Genomic termini of equine herpesvirus 1.

After cell infection with the equine herpesvirus 1 (EHV-1), the termini of the linear double-stranded DNA genome fuse to form circular forms. To investigate the mechanisms in the generation and cleavage of such replicative-form DNAs, the genomic termini, the fusion of termini from replicative-form molecules, and the junction between the short and long genome segments have been analyzed by restriction mapping, blot hybridizations, cloning, and sequencing. The data suggest that the genome ends are not redundant and that the genomic termini are fused in replicative intermediates via 3' single-base extensions at the termini of the unique long segment (UL) and terminal repeat (TR). Adjacent to the EHV-1 termini are AT and gamma sequence elements highly conserved among different herpesviruses. We propose that both of these sequence elements are important for the cleavage of EHV-1 replicative forms.     

Definition of the minimal cis-acting sequences necessary for genome maturation of the herpesvirus murine cytomegalovirus

Herpesvirus DNA replication proceeds via concatemeric replicative intermediates that are comprised of head-to-tail-linked genomes. Genome maturation is carried out by the terminase, a protein complex that mediates both insertion of concatemer DNA into capsids and its subsequent cleavage to release genomes within these capsids. This cleavage is sequence specific, but the governing cis-acting DNA sequences are only partially characterized. Two highly conserved motifs called pac1 and pac2 lie near the ends of herpesvirus genomes and are known to be critical for genome maturation. However, the potential importance of other sequences has not been fully investigated. We have undertaken to define all of the sequences necessary for efficient genome maturation for a herpesvirus by inserting ectopic cleavage sites into the murine cytomegalovirus genome and assessing their ability to mediate genome maturation. A combination of deletion and substitution mutations revealed that the minimal cleavage site is large (~180 bp) and complex. Sequences distal of pac1 (relative to the point of cleavage) were dispensable, suggesting that pac1 may be the sole cis-acting element on this side of the cleavage site. In contrast, a region distal to pac2 up to 150 bp from the point of cleavage was essential. Scanning substitutions revealed that the pac2 side of the cleavage site is complex and may contain multiple cis-acting sequence elements in addition to pac2. These results should facilitate the identification of trans-acting factors that bind to these elements and the elucidation of their functions. Such information will be critical for understanding the molecular basis of this complex process.     

Circularization and cleavage of guinea pig cytomegalovirus genomes.

The mechanisms by which herpesvirus genome ends are fused to form circles after infection and are re-formed by cleavage from concatemeric DNA are unknown. We used the simple structure of guinea pig cytomegalovirus genomes, which have either one repeated DNA sequence at each end or one repeat at one end and no repeat at the other, to study these mechanisms. In circular DNA, two restriction fragments contained fused terminal sequences and had sizes consistent with the presence of single or double terminal repeats. This result implies a simple ligation of genomic ends and shows that circularization does not occur by annealing of single-stranded terminal repeats formed by exonuclease digestion. Cleavage to form the two genome types occurred at two sites, and homologies between these sites identified two potential cis elements that may be necessary for cleavage. One element coincided with the A-rich region of a pac2 sequence and had 9 of 11 bases identical between the two sites. The second element had six bases identical at both sites, in each case 7 bp from the termini. To confirm the presence of cis cleavage elements, a recombinant virus in which foreign sequences displaced the 6- and 11-bp elements 1 kb from the cleavage point was constructed. Cleavage at the disrupted site did not occur. In a second recombinant virus, restoration of 64 bases containing the 6- and 11-bp elements to the disrupted cleavage site restored cleavage. Therefore, cis cleavage elements exist within this 64-base region, and sequence conservation suggests that they are the 6- and 11-bp elements.     

Functional Identification and Analysis of cis-Acting Sequences Which Mediate Genome Cleavage and Packaging in Human Herpesvirus 6

