The herpes simplex virus type 1 (HSV-1) a sequence serves as a cleavage/packaging signal but does not drive recombinational genome isomerization when it is inserted into the HSV-2 genome

Combination of long- and short-read sequencing fully resolves complex repeats of herpes simplex virus 2 strain MS complete genome

Herpes simplex virus serotype 2 (HSV-2) is a ubiquitous human pathogen that causes recurrent genital infections and ulcerations. Many HSV-2 strains with different biological properties have been identified, but only the genomes of HSV-2 strains HG52, SD90e and 333 have been reported as complete and fully characterized sequences. We de novo assembled, annotated and manually curated the complete genome sequence of HSV-2 strain MS, a highly neurovirulent strain, originally isolated from a multiple sclerosis patient. We resolved both DNA ends, as well as the complex inverted repeats regions present in HSV genomes, usually undisclosed in previous published partial herpesvirus genomes, using long reads from Pacific Biosciences (PacBio) technology. Additionally, we identified isomeric genomes by determining the alternative relative orientation of unique fragments in the genome of the sequenced viral population. Illumina short-read sequencing was crucial to examine genetic variability, such as nucleotide polymorphisms, insertion/deletions and sequence determinants of strain-specific virulence factors. We used Illumina data to fix two disrupted open reading frames found in coding homopolymers after PacBio assembly. These results support the combination of long- and short-read sequencing technologies as a precise and effective approach for the accurate de novo assembly and curation of complex microbial genomes.

Structural variability of the herpes simplex virus 1 genome in vitro and in vivo

Herpes simplex virus 1 (HSV-1) is a human pathogen that leads to recurrent facial-oral lesions. Its 152-kb genome is organized in two covalently linked segments, each composed of a unique sequence flanked by inverted repeats. Replication of the HSV-1 genome produces concatemeric molecules in which homologous recombination events occur between the inverted repeats. This mechanism leads to four genome isomers (termed P, IS, IL, and ILS) that differ in the relative orientations of their unique fragments. Molecular combing analysis was performed on DNA extracted from viral particles and BSR, Vero, COS-7, and Neuro-2a cells infected with either strain SC16 or KOS of HSV-1, as well as from tissues of experimentally infected mice. Using fluorescence hybridization, isomers were repeatedly detected and distinguished and were accompanied by a large proportion of noncanonical forms (40%). In both cell and viral-particle extracts, the distributions of the four isomers were statistically equivalent, except for strain KOS grown in Vero and Neuro-2a cells, in which P and IS isomers were significantly overrepresented. In infected cell extracts, concatemeric molecules as long as 10 genome equivalents were detected, among which, strikingly, the isomer distributions were equivalent, suggesting that any such imbalance may occur during encapsidation. In vivo, for strain KOS-infected trigeminal ganglia, an unbalanced distribution distinct from the one in vitro was observed, along with a considerable proportion of noncanonical assortment.

A human cytomegalovirus deleted of internal repeats replicates with near wild type efficiency but fails to undergo genome isomerization

The class E genome of human cytomegalovirus (HCMV) contains long and short segments that invert due to recombination between flanking inverted repeats, causing the genome to isomerize into four distinct isomers. To determine if isomerization is important for HCMV replication, one copy of each repeat was deleted. The resulting virus replicated in cultured human fibroblasts with only a slight growth impairment. Restriction and Southern analyses confirmed that its genome is locked in the prototypic arrangement and unable to isomerize. We conclude that efficient replication of HCMV in fibroblasts does not require (i) the ability to undergo genome isomerization, (ii) genes that lie partially within the deleted repeats, or (iii) diploidy of genes that lie wholly within repeats. The simple genomic structure of this virus should facilitate studies of genome circularization, latency or persistence, and concatemer packaging as such studies are hindered by the complexities imposed by isomerization.

