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

Rapid identification of essential and nonessential herpesvirus genes by direct transposon mutagenesis

Herpesviruses are important pathogens in animals and humans. The large DNA genomes of several herpesviruses have been sequenced, but the function of the majority of putative genes is elusive. Determining which genes are essential for their replication is important for identifying potential chemotherapy targets, designing herpesvirus vectors, and generating attenuated vaccines. For this purpose, we recently reported that herpesvirus genomes can be maintained as infectious bacterial artificial chromosomes (BAC) in Escherichia coli. Here we describe a one-step procedure for random-insertion mutagenesis of a herpesvirus BAC using a Tn1721-based transposon system. Transposon insertion sites were determined by direct sequencing, and infectious virus was recovered by transfecting cultured cells with the mutant genomes. Lethal mutations were rescued by cotransfecting cells containing noninfectious genomes with the corresponding wild-type subgenomic fragments. We also constructed revertant genomes by allelic exchange in bacteria. These methods, which are generally applicable to any cloned herpesvirus genome, will facilitate analysis of gene function for this virus family.

Expression analysis of recombinant herpes simplex virus type 1 DNase

Expression of recombinant herpes simplex virus type 1 (HSV-1) deoxyribonuclease (DNase) was analyzed in BHK-21 cells, a standard cell line for virus propagation, by using mammalian cell expression systems based on vaccinia virus and on Semliki Forest virus (SFV)1. Although the establishing of recombinant vaccinia virus failed due to the apparent toxicity of the herpesviral enzyme, soluble and functional HSV-1 DNase was efficiently expressed in BHK-21 cells by the vaccinia virus/T7 RNA polymerase hybrid system as well as by recombinant Semliki Forest virus. Using rabbit antiserum ExoC, directed against the C-terminal residues 503-626, or mouse monoclonal antibody (MAb) Q1, raised against the type 2 enzyme, a major 85-kDa protein with the identical size of the enzyme from HSV-1-infected cells was identified to be induced in both expression systems. With recombinant SFV functional HSV-1 DNase coincided with the overproduction of a single major 85-kDa protein reaching an optimum between 16 h and 36 h after infection. At later times of infection the enzymatic activity vanished. Thus, recombinant SFV may be an appropriate expression vector for biochemical studies of the enzyme when (i) packaged recombinant virus particles are used for infection and (ii) infection does not exceed 24 h. Due to the limitations of transient expression systems, the vaccinia/T7 RNA polymerase hybrid system is suited for expression analysis on a small scale, and for studying intracellular interactions of the enzyme as demonstrated by immunofluorescence microscopy studies. Using vector pTM1, recombinant HSV-1 DNase was efficiently overproduced in BHK-21 cells at 6 h after transfection and was shown to colocalize with the cellular chromatin at sites apparently distinct from the bulk of the herpesviral replication sites the way it is observed for the enzyme of lytically infected cells. The deleting of the 123 C-terminal amino acid residues did not alter this nuclear localization of HSV-1 DNase, suggesting that the latter sequences and other herpesviral factors are not required for the chromatin association.

In vitro processing of herpes simplex virus type 1 DNA replication intermediates by the viral alkaline nuclease, UL12

Herpes simplex virus type 1 (HSV-1) DNA replication intermediates exist in a complex nonlinear structure that does not migrate into a pulsed-field gel. Genetic evidence suggests that the product of the UL12 gene, termed alkaline nuclease, plays a role in processing replication intermediates (R. Martinez, R. T. Sarisky, P. C. Weber, and S. K. Weller, J. Virol. 70:2075-2085, 1996). In this study we have tested the hypothesis that alkaline nuclease acts as a structure-specific resolvase. Cruciform structures generated with oligonucleotides were treated with purified alkaline nuclease; however, instead of being resolved into linear duplexes as would be expected of a resolvase activity, the artificial cruciforms were degraded. DNA replication intermediates were isolated from the well of a pulsed-field gel ("well DNA") and treated with purified HSV-1 alkaline nuclease. Although alkaline nuclease can degrade virion DNA to completion, digestion of well DNA results in a smaller-than-unit-length product that migrates as a heterogeneous smear; this product is resistant to further digestion by alkaline nuclease. The smaller-than-unit-length products are representative of the entire HSV genome, indicating that alkaline nuclease is not inhibited at specific sequences. To further probe the structure of replicating DNA, well DNA was treated with various known nucleases; our results indicate that replicating DNA apparently contains no accessible double-stranded ends but does contain nicks and gaps. Our data suggest that UL12 functions at nicks and gaps in replicating DNA to correctly repair or process the replicating genome into a form suitable for encapsidation.

