The herpes simplex virus 1 UL15 gene encodes two proteins and is required for cleavage of genomic viral DNA.

Previous studies have shown that a ts mutant [herpes simplex virus 1 (mP)ts66.4] in the UL15 gene fails to package viral DNA into capsids (A. P. W. Poon and B. Roizman, J. Virol. 67:4497-4503, 1993) and that although the intron separating the first and second exons of the UL15 gene contains UL16 and UL17 open reading frames, replacement of the first exon with a cDNA copy of the entire gene does not affect viral replication (J.D. Baines, and B. Roizman, J. Virol. 66:5621-5626, 1992). We report that (i) a polyclonal rabbit antiserum generated against a chimeric protein consisting of the bacterial maltose-binding protein fused in frame to the majority of sequences contained in the second exon of the UL15 gene reacted with two proteins with M(r) of 35,000 and 75,000, respectively, in cells infected with a virus containing the authentic gene yielding a spliced mRNA or with a virus in which the authentic UL15 gene was replaced with a cDNA copy. (ii) Insertion of 20 additional codons into the C terminus of UL15 exon II caused a reduction in the electrophoretic mobility of both the apparently 35,000- and 75,000-M(r) proteins, unambiguously demonstrating that both share the carboxyl terminus of the UL15 exon II. (iii) Accumulation of the 35,000-M(r) protein was reduced in cells infected and maintained in the presence of phosphonoacetate, an inhibitor of viral DNA synthesis. (iv) The UL15 proteins were localized in the perinuclear space at 6 h after infection and largely in the nucleus at 12 h after infection. (v) Viral DNA accumulating in cells infected with herpes simplex virus 1(mP)ts66.4 and maintained at the nonpermissive temperature was in an endless (concatemeric) form, and therefore UL15 is required for the cleavage of mature, unit-length molecules for packaging into capsids.     

Autocatalytic activity of the ubiquitin-specific protease domain of herpes simplex virus 1 VP1-2

The herpes simplex virus (HSV) tegument protein VP1-2 is essential for virus entry and assembly. VP1-2 also contains a highly conserved ubiquitin-specific protease (USP) domain within its N-terminal region. Despite conservation of the USP and the demonstration that it can act on artificial substrates such as polyubiquitin chains, identification of the relevance of the USP in vivo to levels or function of any substrate remains limited. Here we show that HSV VP1-2 USP can act on itself and is important for stability. VP1-2 N-terminal variants encompassing the core USP domain itself were not affected by mutation of the catalytic cysteine residue (C65). However, extending the N-terminal region resulted in protein species requiring USP activity for accumulation. In this context, C65A mutation resulted in a drastic reduction in protein levels which could be stabilized by proteosomal inhibition or by the presence of normal C65. The functional USP domain could increase abundance of unstable variants, indicating action at least in part, in trans. Interestingly, full-length variants containing the inactive USP, although unstable when expressed in isolation, were stabilized by virus infection. The catalytically inactive VP1-2 retained complementation activity of a VP1-2-negative virus. Furthermore, a recombinant virus expressing a C65A mutant VP1-2 exhibited little difference in single-step growth curves and the kinetics and abundance of VP1-2 or a number of test proteins. Despite the absence of a phenotype for these replication parameters, the USP activity of VP1-2 may be required for function, including its own stability, under certain circumstances.     

Topoisomerase II cleavage of herpes simplex virus type 1 DNA in vivo is replication dependent

The genome of herpes simplex virus type 1 contains a large number of recognition sites for eucaryotic DNA type II topoisomerase. Topoisomerase II sites were identified by means of the consensus sequence described previously (J.R. Spitzner and M.T. Muller, Nucleic Acids Res. 16:5553-5556, 1988) and then confirmed by sequencing DNA cleavages introduced by purified topoisomerase II. In vivo, host topoisomerase II also introduced double-stranded DNA breaks in the viral genome at sites predicted by the consensus sequence. Host topoisomerase II acted on all immediate-early genes as well as on genes from other temporal classes; however, cleavages were not detected until 4 to 5 h postinfection and were most intense at 10 h postinfection. Topoisomerase II cleavages were not detected when viral DNA replication was prevented with phosphonoacetic acid. These data indicate that, although progeny viral genomes are acted upon by host topoisomerase II, this enzyme either does not act on parental viral genomes before DNA replication or acts on them with such low efficiency that cleavages are beyond our limit of detection. The findings suggest that host topoisomerase II is involved in aspects of viral replication at late times in the infectious cycle.     