Effects of mutations within the herpes simplex virus type 1 DNA encapsidation signal on packaging efficiency

The cis-acting signals required for cleavage and encapsidation of the herpes simplex virus type 1 genome lie within the terminally redundant region or a sequence. The a sequence is flanked by short direct repeats (DR1) containing the site of cleavage, and quasi-unique regions, Uc and Ub, occupy positions adjacent to the genomic L and S termini, respectively, such that a novel fragment, Uc-DR1-Ub, is generated upon ligation of the genomic ends. The Uc-DR1-Ub fragment can function as a minimal packaging signal, and motifs have been identified within Uc and Ub that are conserved near the ends of other herpesvirus genomes (pac2 and pac1, respectively). We have introduced deletion and substitution mutations within the pac regions of the Uc-DR1-Ub fragment and assessed their effects on DNA packaging in an amplicon-based transient transfection assay. Within pac2, mutations affecting the T tract had the greatest inhibitory effect, but deletion of sequences on either side of this element also reduced packaging, suggesting that its position relative to other sequences within the Uc-DR1-Ub fragment is likely to be important. No single region essential for DNA packaging was detected within pac1. However, mutants lacking the G tracts on either side of the pac1 T-rich motif exhibited a reduced efficiency of serial propagation, and alteration of the sequences between DR1 and the pac1 T element also resulted in defective generation of Ub-containing terminal fragments. The data are consistent with a model in which initiation and termination of packaging are specified by sequences within Uc and Ub, respectively.

Machinery to support genome segment inversion exists in a herpesvirus which does not naturally contain invertible elements

In many herpesviruses, genome segments flanked by inverted repeats invert during DNA replication. It is not known whether this inversion is a consequence of an inherently recombinagenic replicative mechanism common to all herpesviruses or whether the replication enzymes of viruses with invertible segments have specifically evolved additional enzymatic activities to drive inversion. By artificially inserting a fusion of terminal sequences into the genome of a virus which normally lacks invertible elements (murine cytomegalovirus), we created a genome composed of long and short segments flanked by 1,359- and 543-bp inverted repeats. Analysis of genomic DNA from this virus revealed that inversion of both segments generates equimolar amounts of four isomers during the viral propagation necessary to produce DNA for analysis from a single viral particle. We conclude that a herpesvirus which naturally lacks invertible elements is able to support efficient segment inversion. Thus, the potential to invert is probably inherent in the replication machinery of all herpesviruses, irrespective of genome structure, and therefore genomes with invertible elements could have evolved simply by acquisition of inverted repeats and without concomitant evolution of enzymatic activities to mediate inversion. Furthermore, the recombinagenicity of herpesvirus DNA replication must have some importance independent of genome segment inversion.

Herpes simplex virus genome isomerization: origins of adjacent long segments in concatemeric viral DNA

Herpes simplex virus type 1 DNA isomerization was studied by using a viral mutant, 5B8, lacking the unique SpeI site of its parent, SC16. In coinfected cells, SC16 genomic long segments flanked 5B8 genomes in all possible orientations with similar frequencies. Thus, recombination between progeny of different replication templates is sufficient to explain genomic isomerization.

An enhanced packaging system for helper-dependent herpes simplex virus vectors

Helper-dependent herpes simplex virus (HSV) vectors (amplicons) show considerable promise to provide for long-term transduced-gene expression in most cell types. The current packaging system of choice for these vectors involves cotransfection with a set of five overlapping cosmids that encode the full HSV type 1 (HSV-1) helper virus genome from which the packaging (pac) elements have been deleted. Although both the helper virus and the HSV amplicon can replicate, only the latter is packaged into infectious viral particles. Since the titers obtained are too low for practical application, an enhanced second-generation packaging system was developed by modifying both the helper virus and the HSV amplicon vector. The helper virus was reverse engineered by using the original five cosmids to generate a single HSV-bacterial artificial chromosome (BAC) clone in Escherichia coli from which the pac elements were deleted to generate a replication-proficient but packaging-defective HSV-1 genome. The HSV amplicon was modified to contain the simian virus 40 origin of replication, which acts as an HSV-independent replicon to provide for the replicative expansion of the vector. The HSV amplicon is packaged into infectious particles by cotransfection with the HSV-BAC helper virus into the 293T cell line, and the resulting cell lysate is free of detectable helper virus contamination. The combination of both modifications to the original packaging system affords an eightfold increase in the packaged-vector yield.