Sequences present at the genomic termini of herpesviruses become linked during lytic-phase replication and provide the substrate for cleavage and packaging of unit length viral genomes. We have previously shown that homologs of the consensus herpesvirus cleavage-packaging signals, pac1 and pac2, are located at the left and right genomic termini of human herpesvirus 6 (HHV-6), respectively. Immediately adjacent to these elements are two distinct arrays of human telomeric repeat sequences (TRS). We now show that the unique sequence element formed at the junction of HHV-6B genome concatemers (pac2-pac1) is necessary and sufficient for virally mediated cleavage of plasmid DNAs containing the HHV-6B lytic-phase origin of DNA replication (oriLyt). The concatemeric junction sequence also allowed for the packaging of these plasmid molecules into intracellular nucleocapsids as well as mature, infectious viral particles. In addition, this element significantly enhanced the replication efficiency of oriLyt-containing plasmids in virally infected cells. Experiments revealed that the concatemeric junction sequence possesses an unusual, S1 nuclease-sensitive conformation (anisomorphic DNA), which might play a role in this apparent enhancement of DNA replication—although additional studies will be required to test this hypothesis. Finally, we also analyzed whether the presence of flanking viral TRS had any effect on the functional activity of the minimal concatemeric junction (pac2-pac1). These experiments revealed that the TRS motifs, either alone or in combination, had no effect on the efficiency of virally mediated DNA replication or DNA cleavage. Taken together, these data show that the cleavage and packaging of HHV-6 DNA are mediated by cis-acting consensus sequences similar to those found in other herpesviruses, and that these sequences also influence the efficiency of HHV-6 DNA replication. Since the adjacent TRS do not influence either viral cleavage and packaging or viral DNA replication, their function remains uncertain.     

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.     

Structure and heterogeneity of the a sequences of human herpesvirus 6 strain variants U1102 and Z29 and identification of human telomeric repeat sequences at the genomic termini.

The unit-length genome of human herpesvirus 6 (HHV-6) consists of a single unique component (U) bounded by direct repeats DRL and DRR and forms head-to-tail concatemers during productive infection. cis-elements which mediate cleavage and packaging of progeny virions (a sequences) are found at the termini of all herpesvirus genomes. In HHV-6, DRL and DRR are identical and a sequences may therefore also occur at the U-DR junctions to give the arrangement aDRLa-U-aDRRa. We have sequenced the genomic termini, the U-DRR junction, and the DRR.DRL junction of HHV-6 strain variants U1102 and Z29. A (GGGTTA)n motif identical to the human telomeric repeat sequence (TRS) was found adjacent to, but did not form, the termini of both strain variants. The DRL terminus and U-DRR junction contained sequences closely related to that of the well-conserved herpesvirus packaging signal Cn-Gn-Nn-Gn (pac-1), followed by tandem arrays of TRSs separated by single copies of a hexanucleotide repeat. HHV-6 strain U1102 contained repeat sequences not found in HHV-6 Z29. In contrast, the DRR terminus of both variants contained a simple tandem array of TRSs and a close homolog of a herpesvirus pac-2 signal (GCn-Tn-GCn). The DRR.DRL junction was formed by simple head-to-tail linkage of the termini, yielding an intact cleavage signal, pac-2.x.pac-1, where x is the putative cleavage site. The left end of DR was the site of intrastrain size heterogeneity which mapped to the putative a sequences. These findings suggest that TRSs form part of the a sequence of HHV-6 and that the arrangement of a sequences in the genome can be represented as aDRLa-U-a-DRRa.     

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.     

Structure and role of the herpes simplex virus DNA termini in inversion, circularization and generation of virion DNA

The herpes simplex virus genome consists of two components, L and S, which invert relative to each other during viral replication. The a sequence is present at the genomic termini in direct orientation and at the L-S junction in inverted orientation. Previously, we showed that insertion of a fragment spanning the L-S junction into the viral genome causes additional inversions. In this study, we determine the nucleotide sequence of the genomic termini and show that insertion of either the free S terminus or the L terminus causes inversions in the viral genome. We conclude that the a sequence is the inversion-specific sequence, that linear unit-length molecules packaged in virions are generated by cleavage between adjacent copies of the a sequence, that cleavage produces 3' single-base extensions on the genomic termini and that the signal for cleavage is contained within the a sequence.     

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.     

Sequence requirements for DNA rearrangements induced by the terminal repeat of herpes simplex virus type 1 KOS DNA.