Nucleolin is required for an efficient herpes simplex virus type 1 infection

Productive infection by herpes simplex virus type 1 (HSV-1), which occurs in the host cell nucleus, is accompanied by dramatic modifications of the nuclear architecture, including profound alterations of nucleolar morphology. Here, we show that the three most abundant nucleolar proteins--nucleolin, B23, and fibrillarin--are redistributed out of the nucleoli as a consequence of HSV-1 infection. We show that the amount of nucleolin increases progressively during the course of infection. We demonstrate for the first time that a nucleolar protein, i.e., nucleolin, colocalizes with ICP8 in the viral replication compartments, at the time when viral replication is effective, suggesting an involvement of nucleolin in the HSV-1 DNA replication process. At later times of infection, a granular form of nucleolin localizes to the cytoplasm, in structures that display the characteristic features of aggresomes, indicating that this form of nucleolin is very probably destined for degradation. The delocalization of nucleolin from the nucleoli requires the viral ICP4 protein or a factor(s) whose expression involves ICP4. Using small interfering RNA technology, we show that viral replication requires a high level of nucleolin expression, demonstrating for the first time a direct role for a nucleolar protein in herpes simplex virus biology.     

DNA mismatch repair proteins are required for efficient herpes simplex virus 1 replication

Herpes simplex virus 1 (HSV-1) is a double-stranded DNA virus that replicates in the nucleus of its human host cell and is known to interact with many cellular DNA repair proteins. In this study, we examined the role of cellular mismatch repair (MMR) proteins in the virus life cycle. Both MSH2 and MLH1 are required for efficient replication of HSV-1 in normal human cells and are localized to viral replication compartments. In addition, a previously reported interaction between MSH6 and ICP8 was confirmed by coimmunoprecipitation and extended to show that UL12 is also present in this complex. We also report for the first time that MLH1 associates with ND10 nuclear bodies and that like other ND10 proteins, MLH1 is recruited to the incoming genome. Knockdown of MLH1 inhibits immediate-early viral gene expression. MSH2, on the other hand, which is generally thought to play a role in mismatch repair at a step prior to that of MLH1, is not recruited to incoming genomes and appears to act at a later step in the viral life cycle. Silencing of MSH2 appears to inhibit early gene expression. Thus, both MLH1 and MSH2 are required but appear to participate in distinct events in the virus life cycle. The observation that MLH1 plays an earlier role in HSV-1 infection than does MSH2 is surprising and may indicate a novel function for MLH1 distinct from its known MSH2-dependent role in mismatch repair.     

Identification of herpes simplex virus type 1 genes required for origin-dependent DNA synthesis.

The herpes simplex virus (HSV) genome contains both cis- and trans-acting elements which are important in viral DNA replication. The cis-acting elements consist of three origins of replication: two copies of oriS and one copy of oriL. It has previously been shown that five cloned restriction fragments of HSV-1 DNA together can supply all of the trans-acting functions required for the replication of plasmids containing oriS or oriL when cotransfected into Vero cells (M. D. Challberg, Proc. Natl. Acad. Sci. USA, 83:9094-9098, 1986). These observations provide the basis for a complementation assay with which to locate all of the HSV sequences which encode trans-acting functions necessary for origin-dependent DNA replication. Using this assay in combination with the data from large-scale sequence analysis of the HSV-1 genome, we have now identified seven HSV genes which are necessary for transient replication of plasmids containing either oriS or oriL. As shown previously, two of these genes encode the viral DNA polymerase and single-stranded DNA-binding protein, which are known from conventional genetic analysis to be essential for viral DNA replication in infected cells. The functions of the products of the remaining five genes are unknown. We propose that the seven genes essential for plasmid replication comprise a set of genes whose products are directly involved in viral DNA synthesis.     