Functional conservations of the alkaline nuclease of herpes simplex type 1 and human cytomegalovirus

The herpes simplex virus type 1 UL12 gene product, alkaline nuclease (AN), appears to be involved in viral DNA processing and capsid egress from the nucleus (Shao, L., Rapp, L. M., and Weller, S. K., Virology 196, 146-162, 1993). Although the HSV-1 AN is not absolutely essential for viral replication in tissue culture, conservation of the AN gene in all herpesviruses suggests an important role in the life cycle of herpesviruses. The counterpart of HSV-1 AN for human cytomegalovirus (HCMV) is the UL98 gene product. To examine whether the HCMV AN could substitute for HSV-1 AN, we performed trans-complementation experiments using a HSV-1 amplicon plasmid carrying the HCMV UL98 gene. Our results indicate (i) HCMV AN can complement the growth of the HSV-1 AN deletion mutant UL12lacZ virus in trans; (ii) a new recombinant virus, UL12laZcUL98/99, appears to be generated by the integration of the HCMV UL98 gene into the HSV-1 UL12lacZ viral genome; (iii) in contrast to its parental HSV-1 UL12lacZ virus, capsids formed in UL12lacZUL98/99-infected Vero cells were able to transport from the nucleus to the cytoplasm and mature into infectious viruses. Our results demonstrate a functional conservation of AN between HSV-1 and HCMV.

Epstein-Barr virus DNase contains two nuclear localization signals, which are different in sensitivity to the hydrophobic regions

The DNase of Epstein-Barr virus (EBV) is a 470-amino-acid protein which possesses both endonuclease and exonuclease activities and accepts both double-stranded DNA and single-stranded DNA as substrates. It has been reported that this protein may be found in the nucleus and/or cytoplasm of infected cells. In this study, using cell fractionation and immunoblotting to determine the distribution of EBV DNase in Akata cells stimulated with anti-human immunoglobulin G antibody (anti-IgG), the DNase was found to be located predominantly in the nucleus. To map the signals in DNase which mediate its nuclear localization, we monitored the nuclear transport of fusion proteins consisting of various fragments of EBV DNase linked to a cytoplasmic protein, beta-galactosidase (beta-Gal). The results demonstrated that two regions of the DNase with nuclear localization signal (NLS) activity, designated NLS-A (amino acids 239-266) and NLS-B (amino acids 291-306), were able independently to localize the beta-Gal to the nuclei of HEp-2 and HeLa cells. Five basic residues (R or K) were found in each NLS and distributed differently in primary structure. The basic domains and flanking residues of NLS-A and NLS-B are 250YKRPCKRSFIRFI262 and 294LKDVRKRKLGPGH306, respectively. Further examination of these sequences revealed that NLS-A contains bulky aromatic amino acids (Y and F) which may diminish its capacity to act as a strong NLS and lacks the typical proline and glycine helix-breakers. However, NLS-B contains typical proline and glycine helix-breakers and the histidine residue at amino acid 306 is required for NLS activity. In addition, two hydrophobic regions within the DNase were found to inhibit the function of NLS-A but not NLS-B, suggesting that these two domains are different types of NLSs and differ in their sensitivity to hydrophobic regions in the context of protein structure.