We investigated the sequence requirements for the site-specific DNA cleavages and recombinational genome isomerization events driven by the terminal repeat or a sequence of herpes simplex virus type 1 KOS DNA by inserting a series of mutated a sequences into the thymidine kinase locus in the intact viral genome. Our results indicate that sequences located at both extremities of the a sequence contribute to these events. Deletions entering from the Ub side of the a sequence progressively reduced the frequency of DNA rearrangements, and further deletion of the internal DR2 repeat array had an additional inhibitory effect. This deletion series allowed us to map the pac1 site-specific DNA cleavage signal specifying the S-terminal cleavage to a sequence that is conserved among herpesvirus genomes. Constructs lacking this signal were unable to directly specify the S-terminal cleavage event but retained a reduced ability to give rise to S termini following recombination with intact a sequences. Deletions entering from the Uc side demonstrated that the copy of direct repeat 1 located adjacent to the Uc region plays an important role in the DNA rearrangements induced by the a sequence: mutants lacking this sequence displayed a reduced frequency of novel terminal and recombinational inversion fragments, and further deletions of the Uc region had a relatively minor additional effect. By using a construct in which site-specific cleavage was directed to heterologous DNA sequences, we found that the recombination events leading to genome segment inversion did not occur at the sites of DNA cleavage used by the cleavage-packaging machinery. This observation, coupled with the finding that completely nonoverlapping portions of the a sequence retained detectable recombinational activity, suggests that inter-a recombination does not occur by cleavage-ligation at a single specific site in herpes simplex virus type 1 strain KOS. The mutational sensitivity of the extremities of the a sequence leads us to hypothesize that the site-specific DNA breaks induced by the cleavage-packaging system stimulate the initiation of recombination.     

A 128-base-pair sequence containing the pac1 and a presumed cryptic pac2 sequence includes cis elements sufficient to mediate efficient genome maturation of human cytomegalovirus

Herpesvirus DNA replication proceeds via concatemeric replicative intermediates that are comprised of head-to-tail linked genomes. Genome maturation is carried out by the terminase, an enzyme complex that mediates both the insertion of concatemer DNA into capsids and its subsequent cleavage to release genomes within these capsids. This cleavage is sequence specific, but the governing cis-acting DNA sequences are only partially characterized. Two highly conserved motifs, the pac1 and pac2 motifs, lie near the ends of herpesvirus genomes and are known to be critical for genome maturation. In murine cytomegalovirus, poorly conserved sequences distal to the pac2 motif up to 150 bp from the point of cleavage are also important for cleavage. Here, we sought to identify the cleavage/packaging signals of human cytomegalovirus. Our results show that a previously proposed pac2-like poly(A) tract is dispensable for cleavage/packaging function and suggest that human cytomegalovirus may utilize a cryptic pac2 motif that lacks a poly(A) tract characteristic of pac2 motifs in other herpesviruses. Additional distal sequences 47 to 100 bp from the point of cleavage were found to enhance cleavage efficiency. These results should facilitate the identification of trans-acting factors that bind to these cis elements and elucidation of their functions. Such information will be critical for understanding the molecular basis of this complex process.     

Terminally Repeated Sequences on a Herpesvirus Genome Are Deleted following Circularization but Are Reconstituted by Duplication during Cleavage and Packaging of Concatemeric DNA

The mechanisms underlying cleavage of herpesvirus genomes from replicative concatemers are unknown. Evidence from herpes simplex virus type 1 suggests that cleavage occurs by a nonduplicative process; however, additional evidence suggests that terminal repeats may also be duplicated during the cleavage process. This issue has been difficult to resolve due to the variable numbers of reiterated terminal repeats that the herpes simplex virus type 1 genome can contain. Guinea pig cytomegalovirus is a herpesvirus with a simple terminal repeat arrangement that defines two genome types. Type II genomes have a single copy of a 1-kb terminal repeat at both their left and right termini, whereas type I genomes have only one copy at their left termini and lack the repeat at their right termini. In a previous study, we constructed a recombinant guinea pig cytomegalovirus in which certain cis elements were disrupted such that only type II genomes were produced. Here we show that double repeats that are formed by circularization of infecting genomes are rapidly converted to single repeats, such that the junctions between genomes within replicative concatemers formed late in infection almost exclusively contain single copies of the terminal repeat. Therefore, for the recombinant virus, each cleavage event begins with a single repeat within a concatemer yet produces two repeats, one at each of the resulting termini, demonstrating that terminal repeat duplication occurs in conjunction with cleavage. For wild-type guinea pig cytomegalovirus, the formation of type I genomes further suggests that cleavage can also occur by a nonduplicative process and that duplicative and nonduplicative cleavage can occur concurrently. Other herpesviruses having terminal repeats, such as the herpes simplex viruses and human cytomegalovirus, may also utilize repeat duplication and deletion; however, the biological importance of these events remains unknown.     