Residues of VP26 of herpes simplex virus type 1 that are required for its interaction with capsids

VP26 is the smallest capsid protein and decorates the outer surface of the capsid shell of herpes simplex virus. It is located on the hexons at equimolar amounts with VP5. Its small size (112 amino acids) and high copy number make it an attractive molecule to use as a probe to investigate the complex pattern of capsid protein interactions. An in vitro capsid binding assay and a green fluorescent protein (GFP) localization assay were used to identify VP26 residues important for its interaction with capsids. To test for regions of VP26 that may be essential for binding to capsids, three small in-frame deletion mutations were generated in VP26, Delta18-25, Delta54-60, and Delta93-100. Their designations refer to the amino acids deleted by the mutation. The mutation at the C terminus of the molecule, which encompasses a region of highly conserved residues, abolished binding to the capsid and the localization of GFP to the nucleus in characteristic large puncta. Additional mutations revealed that a region of VP26 spanning from residue 50 to 112 was sufficient for the localization of the fused protein (VP26-GFP) to the nucleus and for it to bind to capsids. Using site-directed mutagenesis of conserved residues in VP26, two key residues for protein-protein interaction, F79 and G93, were identified as judged by the localization of GFP to nuclear puncta. When these mutations were analyzed in the capsid binding assay, they were also found to eliminate binding of VP26 to the capsid structure. Surprisingly, additional mutations that affected the ability of VP26 to bind to capsids in vitro were uncovered. Mutations at residues A58 and L64 resulted in a reduced ability of VP26 to bind to capsids. Mutation of the hydrophobic residues M78 and A80, which are adjacent to the hydrophobic residue F79, abolished VP26 capsid binding. In addition, the block of conserved amino acids in the carboxy end of the molecule had the most profound effect on the ability of VP26 to interact with capsids. Mutation of amino acid G93, L94, R95, R96, or T97 resulted in a greatly diminished ability of VP26 to bind capsids. Yet, all of these residues other than G93 were able to efficiently translocate or concentrate GFP into the nucleus, giving rise to the punctate fluorescence. Thus, the interaction of VP26 with the capsid appears to occur through at least two separate mechanisms. The initial interaction of VP26 and VP5 may occur in the cytoplasm or when VP5 is localized in the nucleus. Residues F79 and G93 are important for this bi-molecular interaction, resulting in the accumulation of VP26 in the nucleus in concentrated foci. Subsequent to this association, additional amino acids of VP26, including those in the C-terminal conserved domain, are important for interaction of VP26 with the three-dimensional capsid structure.     

Analysis of the interaction between the essential herpes simplex virus 1 tegument proteins VP16 and VP1/2

The incorporation of tegument proteins into the herpes simplex virus 1 (HSV-1) virion during virion assembly is thought to be a complex, multistage process occurring via numerous interactions between the tegument and the capsid, within the tegument, and between the tegument and the envelope. Here, we set out to examine if the direct interaction between two essential tegument proteins VP1/2 and VP16 is required for connecting the inner tegument with the outer tegument. By using glutathione S-transferase (GST) pulldowns, we identified an essential role of lysine 343 in VP16, mutation of which to a neutral amino acid abrogated the interaction between VP1/2 and VP16. When the K343A substitution was inserted into the gene encoding VP16 (UL48) of the viral genome, HSV-1 replicated successfully although its growth was delayed, and final titers were reduced compared to titers of wild-type virus. Surprisingly, the mutated VP16 was incorporated into virions at levels similar to those of wild-type VP16. However, the analysis of VP16 on cytoplasmic capsids by fluorescence microscopy showed that VP16 associated with cytoplasmic capsids less efficiently when the VP16-VP1/2 interaction was inhibited. This implies that the direct interaction between VP1/2 and VP16 is important for the efficiency/timing of viral assembly but is not essential for HSV-1 replication in cell culture. These data also support the notion that the incorporation of tegument proteins into the herpesviruses is a very complex process with significant redundancy.     

A domain in the herpes simplex virus 1 triplex protein VP23 is essential for closure of capsid shells into icosahedral structures