Human cytomegalovirus oriLyt sequence requirements

The mechanisms of action and regulation of the human cytomegalovirus (HCMV) lytic-phase DNA replicator, oriLyt, which spans more than 2 kbp in a structurally complex region near the middle of the unique long region (UL), are not understood. Because oriLyt is thought to be essential for promoting initiation of lytic DNA synthesis and may participate in regulating the switch between lytic and latent phases, we undertook a mutational study to better define its sequence requirements. Kanr gene cassette insertions located an oriLyt core region between nucleotides (nt) 91751 and 93299 that is necessary but not sufficient for replicator activity in transient assays. In contrast, insertions into auxiliary regions flanking either side of this core-also required for significant replicator activity-had little effect. To search for essential components within the core region, we made a series of overlapping, roughly 200-bp deletions, and qualitatively and quantitatively assessed the abilities of the resulting constructs to mediate replication. All but one of these deletions produced a significant (i.e., greater than twofold) loss of activity, arguing that sequences across this entire region contribute to replicator function. However, two particularly critical segments separated by a dispensable region, here called essential regions I and II, were identified. Within essential region I, which overlaps the previously identified early transcript SRT, two adjacent but nonoverlapping, roughly 200-bp deletions abolished detectable replication. No single element or motif from the left half of essential region I was found to be essential. Thus, essential region I probably promotes replication through the cooperation of multiple elements. However, four small deletions in the right half of essential region I, which included or lay adjacent to the conserved 31-nt oligopyrimidine tract (referred to as the Y block), abolished or virtually abolished oriLyt activity. Together, these results identify candidate oriLyt sequences within which molecular interactions essential for initiation of oriLyt-mediated DNA synthesis are likely to occur.

The exonuclease activity of HSV-1 UL12 is required for in vivo function

The herpes simplex virus type 1 (HSV-1) UL12 gene encodes an alkaline pH-dependent deoxyribonuclease termed alkaline nuclease. A recombinant UL12 knockout mutant, AN-1, is severely compromised for growth, and analysis of this mutant suggests that UL12 plays a role in processing complex DNA replication intermediates (R. Martinez, R. T. Sarisky, P. C. Weber, and S. K. Weller, (1996) J. Virol. 70, 2075-2085). This processing step may be required for the generation of capsids that are competent for egress from the nucleus to the cytoplasm. In this report, we address the question of whether the AN-1 growth phenotype is due to the loss of UL12 catalytic activity. We constructed two point mutations in a highly conserved region (motif II) of UL12 and purified wild-type and mutant enzymes from a baculovirus expression system. Both mutant proteins are stable, soluble, and competent for correct nuclear localization, suggesting that they have retained an intact global conformation. Neither mutant protein, however, exhibits exonuclease activity. In order to examine the in vivo effects of these mutations, we determined whether expression of mutant proteins from amplicon plasmids could complement AN-1. While the wild-type plasmid complements the growth of the null mutant, neither UL12 mutant can do so. Loss of exonuclease activity therefore correlates with loss of in vivo function.

Combined effects of interferon-alpha and acyclovir on herpes simplex virus type 1 DNA polymerase and alkaline DNase

Treatment of cells with combinations of human interferon-alpha (IFN-alpha) and the nucleoside analog, acyclovir (ACV), leads to the synergistic inhibition of herpes simplex virus type 1 (HSV-1) replication. We have examined the effect of these agents on the replication of HSV-1 DNA and the synthesis of early viral enzymes to understand the mechanism(s) responsible for this synergistic activity. Combination treatment with 100 IU/ml IFN-alpha and 5 microM ACV led to HSV-1 DNA levels more than 8-fold lower than in cells treated with ACV alone, while IFN-alpha treatment alone had no detectable effect on viral DNA synthesis. Steady state levels of DNA polymerase were reduced approximately 50% by IFN-alpha and 25% by ACV, but combination treatment did not decrease enzyme levels to an extent greater than the sum of these effects. In contrast, the activity of another early viral enzyme, alkaline DNase, was reduced less than 20% by IFN-alpha alone or combination treatment and was unaffected by ACV treatment. No decrease in the level of mRNA encoding either enzyme was detected in IFN-alpha-treated cells although ACV treatment reduced polymerase mRNA levels. These studies suggest that the synergistic anti-HSV activities of IFN-alpha with ACV could be mediated, in part, through some post-transcriptional mechanism induced by IFN-alpha treatment, leading to the reduction in production of viral early enzymes, especially DNA polymerase.

Functional expression of the bovine herpesvirus 1 alkaline deoxyribonuclease (UL12) in Escherichia coli

Sequence analysis within the unique long segment of the bovine herpesvirus 1 (BHV-1; infectious bovine rhinotracheitis virus) genome identified an open reading frame whose deduced protein product of 487 amino acids exhibited homology to alkaline deoxyribonucleases (DNases) of other herpesviruses. To determine this BHV-1 gene product has nuclease activity, the gene designated UL12 was inserted into the vector pET-28a(+) and expressed in Escherichia coli as an oligohistidine-tagged protein. Upon induction with isopropyl beta-D-thiogalactopyranoside E. coli BL21 (DE3) [pLysS] cells carrying this recombinant plasmid produced a 57-kDa protein, the molecular mass of which was in accordance with the prediction from the DNA sequence. The recombinant UL12 protein purified by nickel-chelating affinity chromatography exhibited both exonuclease and endonuclease activity, each with an alkaline pH optimum.