DNA replication promotes high-frequency homologous recombination during Autographa californica multiple nuclear polyhedrosis virus infection

The relative ease with which foreign genes can be incorporated into the genome of the baculovirus Autographa californica nuclear polyhedrosis virus (AcMNPV) indicates that a highly efficient recombinational process exists within infected cells. However, it is unclear whether this is due to marker transfer mediated by host cell enzymes or recombination events promoted by AcMNPV itself. To address the latter possibility, a pair of inverted repeat IS50 elements derived from the bacterial transposon Tn5 was inserted into the polyhedrin gene locus of the AcMNPV genome. Inversion of Tn5 sequences arising from recombination between its IS50 repeats could be readily detected in this virus, indicating that AcMNPV DNA undergoes high-frequency recombination during infection. To further characterize this process, a transient recombination assay was developed and used to identify the cis- and trans-acting requirements for Tn5 inversion in AcMNPV. A transfected Tn5-containing plasmid was found to undergo the same sequence inversion events seen in the viral genome, but only if it also contained a putative AcMNPV origin of replication (homologous region 2) in cis and was replicated by AcMNPV gene products supplied in trans. Taken together, these results indicated that recombination events which occur in infected cells were strictly dependent upon AcMNPV-mediated DNA replication. Direct support for this hypothesis was provided by the observation that the minimal set of AcMNPV genes that was essential for plasmid DNA replication also promoted recombination events leading to Tn5 inversion in the absence of any other viral function. Finally, using a panel of deletion mutants of the IS50 elements in Tn5, sequence inversion was shown to be the result of homologous rather than site-specific recombination, since it occurred independently of a discrete sequence within the transposon. These results demonstrate that the AcMNPV DNA replication machinery exhibits a strong propensity to promote homologous recombination events during infection and is likely to play a role in the high frequency of marker transfer observed in this virus.

The a sequence is dispensable for isomerization of the herpes simplex virus type 1 genome

The herpes simplex virus type 1 (HSV-1) genome consists of two components, L (long) and S (short), that invert relative to each other during productive infection to generate four equimolar isomeric forms of viral DNA. Recent studies have indicated that this genome isomerization is the result of DNA replication-mediated homologous recombination between the large inverted repeat sequences that exist in the genome, rather than site-specific recombination through the terminal repeat a sequences present at the L-S junctions. However, there has never been an unequivocal demonstration of the dispensability of the latter element for this process using a recombinant virus whose genome lacks a sequences at its L-S junctions. This is because the genetic manipulations required to generate such a viral mutant are not possible using simple marker transfer, since the cleavage and encapsidation signals of the a sequence represent essential cis-acting elements which cannot be deleted outright from the viral DNA. To circumvent this problem, a simple two-step strategy was devised by which essential cis-acting sites like the a sequence can be readily deleted from their natural loci in large viral DNA genomes. This method involved initial duplication of the element at a neutral site in the viral DNA and subsequent deletion of the element from its native site. By using this approach, the a sequence at the L-S junction was rendered dispensable for virus replication through the insertion of a second copy into the thymidine kinase (TK) gene of the viral DNA; the original copies at the L-S junctions were then successfully deleted from this virus by conventional marker transfer. The final recombinant virus, HSV-1::L-S(delta)a, was found to be capable of undergoing normal levels of genome isomerization on the basis of the presence of equimolar concentrations of restriction fragments unique to each of the four isomeric forms of the viral DNA. Interestingly, only two of these genomic isomers could be packaged into virions. This restriction was the result of inversion of the L component during isomerization, which prevented two of the four isomers from having the cleavage and encapsidation signals of the a sequence in the TK gene in a packageable orientation. This phenomenon was exploited as a means of directly measuring the kinetics of HSV-1::L-S(delta)a genome isomerization. Following infection with virions containing just the two packaged genomic isomers, all four isomers were readily detected at a stage in infection coincident with the onset of DNA replication, indicating that the loss of the a sequence at the L-S junction had no adverse effect on the frequency of isomerization events in this virus. These results therefore validate the homologous recombination model of HSV-1 genome isomerization by directly demonstrating that the a sequence at the L-S junction is dispensable for this process. The strategy used to remove the a sequence from the HSV-1 genome in this work should be broadly applicable to studies of essential cis-acting elements in other large viral DNA molecules.