VP23 is a key component of the triplex structure. The triplex, which is unique to herpesviruses, is a complex of three proteins, two molecules of VP23 which interact with a single molecule of VP19C. This structure is important for shell accretion and stability of the protein coat. Previous studies utilized a random transposition mutagenesis approach to identify functional domains of the triplex proteins. In this study, we expand on those findings to determine the key amino acids of VP23 that are required for triplex formation. Using alanine-scanning mutagenesis, we have made mutations in 79 of 318 residues of the VP23 polypeptide. These mutations were screened for function both in the yeast two-hybrid assay for interaction with VP19C and in a genetic complementation assay for the ability to support the replication of a VP23 null mutant virus. These assays identified a number of amino acids that, when altered, abolish VP23 function. Abrogation of virus assembly by a single-amino-acid change bodes well for future development of small-molecule inhibitors of this process. In addition, a number of mutations which localized to a C-terminal region of VP23 (amino acids 205 to 241) were still able to interact with VP19C but were lethal for virus replication when introduced into the herpes simplex virus 1 (HSV-1) KOS genome. The phenotype of many of these mutant viruses was the accumulation of large open capsid shells. This is the first demonstration of capsid shell accumulation in the presence of a lethal VP23 mutation. These data thus identify a new domain of VP23 that is required for or regulates capsid shell closure during virus assembly.     

The 60-residue C-terminal region of the single-stranded DNA binding protein of herpes simplex virus type 1 is required for cooperative DNA binding

ICP8 is the major single-stranded DNA (ssDNA) binding protein of the herpes simplex virus type 1 and is required for the onset and maintenance of viral genomic replication. To identify regions responsible for the cooperative binding to ssDNA, several mutants of ICP8 have been characterized. Total reflection X-ray fluorescence experiments on the constructs confirmed the presence of one zinc atom per molecule. Comparative analysis of the mutants by electrophoretic mobility shift assays was done with oligonucleotides for which the number of bases is approximately that occluded by one protein molecule. The analysis indicated that neither removal of the 60-amino-acid C-terminal region nor Cys254Ser and Cys455Ser mutations qualitatively affect the intrinsic DNA binding ability of ICP8. The C-terminal deletion mutants, however, exhibit a total loss of cooperativity on longer ssDNA stretches. This behavior is only slightly modulated by the two-cysteine substitution. Circular dichroism experiments suggest a role for this C-terminal tail in protein stabilization as well as in intermolecular interactions. The results show that the cooperative nature of the ssDNA binding of ICP8 is localized in the 60-residue C-terminal region. Since the anchoring of a C- or N-terminal arm of one protein onto the adjacent one on the DNA strand has been reported for other ssDNA binding proteins, this appears to be the general structural mechanism responsible for the cooperative ssDNA binding by this class of protein.     

RNA-dependent protein kinase is required for alpha-1 interferon transgene-induced resistance to genital herpes simplex virus type 2

We investigated the mechanism of resistance to genital herpes simplex virus type 2 (HSV-2) infection in mice transfected with the murine alpha-1 interferon (IFN-alpha1) transgene. In situ transfection of mice with the IFN-alpha1 transgene resulted in an elevation in an IFN-responsive gene, RNA-dependent protein kinase (PKR), but not 2',5'-oligoadenylate synthetases (OAS), in vaginal tissue. Coupled with the finding that mice lacking a functional PKR pathway were no longer resistant to genital HSV-2 infection following transfection with the IFN-alpha1 transgene in comparison to wild-type mice or mice lacking a functional OAS pathway, these results suggest that PKR is the dominant antiviral pathway activated by the IFN-alpha1 transgene.     

A single mutation responsible for temperature-sensitive entry and assembly defects in the VP1-2 protein of herpes simplex virus

Evidence for an essential role of the herpes simplex virus type 1 (HSV-1) tegument protein VP1-2 originated from the analysis of the temperature-sensitive (ts) mutant tsB7. At the nonpermissive temperature (NPT), tsB7 capsids accumulate at the nuclear pore, with defective genome release and substantially reduced virus gene expression. We compared the UL36 gene of tsB7 with that of the parental strain HFEM or strain 17 and identified four amino acid substitutions, 1061D → G, 1453Y → H, 2273Y → H, and 2558T → I. We transferred the UL36 gene from tsB7, HFEM, or strain 17 into a KOS background. While KOS recombinants containing the HFEM or strain 17 UL36 gene exhibited no ts defect, recombinants containing the tsB7 UL36 VP1-2 exhibited a 5-log deficiency at the NPT. Incubation at the NPT resulted in little or no virus gene expression, though limited expression could be detected in a highly delayed fashion. Using shift-down regimes, gene expression recovered and recapitulated the time course normally observed, indicating that the initial block was in a reversible pathway. Using temperature shift-up regimes, a second defect later in the replication cycle was also observed in the KOS.ts viruses. We constructed a further series of recombinants which contained subsets of the four substitutions. A virus containing the wild-type (wt) residue at position 1453 and with the other three residues being from tsB7 VP1-2 exhibited wt plaquing efficiency. Conversely, a virus containing the three wt residues but the single Y → H change at position 1453 from tsB7 exhibited a 4- to 5-log drop in plaquing efficiency and was defective at both early and late stages of infection.     