Herpes simplex virus DNA packaging without measurable DNA synthesis

Herpes simplex virus (HSV) type 1 DNA synthesis and packaging occur within the nuclei of infected cells; however, the extent to which the two processes are coupled remains unclear. Correct packaging is thought to be dependent upon DNA debranching or other repair processes, and such events commonly involve new DNA synthesis. Furthermore, the HSV UL15 gene product, essential for packaging, nevertheless localizes to sites of active DNA replication and may link the two events. It has previously been difficult to determine whether packaging requires concomitant DNA synthesis due to the complexity of these processes and of the viral life cycle; however, we have recently described a model system which simplifies the study of HSV assembly. Cells infected with HSV strain tsProt.A accumulate unpackaged capsids at the nonpermissive temperature of 39 degrees C. Following release of the temperature block, these capsids proceed to package viral DNA in a single, synchronous wave. Here we report that, when DNA replication was inhibited prior to release of the temperature block, DNA packaging and later events in viral assembly nevertheless occurred at near-normal levels. We conclude that, under our conditions, HSV DNA packaging does not require detectable levels of DNA synthesis.

Genetic analysis of the UL 15 gene locus for the putative terminase of herpes simplex virus type 1

The herpes simplex virus (HSV-1) UL15 gene encodes one of the six viral gene products required for viral DNA cleavage and packaging. UL15 is a spliced gene and encodes two separately translated proteins, UL15 and UL15.5. Sequence analysis reveals that UL15 shares homology with gp 17, the large catalytic subunit of the bacteriophage T4 terminase, a protein which cleaves the polymeric T4 DNA into monomers. Both proteins contain a putative ATP binding motif known as the Walker A and B boxes. In this report, immunofluorescence was used to show that UL15 localizes to the nucleus in the absence of any other viral proteins; this indicates that UL15 contains its own nuclear localization signal. In addition, we found that UL15 colocalizes with replication compartments at early times (6 h postinfection). Since, at this time, preformed capsids as well as other cleavage and packaging proteins are also recruited to replication compartments, it seems likely that cleavage and packaging occurs in the same compartments in which DNA synthesis occurs. Also in this report, we have investigated UL15.5, the N-terminally truncated gene product of the UL15 open reading frame (ORF). The start codon has been mapped to Met443 within the UL15 ORF. Furthermore, we have shown that plasmids containing a UL15.5 knockout mutation still complement the growth of UL15 insertion mutant viruses, indicating that UL15.5 is not required for viral growth in cell culture. Last, we constructed a UL15 mutant, UL15C(G263A), in which the invariant Gly263 in the Walker box A of the ATP binding motif (GKT) was substituted with an alanine. We show that the mutant gene fails to support the growth of UL15 insertion mutant viruses, indicating that the putative ATP binding motif of UL15 is indispensable for its function.

Structure-function analysis of the herpes simplex virus type 1 UL12 gene: correlation of deoxyribonuclease activity in vitro with replication function

Although the product of the UL12 gene of herpes simplex virus type 1 (HSV-1) has been shown to possess both exonuclease and endonuclease activities in vitro, and deletion of most of the gene within the viral genome results in inefficient production and maturation of infectious virions, the function of the deoxyribonuclease (DNase) activity per se in virus replication remains unclear. In order to correlate the in vitro and in vivo activities of the protein encoded by UL12, mutant proteins were tested for nuclease activity in vitro by a novel hypersensitivity cleavage assay and for their ability to complement the replication of a DNase null mutant, AN-1. Rabbit reticulocyte lysates programmed with wild-type UL12 RNA cleaved at the same sites cleaved by purified HSV-1 DNase, but distinct from those cleaved by DNase 1 or micrococcal nuclease. All mutants which lacked DNase activity in vitro also failed to complement the replication of AN-1 in nonpermissive cells. Likewise, all mutants which contained HSV-1 DNase activity, as detected by the hypersensitivity cleavage assay, were capable of complementing the replication of the DNase null mutant, though to varying extents. Of particular note was the d1-126 mutant protein, which, despite having the same specific activity as the wild-type enzyme in vitro, complemented the replication of AN-1 significantly less than the wild-type protein. The results suggest that DNase activity per se is required for efficient replication of HSV-1 in vivo. However, residues, including the N-terminal 126 amino acids, which are dispensable for enzymatic activity in vitro may facilitate the accessibility or activity of the protein in vivo.

