSV-1 genome behave in an SV40 minichromosome. Tandem copies of the L-S junction of the HSV-1 genome were observed to promote deletions in an SV40 shuttle plasmid at a frequency that was considerably greater than that of duplicated bacterial plasmid vector DNA. However, the presence of superinfecting HSV-1 did not enhance the frequency of these recombination events. These results support our previous findings that HSV-1 genome isomerization is mediated by a homologous recombination mechanism which is intimately associated with the act of viral DNA synthesis. Moreover, they demonstrate that the sequences which comprise the L-S junction appear to be inherently recombinogenic and, therefore, do not contain specific signals required for HSV-1 genome isomerization.