The relationship between incorporation of E-5-(2-Bromovinyl)-2'-deoxyuridine into herpes simplex virus type 1 DNA with virus infectivity and DNA integrity

E-5-(2-Bromovinyl)-2'-deoxyuridine (BrvdUrd) produced a dose-dependent shift in the density of herpes simplex virus type 1 (HSV-1) DNA at concentrations which yielded potent inhibition of virus replication in cultured Vero cells. Although the density of cellular DNA was not altered by these concentrations of BrvdUrd, incorporation of this analogue into cellular DNA of HSV-1-infected cells has been previously observed in this laboratory. The degree of inhibition correlated with the amount of BrvdUrd substituted for thymidine in HSV-1 DNA. BrvdUrd-substituted DNA was more labile as determined by a dose-dependent increase in single strand breaks when examined by centrifugation in alkaline sucrose gradients. Thus, the potent antiviral action of BrvdUrd observed in cell culture correlates not only with its incorporation into HSV-1 DNA but also with an altered stability of this DNA.     

ICP0 is required for efficient reactivation of herpes simplex virus type 1 from neuronal latency

Relative to wild-type herpes simplex virus type 1 (HSV-1), ICP0-null mutant viruses reactivate inefficiently from explanted, latently infected mouse trigeminal ganglia (TG), indicating that ICP0 is not essential for reactivation but plays a central role in enhancing the efficiency of reactivation. The validity of these findings has been questioned, however, because the replication of ICP0-null mutants is impaired in animal models during the establishment of latency, such that fewer mutant genomes than wild-type genomes are present in latently infected mouse TG. Therefore, the reduced number of mutant viral genomes available to reactivate, rather than mutations in the ICP0 gene per se, may be responsible for the reduced reactivation efficiency of ICP0-null mutants. We have recently demonstrated that optimization of the size of the ICP0 mutant virus inoculum and transient immunosuppression of mutant-infected mice with cyclophosphamide can be used to establish wild-type levels of ICP0-null mutant genomes in latently infected TG (W. P. Halford and P. A. Schaffer, J. Virol. 74:5957-5967, 2000). Using this procedure to equalize mutant and wild-type genome numbers, the goal of the present study was to determine if, relative to wild-type virus, the absence of ICP0 function in two ICP0-null mutants, n212 and 7134, affects reactivation efficiency from (i) explants of latently infected TG and (ii) primary cultures of latently infected TG cells. Although equivalent numbers of viral genomes were present in TG of mice latently infected with either wild-type or mutant viruses, reactivation of n212 and 7134 from heat-stressed TG explants was inefficient (31 and 37% reactivation, respectively) relative to reactivation of wild-type virus (KOS) (95%). Similarly, n212 and 7134 reactivated inefficiently from primary cultures of dissociated TG cells plated directly after removal from the mouse (7 and 4% reactivation, respectively), relative to KOS (60% reactivation). The efficiency and kinetics of reactivation of KOS, n212, and 7134 from cultured TG cells (treated with acyclovir to facilitate the establishment of latency) in response to heat stress or superinfection with a nonreplicating HSV-1 ICP4(-) mutant, n12, were compared. Whereas heat stress induced reactivation of KOS from 69% of latently infected TG cell cultures, reactivation of n212 and 7134 was detected in only 1 and 7% of cultures, respectively. In contrast, superinfection with the ICP4(-) virus, which expresses high levels of ICP0, resulted in the production of infectious virus in nearly 100% of cultures latently infected with KOS, n212, or 7134 within 72 h. Thus, although latent mutant viral genome loads were equivalent to that of wild-type virus, in the absence of ICP0, n212 and 7134 reactivated inefficiently from latently infected TG cells during culture establishment and following heat stress. Collectively, these findings demonstrate that ICP0 is required to induce efficient reactivation of HSV-1 from neuronal latency.