The herpes simplex virus type 1 cleavage/packaging protein, UL32, is involved in efficient localization of capsids to replication compartments

Six genes, including UL32, have been implicated in the cleavage and packaging of herpesvirus DNA into preassembled capsids. We have isolated a UL32 insertion mutant which is capable of near-wild-type levels of viral DNA synthesis; however, the mutant virus is unable to cleave and package viral DNA, consistent with the phenotype of a previously isolated temperature-sensitive herpes simplex virus type 1 mutant, tsN20 (P. A. Schaffer, G. M. Aron, N. Biswal, and M. Benyesh-Melnick, Virology 52:57-71, 1973). A polyclonal antibody which recognizes UL32 was previously used by Chang et al. (Y. E. Chang, A. P. Poon, and B. Roizman, J. Virol. 70:3938-3946, 1996) to demonstrate that UL32 accumulates predominantly in the cytoplasm of infected cells. In this report, a functional epitope-tagged version of UL32 showed that while UL32 is predominantly cytoplasmic, some nuclear staining which colocalizes with the major DNA binding protein (ICP8, UL29) in replication compartments can be detected. We have also used a monoclonal antibody (5C) specific for the hexon form of major capsid protein VP5 to study the distribution of capsids during infection. In cells infected with wild-type KOS (6 and 8 h postinfection), 5C staining patterns indicate that capsids are present in nuclei within replication compartments. These results suggest that cleavage and packaging occur in replication compartments at least at 6 and 8 h postinfection. Cells infected with the UL32 mutant exhibit a hexon staining pattern which is more diffusely distributed throughout the nucleus and which is not restricted to replication compartments. We propose that UL32 may play a role in "bringing" preassembled capsids to the sites of DNA packaging and that the failure to localize to replication compartments may explain the cleavage/packaging defect exhibited by this mutant. These results suggest that the UL32 protein is required at a step distinct from those at which other cleavage and packaging proteins are required and may be involved in the correct localization of capsids within infected cells.

Recombinant pseudorabies virus DNase exhibits a RecBCD-like catalytic function

The pseudorabies virus (PRV) DNase gene has previously been mapped within the PRV genome. To characterize further the enzymic properties of PRV DNase, this enzyme was expressed in Escherichia coli with the use of a pET expression vector. The protein was purified to homogeneity and assayed for nuclease activity in vitro. Recombinant PRV DNase exhibited an alkaline pH preference and an absolute requirement for Mg2+ ions that could not be replaced by Ca2+ and Na+ ions. Further studies showed that PRV DNase exhibited endonuclease, 5'-exonuclease and 3'-exonuclease activities in both single-stranded and double-stranded DNA. This activity occurred randomly and no significant base preference was demonstrated. The multiple biochemical activities of PRV DNase are similar to the activities of Neurospora crassa endo-exonuclease and E. coli RecBCD, two additional enzymes that are involved in recombination. Taken together, the similarity of action between N. crassa endo-exonuclease, E. coli RecBCD, and PRV DNase suggests that PRV DNase might have a role in the process of recombination that occurs during PRV infection.

The product of the herpes simplex virus type 1 UL25 gene is required for encapsidation but not for cleavage of replicated viral DNA