Deletion mutants of simian virus 40 generated by enzymatic excision of DNA segments from the viral genome

Deleted genomes of simian virus 40 have been constructed by enzymatic excision of specific segments of DNA from the genome of wild-type SV40². For this purpose, a restriction endonuclease from Hemophilus influenzae (endo R · HindIII) was used. This enzyme cleaves SV40 DNA into six fragments, which have cohesive termini. Partial digest products were separated by electrophoresis in agarose gel and subsequently cloned by plaque formation in the presence of complementing temperature-sensitive mutants of SV40. Individual deletion mutants generated in this way were mapped by analysis of DNA fragments produced by endo R · Hind digestion of their deleted genomes, and by heteroduplex mapping. Two types of deletions were found: (1) “excisional” deletions, in which the limits of the deleted segment corresponded to HindIII cleavage sites, and (2) “extended” deletions, in which the deleted segment extended beyond HindIII cleavage sites. Excisionally deleted genomes presumably arose by cyclization of a linear fragment via cohesive termini generated by endo R · HindIII whereas genomes with extended deletions probably were generated by intramolecular recombination near the ends of linear fragments. Of the nine mutants analyzed, two had deletions in the “early” region of the SV40 genome, six had deletions in the “late” region, and one had a deletion that spanned both regions.     

The alpha sequence of the cytomegalovirus genome functions as a cleavage/packaging signal for herpes simplex virus defective genomes.

Although herpes simplex virus (HSV) 1 and human cytomegalovirus (CMV) differ remarkably in their biological characteristics and do not share nucleotide sequence homology, they have in common a genome structure that undergoes sequence isomerization of the long (L) and short (S) components. We have demonstrated that the similarity in their genome structures extends to the existence of an alpha sequence in the CMV genome as previously defined for the HSV genome. As such, the alpha sequence is predicted to participate as a cis-replication signal in four viral functions: (i) inversion, (ii) circularization, (iii) amplification, and (iv) cleavage and packaging of progeny viral DNA. We have constructed a chimeric HSV-CMV amplicon (herpesvirus cis replication functions carried on an Escherichia coli plasmid vector) substituting CMV DNA sequences for the HSV cleavage/packaging signal in a test of the ability of this CMV L-S junction sequence to provide the cis signal for cleavage/packaging in HSV 1-infected cells. We demonstrate that the alpha sequence of CMV DNA functions as a cleavage/packaging signal for HSV defective genomes. We show the structure of this sequence and provide a functional demonstration of cross complementation in replication signals which have been preserved over evolutionary time in these two widely divergent human herpesviruses.     

Functional complementation of UL3.5-negative pseudorabies virus by the bovine herpesvirus 1 UL3.5 homolog.

The UL3.5 gene is positionally conserved but highly variable in size and sequence in different members of the Alphaherpesvirinae and is absent from herpes simplex virus genomes. We have shown previously that the pseudorabies virus (PrV) UL3.5 gene encodes a nonstructural protein which is required for secondary envelopment of intracytoplasmic virus particles in the trans-Golgi region. In the absence of UL3.5 protein, naked nucleocapsids accumulate in the cytoplasm, release of infectious virions is drastically reduced, and plaque formation in cell culture is inhibited (W. Fuchs, B. G. Klupp, H. Granzow, H.-J. Rziha, and T. C. Mettenleiter, J. Virol. 70:3517-3527, 1996). To assay functional complementation by a heterologous herpesviral UL3.5 protein, the UL3.5 gene of bovine herpesvirus 1 (BHV-1) was inserted at two different sites within the genome of UL3.5-negative PrV. In cells infected with the PrV recombinants the BHV-1 UL3.5 gene product was identified as a 17-kDa protein which was identical in size to the UL3.5 protein detected in BHV-1-infected cells. Expression of BHV-1 UL3.5 compensated for the lack of PrV UL3.5, resulting in a ca. 1,000-fold increase in virus titer and restoration of plaque formation in cell culture. Also, the intracellular block in viral egress was resolved by the BHV-1 UL3.5 gene. We conclude that the UL3.5 proteins of PrV and BHV-1 are functionally related and are involved in a common step in the egress of alphaherpesviruses.     

Molecular cloning and physical mapping of the tupaia herpesvirus genome.