Structure of the rat cytomegalovirus genome termini

The lytic replication cycle of herpesviruses can be divided into the following three steps: (i) circularization, in which, after infection, the termini of the linear double-stranded viral genome are fused; (ii) replication, in which the circular DNA serves as template for DNA replication, which generates large DNA concatemers; and (iii) maturation, in which the concatemeric viral DNA is processed into unit-length genomes, which are packaged into capsids. Sequences at the termini of the linear virion DNA are thought to play a key role in both genome circularization and maturation. To investigate the mechanism of these processes in the replication of rat cytomegalovirus (RCMV), we cloned, sequenced, and characterized the genomic termini of this betaherpesvirus. Both RCMV genomic termini were found to contain a single copy of a direct terminal repeat (TR). The TR sequence is 504 bp in length, has a high GC content (76%), and is not repeated at internal sites within the RCMV genome. The TR comprises several small internal direct repeats as well as two sequences which are homologous to herpesvirus pac-1 and pac-2 sites, respectively. The organization of the RCMV TR is unique among cytomegaloviruses with respect to the position of the pac sequences: pac-1 is located near the left end of the TR, whereas pac-2 is present near the right end. Both RCMV DNA termini carry an extension of a single nucleotide at the 3' end. Since these nucleotides are complementary, circularization of the viral genome is likely to occur via a simple ligation reaction.

Herpes simplex virus type 1 alkaline nuclease is required for efficient processing of viral DNA replication intermediates

Mutations in the alkaline nuclease gene of herpes simplex type 1 (HSV-1) (nuc mutations) induce almost wild-type levels of viral DNA; however, mutant viral yields are 0.1 to 1% of wild-type yields (L. Shao, L. Rapp, and S. Weller, Virology 195:146-162, 1993; R. Martinez, L. Shao, J.C. Bronstein, P.C. Weber, and S. Weller, Virology 215:152-164, 1996). nuc mutants are defective in one or more stages of genome maturation and appear to package DNA into aberrant or defective capsids which fail to egress from the nucleus of infected cells. In this study, we used pulsed-field gel electrophoresis to test the hypothesis that the defects in nuc mutants are due to the failure of the newly replicated viral DNA to be processed properly during DNA replication and/or recombination. Replicative intermediates of HSV-1 DNA from both wild-type- and mutant-infected cells remain in the wells of pulsed-field gels, while free linear monomers are readily resolved. Digestion of this well DNA with restriction enzymes that cleave once in the viral genome releases discrete monomer DNA from wild-type virus-infected cells but not from nuc mutant-infected cells. We conclude that both wild-type and mutant DNAs exist in a complex, nonlinear form (possibly branched) during replication. The fact that discrete monomer-length DNA cannot be released from nuc DNA by a single-cutting enzyme suggests that this DNA is more branched than DNA which accumulates in cells infected with wild-type virus. The well DNA from cells infected with wild-type and nuc mutants contains XbaI fragments which result from genomic inversions, indicating that alkaline nuclease is not required for mediating recombination events within HSV DNA. Furthermore, nuc mutants are able to carry out DNA replication-mediated homologous recombination events between inverted repeats on plasmids as evaluated by using a quantitative transient recombination assay. Well DNA from both wild-type- and mutant-infected cells contains free U(L) termini but not free U(S) termini. Various models to explain the structure of replicating DNA are considered.

Structure and role of the terminal repeats of Epstein-Barr virus in processing and packaging of virion DNA

The linear virion Epstein-Barr virus (EBV) DNA is terminated at both ends by a variable number of direct, tandemly arranged terminal repeats (TRs) which are approximately 500 bp in size The number of TRs at each terminus can vary. After infection of host cells, the EBV DNA circularizes via the TRs by an unknown mechanism, and replication of the viral DNA during the lytic phase of the EBV life cycle leads to large DNA concatemers which need to be cleaved into virion DNA units, eventually. This cleavage event occurs at an unknown locus within the TRs of EBV, which are the cis-acting elements essential for cleavage of the concatemers and encapsidation of the virion DNA. To investigate the mechanism of DNA processing during genome circularization and cleavage of concatemeric DNA, the genomic termini of EBV were cloned, sequenced, and analyzed by direct labeling of the virion DNA. Both termini ended with identical 11-bp elements; the right end has acquired an additional 9-bp stretch that seemed to originate from the leftmost unique sequences. The left terminus is blunt, whereas the right terminus appears to have a 3' single-base extension. In a transient packaging assay, a single terminal repeat was found to be sufficient for encapsidation of plasmid DNA, and mutagenesis of the TR element defined a region of 159 bp, including the 11-bp element, which is essential for packaging. These results indicate that the genomic termini of EBV are not generated by a simple cut of a hypothetical terminase. The mechanism for cleavage of concatemers seems to involve recombination events.