The herpes simplex virus type 1 (HSV-1) UL25 gene contains a 580-amino-acid open reading frame that codes for an essential protein. Previous studies have shown that the UL25 gene product is a virion component (M. A. Ali et al., Virology 216:278-283, 1996) involved in virus penetration and capsid assembly (C. Addison et al., Virology 138:246-259, 1984). In this study, we describe the isolation of a UL25 mutant (KUL25NS) that was constructed by insertion of an in-frame stop codon in the UL25 open reading frame and propagated on a complementing cell line. Although the mutant was capable of synthesis of viral DNA, it did not form plaques or produce infectious virus in noncomplementing cells. Antibodies specific for the UL25 protein were used to demonstrate that KUL25NS-infected Vero cells did not express the UL25 protein. Western immunoblotting showed that the UL25 protein was associated with purified, wild-type HSV A, B, and C capsids. Transmission electron microscopy indicated that the nucleus of Vero cells infected with KUL25NS contained large numbers of both A and B capsids but no C capsids. Analysis of infected cells by sucrose gradient sedimentation analysis confirmed that the ratio of A to B capsids was elevated in KUL25NS-infected Vero cells. Following restriction enzyme digestion, specific terminal fragments were observed in DNA isolated from KUL25NS-infected Vero cells, indicating that the UL25 gene was not required for cleavage of replicated viral DNA. The latter result was confirmed by pulsed-field gel electrophoresis (PFGE), which showed the presence of genome-size viral DNA in KUL25NS-infected Vero cells. DNase I treatment prior to PFGE demonstrated that monomeric HSV DNA was not packaged in the absence of the UL25 protein. Our results indicate that the product of the UL25 gene is required for packaging but not cleavage of replicated viral DNA.

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.

Sequences within the herpesvirus-conserved pac1 and pac2 motifs are required for cleavage and packaging of the murine cytomegalovirus genome

The DNA sequence motifs pac1 [an A-rich region flanked by poly(C) runs] and pac2 (CGCGGCG near an A-rich region) are conserved near herpesvirus genomic termini and are believed to mediate cleavage of genomes from replicative concatemers. To determine their importance in the cleavage process, we constructed a number of recombinant murine cytomegaloviruses with a second cleavage site inserted at an ectopic location within the viral genome. Cleavage at a wild-type ectopic site occurred as frequently as at the natural cleavage site, whereas mutation of this ectopic site revealed that some of the conserved motifs of pac1 and pac2 were essential for cleavage whereas others were not. Within pac1, the left poly(C) region was very important for cleavage and packaging but the A-rich region was not. Within pac2, the A-rich region and adjacent sequences were essential for cleavage and packaging and the CGCGGCG region contributed to, but was not strictly essential for, efficient cleavage and packaging. A second A-rich region was not important at all. Furthermore, mutations that prevented cleavage also blocked duplication and deletion of the murine cytomegalovirus 30-bp terminal repeat at the ectopic site, suggesting that repeat duplication and deletion are consequences of cleavage. Given that the processes of genome cleavage and packaging appear to be highly conserved among herpesviruses, these findings should be relevant to other members of this family.

A major DNA binding protein encoded by BALF2 open reading frame of Epstein-Barr virus (EBV) forms a complex with other EBV DNA-binding proteins: DNAase, EA-D, and DNA polymerase

A major 135-kDa DNA binding protein (mDBP) encoded by the BALF2 open reading frame of Epstein-Barr Virus (EBV) is known to be an essential protein for the induction of the lytic cycle. The present investigation was carried out to know whether this protein forms a complex in vivo with other viral DNA binding proteins (DBP) involved in DNA replication: DNA polymerase, EA-D (diffused early antigen), and DNAase. Immunoprecipitation assays followed by mono- and two-dimensional electrophoresis showed that mDBP forms a complex with these three DBP. Other complexes were also found such as EA-D/DNAase, DNA polymerase/DNAase, and DNA polymerase/EA-D. The complexed forms already exist in the early stage of EBV cycle before DNA synthesis is induced in the EBV producer P3HR-1 cell line. The exonuclease activity encoded by DNAase was found to be inhibited when this enzyme complexed with mDBP, while the EBV DNA polymerase retained its activity in the complexed form with mDBP. Our results suggest that these complexes already present before DNA synthesis are necessary for EBV DNA synthesis.