Purified virion DNA of about 200 kilobase pairs of tupaia herpesvirus strain 2 was cleaved with EcoRI or HindIII restriction endonuclease. Restriction fragments representing the complete viral genome including both termini were inserted into the EcoRI, HindIII, and EcoRI-HindIII sites of the bacterial plasmid pAT153. Restriction maps for the restriction endonucleases EcoRI and HindIII were constructed with data derived from Southern blot hybridizations of individual viral DNA fragments or cloned DNA fragments which were hybridized to either viral genome fragments or recombinant plasmids. The analysis revealed that the tupaia herpesvirus genome consists of a long unique sequence of 200 kilobase pairs and that inverted repeat DNA sequences of greater than 40 base pairs do not occur, in agreement with previous electron microscopic data. No DNA sequence homology was detectable between the tupaia herpesvirus DNA and the genome of murine cytomegalovirus, which was reported to have a similar structure. In addition, seven individual isolates of tupaia herpesvirus were characterized. The isolates can be grouped into five strains by their DNA cleavage patterns.     

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.     

Nucleotide sequence and characterization of a repetitive DNA element from the genome of Bordetella pertussis with characteristics of an insertion sequence

A repeating element of DNA has been isolated and sequenced from the genome of Bordetella pertussis. Restriction map analysis of this element shows single internal ClaI, SphI, BstEII and SalI sites. Over 40 DNA fragments are seen in ClaI digests of B. pertussis genomic DNA to which the repetitive DNA sequence hybridizes. Sequence analysis of the repeat reveals that it has properties consistent with bacterial insertion sequence (IS) elements. These properties include its length of 1053 bp, multiple copy number and presence of 28 bp of near-perfect inverted repeats at its termini. Unlike most IS elements, the presence of this element in the B. pertussis genome is not associated with a short duplication in the target DNA sequence. This repeating element is not found in the genomes of B. parapertussis or B. bronchiseptica. Analysis of a DNA fragment adjacent to one copy of the repetitive DNA sequence has identified a different repeating element which is found in nine copies in B. parapertussis and four copies in B. pertussis, suggesting that there may be other repeating DNA elements in the different Bordetella species. Computer analysis of the B. pertussis repetitive DNA element has revealed no significant nucleotide homology between it and any other bacterial transposable elements, suggesting that this repetitive sequence is specific for B. pertussis.     

Proteolytic cleavage of bovine herpesvirus 1 (BHV-1) glycoprotein gB is not necessary for its function in BHV-1 or pseudorabies virus.

Glycoprotein B homologs represent the most highly conserved group of herpesvirus glycoproteins. They exist in oligomeric forms based on a dimeric structure. Despite the high degree of sequence and structural conservation, differences in posttranslational processing are observed. Whereas gB of herpes simplex virus is not proteolytically processed after oligomerization, most other gB homologs are cleaved by a cellular protease into subunits that remain linked via disulfide bonds. Proteolytic cleavage is common for activation of viral fusion proteins, and it has been shown that herpesvirus gB homologs are essential for membrane fusion events during infection, e.g., virus penetration and direct viral cell-to-cell spread. To analyze the importance of proteolytic cleavage for the function of gB homologs, we isolated a mutant bovine herpesvirus 1 (BHV-1) expressing a BHV-1 gB that is no longer proteolytically processed because of a deletion of the proteolytic cleavage site and analyzed its phenotype in cell culture. We showed previously that BHV-1 gB can functionally substitute for the homologous glycoprotein in pseudorabies virus (PrV), based on the isolation of a PrV gB-negative PrV recombinant that expresses BHV-1 gB (A. Kopp and T. C. Mettenleiter, J. Virol, 66:2754-2762, 1992). Therefore, we also isolated a mutant PrV lacking PrV gB but expressing a noncleavable BHV-1 gB. Our results show that cleavage of BHV-1 gB is not essential for its function in either a BHV-1 or a PrV background. Compared with the PrV recombinant expressing cleavable BHV-1 gB, deletion of the cleavage site in the recombinant PrV did not detectably alter the viral phenotype, as analyzed by plaque assays, one-step growth kinetics, and penetration kinetics. In the BHV-1 mutant, the uncleaved BHV-1 gB was functionally equivalent to the wild-type protein with regard to penetration and showed only slightly delayed one-step growth kinetics compared with parental wild-type BHV-1. However, the resulting plaques were significantly smaller, indicating a role for proteolytic cleavage of BHV-1 gB in cell-to-cell spread of BHV-1.