Excision of DNA fragments corresponding to the unit-length a sequence of herpes simplex virus type 1 and terminus variation predominate on one side of the excised fragment

DNA fragments corresponding to the unit-length a sequence of herpes simplex virus type 1 (HSV-1) were identified in HSV-1 DNA preparations extracted by the method of Hirt. The DNA fragments were molecularly cloned, and nucleotide sequences were determined. Most termini of the fragments were at sites on DR1 corresponding to the termini of linear HSV-1 DNA generated by the cleavage-packaging system. In one-step growth experiments, DNA fragments of the unit-length a sequence appeared simultaneously with the termini of linear HSV-1 DNAs produced by cleavage of circular and concatemeric DNAs. Therefore, excision of the unit-length a sequence appeared closely related to the cleavage-packaging system. Termini of the excised DNA fragments of the variant a sequence with two DR2 arrays varied on the L-component side, while termini on the S-component side were at the site on DR1 corresponding to the authentic cleavage site. It is thus assumed that the cleavage-packaging system functions adequately on the DR1 second distal from the S component, and cleavages of other DR1 are rare and less accurate. If this notion is tenable, then most termini on the S-component side of the excised DNA fragments are derived from the second DR1 properly cleaved and should be constant, while termini on the L-component side are from regions on and around the DR1 third distal from the S component and may be variable. Cleavage of DR1 is likely to be affected by the topological relationship with the S component.

Herpes simplex virus type 1 recombination: the Uc-DR1 region is required for high-level a-sequence-mediated recombination

The a sequences of herpes simplex virus type 1 are believed to be the cis sites for inversion events that generate four isomeric forms of the viral genome. Using an assay that measures deletion of a beta-galactosidase gene positioned between two directly repeated sequences in plasmids transiently maintained in Vero cells, we had found that the a sequence is more recombinogenic than another sequence of similar size. To investigate the basis for the enhanced recombination mediated by the a sequence, we examined plasmids containing direct repeats of approximately 350 bp from a variety of sources and with a wide range of G+C content. We observed that all of these plasmids show similar recombination frequencies (3 to 4%) in herpes simplex virus type 1-infected cells. However, recombination between directly repeated a sequences occurs at twice this frequency (6 to 10%). In addition, we find that insertion of a cleavage site for an a-sequence-specific endonuclease into the repeated sequences does not appreciably increase the frequency of recombination, indicating that the presence of endonuclease cleavage sites within the a sequence does not account for its recombinogenicity. Finally, by replacing segments of the a sequence with DNA fragments of similar length, we have determined that only the 95-bp Uc-DR1 segment is indispensable for high-level a-sequence-mediated recombination.

Requirement for double-strand breaks but not for specific DNA sequences in herpes simplex virus type 1 genome isomerization events

Herpes simplex virus type 1 (HSV-1) genome isomerization occurs as a result of DNA replication-mediated homologous recombination between several sets of inverted repeat sequences present in the viral DNA. The frequency with which this recombination occurs has been demonstrated to be dependent upon DNA homology length rather than specific sequences. However, the smallest of the viral inverted repeats, the alpha sequence, has been shown to function as a recombinational hot spot, leading to speculation that this sequence may represent a specific element through which genome isomerization is mediated. To investigate this apparent paradox, a quantitative transient recombination assay system was developed and used to examine the recombinogenic properties of a panel of alpha sequence mutants. This analysis revealed that the presence of both the pac1 and pac2 elements was both necessary and sufficient for the induction of high-frequency recombination events by the alpha sequence. However, it was the double-strand break promoted by pac1 and pac2 during cleavage and packaging at the alpha sequence, and not the DNA sequences of the elements themselves, which appeared to be critical for recombination. This was illustrated (i) by the inability of the same pac1 and pac2 sequences to mediate inversion events in cells infected with an HSV-1 mutant which was competent for DNA replication-dependent recombination but defective for the cleavage and packaging process and (ii) by the ability of double-strand breaks generated in non-HSV-1 DNA by an in vivo-expressed restriction endonuclease to significantly stimulate the initiation of recombination events in virus-infected cells. Thus, the alpha sequence appears to act as a hot spot for homologous recombination simply because it happens to coincide with the site of the double-strand break which is generated during the cleavage and packaging process, not because it contains discrete sequences which are required for this activity. However, it was found that this enhanced recombinogenicity disappeared when the element was flanked by regions of extensive sequence homology, particularly that of the large inverted repeats which flank the alpha sequence at its natural site in the HSV-1 genome. These findings are consistent with a model for HSV-1 genome isomerization in which recombination is initiated primarily by multiple random double-strand breaks which arise during DNA replication across the inverted repeats of the genome, rather than by a single specific break which occurs at the alpha sequence during the cleavage and packaging process.