Equimolar generation of the four possible arrangements of adjacent L components in herpes simplex virus type 1 replicative intermediates

Herpes simplex virus type 1 (HSV-1) replication generates high-molecular-weight intermediates containing branched DNA and concatemers carrying adjacent genomes with inverted L components. We have studied replicative intermediates generated by (i) wild-type HSV-1; (ii) 5dl1.2, an ICP27 null mutant which fails to synthesize normal amounts of DNA and late proteins; (iii) RBMu3, a mutant containing a deletion in the inverted repeats which fails to generate genomic isomers; and (iv) amplicon plasmids and vectors which contain no inverted sequences. Replication intermediates were analyzed by pulsed-field gel electrophoresis, after restriction enzyme digestion of infected-cell DNA, followed by blot hybridization. DNA fragments were statistically quantified after phosphorimaging. We observed that (i) the four possible configurations of L components of two adjacent genomes in the concatemers are present at equimolar amounts at any time during virus replication, (ii) ICP27 is not required for inversions or for branched DNA to occur, and (iii) replication intermediates of both RBMu3 mutant and amplicon plasmids or vectors do contain branched structures, although the concatemers they generate contain no inversions. These data indicate that inversions are generated by a mechanism intrinsically linked to virus DNA replication, most likely homologous recombination between inverted repeats. Branched structures are detected in all replicating molecules, including those that do not invert, suggesting that they are constitutively linked to virus DNA synthesis. Our results are consistent with the notion that the four HSV-1 genomic isomers are generated by alternative cleavage frames of replication concatemers containing equimolar amounts of L-component inversions.

Characterization of ICP6::lacZ insertion mutants of the UL15 gene of herpes simplex virus type 1 reveals the translation of two proteins

The herpes simplex virus type 1 (HSV-1) UL15 gene is a spliced gene composed of two exons and is predicted to encode an 81-kDa protein of 735 amino acids (aa). Two UL15 gene products with molecular masses of 75 and 35 kDa have been observed (J. Baines, A. Poon, J. Rovnak, and B. Roizman, J. Virol. 68:8118-8124, 1994); however, it is not clear whether the smaller form represents a proteolytic cleavage product of the larger form or whether it is separately translated. In addition, an HSV-1 temperature-sensitive mutant in the UL15 gene (ts66.4) is defective in both cleavage of viral DNA concatemers into unit-length monomers and packaging of viral DNA into capsids (A. Poon and B. Roizman, J. Virol. 67:4497-4503, 1993; J. Baines et al., J. Virol. 68:8118-8124, 1994). In this study, we detected two UL15 gene products of 81 and 30 kDa in HSV-1-infected cells, using a polyclonal antibody raised against a maltose binding protein fusion construct containing UL15 exon 2. In addition, we report the isolation of two HSV-1 insertion mutants, hr81-1 and hr81-2, which contain an ICP6::lacZ insertion in UL15 exon 1 and exon 2 and thus would be predicted to encode C-terminally truncated peptides of 153 and 509 aa long, respectively. hr81-1 and hr81-2 are defective in DNA cleavage and packaging and accumulate only B capsids. However, both mutants are able to undergo wild-type levels of DNA replication and genomic inversion, suggesting that genomic inversion is a result of DNA replication rather than of DNA cleavage and packaging. We also provide evidence that the 81- and 30-kDa proteins are the products of separate in-frame translation events from the UL15 gene and that the 81-kDa full-length UL15 protein is required for DNA cleavage and packaging.

The product of the UL12.5 gene of herpes simplex virus type 1 is a capsid-associated nuclease

The UL12 open reading frame of herpes simplex virus type 1 (HSV-1) encodes a deoxyribonuclease that is frequently referred to as alkaline nuclease (AN) because of its high pH optimum. Recently, an alternate open reading frame designated UL12.5 was identified within the UL12 gene. UL12.5 and UL12 have the same translational stop codon, but the former utilizes an internal methionine codon of the latter gene to initiate translation of a 60-kDa amino-terminal truncated form of AN. Since the role of the UL12.5 protein in the HSV-1 life cycle has not yet been determined, its properties were investigated in this study. Unlike AN, which can be readily solubilized from infected cell lysates, the UL12.5 protein was found to be a highly insoluble species, even when isolated by high-salt detergent lysis. Since many of the structural polypeptides which constitute the HSV-1 virion are similarly insoluble, a potential association of UL12.5 protein with virus particles was examined. By using Western blot analysis, the UL12.5 protein could be readily detected in preparations of intact virions, isolated capsid classes, and even capsids that had been extracted with 2 M guanidine-HCl. In contrast, AN was either missing or present at only low levels in each of these structures. Since the inherent insolubility of the UL12.5 protein prevented its potential deoxyribonuclease activity from being assayed in infected-cell lysates, partially purified fractions of soluble UL12.5 protein were generated by selectively solubilizing either insoluble infected-cell proteins or isolated capsid proteins with urea and renaturing them by stepwise dialysis. Initial analysis of these preparations revealed that they did contain an enzymatic activity that was not present in comparable fractions from cells infected with a UL12.5 null mutant of HSV-1. Additional biochemical characterization revealed that UL12.5 protein was similar to AN with respect to pH optimum, ionic strength, and divalent cation requirements and possessed both exonucleolytic and endonucleolytic functions. The finding that the UL12.5 protein represents a capsid-associated form of AN which exhibits nucleolytic activity suggests that it may play some role in the processing of genomic DNA during encapsidation.