A novel class of transcripts expressed with late kinetics in the absence of ICP4 spans the junction between the long and short segments of the herpes simplex virus type 1 genome

A novel family of transcripts that span the junction between the long and short segments of the herpes simplex virus type 1 genome has been identified. These transcripts, designated L/S junction-spanning transcripts (L/STs), are synthesized in abundance in a variety of cells infected with mutant viruses defective in the gene for ICP4, the major transcriptional regulatory protein of the virus. Transcription of abundant 2.3- and 8.5-kb series of L/STs was shown to initiate within the same sequences as less abundant 4.2-, 7.3-, and > 9.5-kb transcripts by Northern (RNA) blot analysis. S1 nuclease analysis revealed a single 5' terminus 28 bp downstream of a TATA box and 6 bp downstream of a consensus ICP4 binding site. The location of the transcriptional start site indicates that the promoter of the L/STs likely corresponds to the bidirectional promoter described by Bohenzky et al. (R. A. Bohenzky, A. G. Papavassiliou, I. H. Gelman, and S. Silverstein, J. Virol. 67:632-642, 1993). The L/STs accumulate with late kinetics in ICP4 mutant-infected cells and are polyadenylated. Mutant viruses encoding forms of ICP4 unable to bind the consensus site, ATCGTC, exhibited abundant expression of the L/STs, whereas mutants encoding forms of ICP4 able to bind this site expressed no detectable L/STs, suggesting that ICP4 plays a critical role in repressing L/ST expression. Their synthesis in ICP4 mutant-infected cells is inhibited by the protein synthesis inhibitor cycloheximide, indicating that they are induced either by an immediate-early viral protein other than ICP4 or by a virus-induced cellular protein. Preliminary evidence indicates that the L/STs are not present in latently infected ganglia. The abundant expression of the L/STs with late kinetics only in the absence of functional ICP4 and the sensitivity of their synthesis to cycloheximide indicate that they are not members of any of the recognized kinetic classes of herpes simplex virus type 1 transcripts but constitute a new class of viral transcript.

Herpes simplex virus type 1 variant a sequence generated by recombination and breakage of the a sequence in defined regions, including the one involved in recombination

A herpes simplex virus type 1 clone, GN29, having exclusively the variant a sequence was isolated. This a sequence was composed of unique (U) and directly repeated (DR) elements DR1, Ub, (DR2)14, Ucd, Ubd, (DR2)5, DR4n2, and Uc and was assumed to be generated by recombination between sites in Ub and Uc. Unusual DNA fragments containing parts of the a sequence, present in the DNA preparations of GN29, were molecularly cloned. Almost all termini of the cloned unusual DNA fragments were situated in defined regions assumed to be recombinogenic: (i) a site in the inverted repeat of the L component, (ii) DR1, (iii) DR2, (iv) the DR4 stretch, and (v) the novel recombination stretch in the variant a sequence of GN29. The termini of unusual DNA fragments, possibly produced by strand breaks, can serve as free DNA ends to initiate recombination of the a sequence. These results support the model of double-strand-break repair for recombination of the a sequence. Sequence-specific enhancement of the recombination of the a sequence probably depends on the presence of recombinogenic elements apt to break, such as DR2 repeats and the DR4 stretch.