Characterization of Monoclonal Antibodies to the Zta and DNase Proteins of Epstein-Barr Virus

Two monoclonal antibodies (mAb) were derived and designated 4F10 and 311H. 4F10 was against the Epstein-Barr virus (EBV) Zta protein and 311H specifically recognized EBV DNase enzyme. Using mAb 4F10 as a probe, the Zta protein could be detected as a 36-kD molecule in L5 cells and as a 38-kD molecule in B95-8 cells, reflecting the fact reported by other laboratories, using rabbit polyclonal antisera, that the Zta protein was variously modified in different host cells. 311H mAb was generated using antigens purified from one-step His-Bind column chromatography. The antigenic epitope recognized by this mAb was mapped within the residues 1-152 of EBV DNase by reacting the mAb with three distinct truncated mutants. Also, using 311H as a reagent to trace the kinetic expression of EBV DNase proteins in EBV-infected Akata cells, the Western blotting results indicated that DNase antigen could be detected at 12 h postactivation. The feasibility of applying these two mAb in the investigation of EBV biology is discussed. Copyright 1997 S. Karger AG, Basel

Purification of the infectious bovine rhinotracheitis virus alkaline deoxyribonuclease expressed in Escherichia coli

Nucleotide sequence analysis within the unique long segment of the infectious bovine rhinotracheitis virus (IBRV) genome identified an open reading frame of 1461 base pairs whose deduced polypeptide of 487 amino acids exhibited homology to alkaline deoxyribonucleases of other herpesviruses. To determine whether this IBRV gene product has nuclease activity, the gene designated UL12 was inserted into the vector pET-28a(+) and expressed in Escherichia coli as an oligohistidine-tagged protein. Upon induction with isopropyl beta-D-thiogalactopyranoside E. coli BL21 (DE3)[pLysS] cells harboring this recombinant plasmid produced a 57-kDa protein, the molecular mass of which was in accordance with the prediction from the nucleotide sequence. A one-step purification procedure using metal affinity chromatography resulted in a homogeneous preparation of this recombinant protein. The purified protein exhibited both exonuclease and endonuclease activities, each with an alkaline pH optimum.

Herpes simplex virus DNA replication

The Herpesviridae comprise a large class of animal viruses of considerable public health importance. Of the Herpesviridae, replication of herpes simplex virustype-1 (HSV-1) has been the most extensively studied. The linear 152-kbp HSV-1 genome contains three origins of DNA replication and approximately 75 open-reading frames. Of these frames, seven encode proteins that are required for originspecific DNA replication. These proteins include a processive heterodimeric DNA polymerase, a single-strand DNA-binding protein, a heterotrimeric primosome with 5'-3' DNA helicase and primase activities, and an origin-binding protein with 3'-5' DNA helicase activity. HSV-1 also encodes a set of enzymes involved in nucleotide metabolism that are not required for viral replication in cultured cells. These enzymes include a deoxyuridine triphosphatase, a ribonucleotide reductase, a thymidine kinase, an alkaline endo-exonuclease, and a uracil-DNA glycosylase. Host enzymes, notably DNA polymerase alpha-primase, DNA ligase I, and topoisomerase II, are probably also required. Following circularization of the linear viral genome, DNA replication very likely proceeds in two phases: an initial phase of theta replication, initiated at one or more of the origins, followed by a rolling-circle mode of replication. The latter generates concatemers that are cleaved and packaged into infectious viral particles. The rolling-circle phase of HSV-1 DNA replication has been reconstituted in vitro by a complex containing several of the HSV-1 encoded DNA replication enzymes. Reconstitution of the theta phase has thus far eluded workers in the field and remains a challenge for the future.