The region of the herpes simplex virus type 1 LAT gene that is colinear with the ICP34.5 gene is not involved in spontaneous reactivation.

The goal of this report was to determine if the region of the LAT gene that is colinear with ICP34.5 (kb 6.2 to 7.1 of LAT) is involved in spontaneous reactivation of herpes simplex virus type 1. We inserted one copy of the ICP34.5 gene into the unique long region of a herpes simplex virus type 1 (strain McKrae) mutant lacking both copies of ICP34.5 (one in each viral long repeat) and the corresponding 917-nucleotide colinear portion of LAT (kb 6.2 to 7.1). Rabbits were ocularly infected with this mutant, and spontaneous reactivation relative to that for the wild-type virus and the original mutant was measured. As we previously reported, the original ICP34.5-deleted virus (d34.5) was significantly impaired for spontaneous reactivation and virulence (G. C. Perng, R. L. Thompson, N. M. Sawtell, W. E. Taylor, S. M. Slanina, H. Ghiasi, R. Kaiwar, A. B. Nesburn, and S. L. Wechsler, J. Virol. 69:3033-3041, 1995). In contrast, we report here that restoration of one copy of ICP34.5 at a distant location completely restored the wild-type level of in vivo spontaneous reactivation, despite retention of the deletion in LAT (spontaneous reactivation rate = 0.3 to 1.4% for the ICP34.5 deletion mutant, 7.7 to 19.6% for the wild type, and 9 to 16.1% for virus with one copy of ICP34.5). Thus, the 917-nucleotide region of LAT from kb 6.2 to 7.1 was not involved in the LAT function required for wild-type spontaneous reactivation. We also found that restoration of a single ICP34.5 gene in a novel location did not restore wild-type virulence (rabbit death rate = 0% [0 of 15] for the original ICP34.5 deletion mutant, 8% [2 of 24] for the single-copy IPC34.5 virus, and 52% [14 of 27] for wild-type virus; P < 0.001 for one versus two copies of ICP34.5). It is likely that either two gene doses of ICP34.5 or its location in the long repeat is essential for full functionality of ICP34.5's virulence function. Furthermore, the ability of the single-copy ICP34.5 virus to reactivate at wild-type levels despite being significantly less virulent than wild-type virus separates the spontaneous reactivation phenotype from the virulence phenotype.     

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.     

Phenotype of the herpes simplex virus type 1 protease substrate ICP35 mutant virus.

The herpes simplex virus type 1 ICP35 assembly protein is involved in the formation of viral capsids. ICP35 is encoded by the UL26.5 gene and is specifically processed by the herpes simplex virus type 1 protease encoded by the UL26 gene. To better understand the functions of ICP35 in infected cells, we have isolated and characterized an ICP35 mutant virus, delta ICP35. The mutant virus was propagated in complementing 35J cells, which express wild-type ICP35. Phenotypic analysis of delta ICP35 shows that (i) mutant virus growth in Vero cells was severely restricted, although small amounts of progeny virus was produced; (ii) full-length ICP35 protein was not produced, although autoproteolysis of the protease still occurred in mutant-infected nonpermissive cells; (iii) viral DNA replication of the mutant proceeded at wild-type levels, but only a very small portion of the replicated DNA was processed to unit length and encapsidated; (iv) capsid structures were observed in delta ICP35-infected Vero cells by electron microscopy and by sucrose sedimentation analysis; (v) assembly of VP5 into hexons of the capsids was conformationally altered; and (vi) ICP35 has a novel function which is involved in the nuclear transport of VP5.     

Evidence that the herpes simplex virus type 1 ICP0 protein does not initiate reactivation from latency in vivo

The stress-induced host cell factors initiating the expression of the herpes simplex virus lytic cycle from the latent viral genome are not known. Previous studies have focused on the effect of specific viral proteins on reactivation, i.e., the production of detectable infectious virus. However, identification of the viral protein(s) through which host cell factors transduce entry into the lytic cycle and analysis of the promoter(s) of this (these) first protein(s) will provide clues to the identity of the stress-induced host cell factors important for reactivation. In this report, we present the first strategy developed for this type of analysis and use this strategy to test the established hypothesis that the herpes simplex virus ICP0 protein initiates reactivation from the latent state. To this end, ICP0 null and promoter mutants were analyzed for the abilities (i) to exit latency and produce lytic-phase viral proteins (initiate reactivation) and (ii) to produce infectious viral progeny (reactivate) in explant and in vivo. Infection conditions were manipulated so that approximately equal numbers of latent infections were established by the parental strains, the mutants, and their genomically restored counterparts, eliminating disparate latent pool sizes as a complicating factor. Following hyperthermic stress (HS), which induces reactivation in vivo, equivalent numbers of neurons exited latency (as evidenced by the expression of lytic-phase viral proteins) in ganglia latently infected with either the ICP0 null mutant dl1403 or the parental strain. In contrast, infectious virus was detected in the ganglia of mice latently infected with the parental strain but not with ICP0 null mutant dl1403 or FXE. These data demonstrate that the role of ICP0 in the process of reactivation is not as a component of the switch from latency to lytic-phase gene expression; rather, ICP0 is required after entry into the lytic cycle has occurred. Similar analyses were carried out with the DeltaTfi mutant, which contains a 350-bp deletion in the ICP0 promoter, and the genomically restored isolate, DeltaTfiR. The numbers of latently infected neurons exiting latency were not different for DeltaTfi and DeltaTfiR. However, DeltaTfi did not reactivate in vivo, whereas DeltaTfiR reactivated in approximately 38% of the mice. In addition, ICP0 was detected in DeltaTfiR-infected neurons exiting latency but was not detected in those neurons exiting latency infected with DeltaTfi. We conclude that while ICP0 is important and perhaps essential for infectious virus production during reactivation in vivo, this protein is not required and appears to play no major role in the initiation of reactivation in vivo.     

An African swine fever virus virulence-associated gene NL-S with similarity to the herpes simplex virus ICP34.5 gene.

We described previously an African swine fever virus (ASFV) open reading frame, 23-NL, in the African isolate Malawi Lil 20/1 whose product shared significant similarity in a carboxyl-terminal domain with those of a mouse myeloid differentiation primary response gene, MyD116, and the herpes simplex virus neurovirulence-associated gene, ICP34.5 (M. D. Sussman, Z. Lu, G. Kutish, C. L. Afonso, P. Roberts, and D. L. Rock, J. Virol. 66:5586-5589, 1992). The similarity of 23-NL to these genes suggested that this gene may function in some aspect of ASFV virulence and/or host range. Sequence analysis of additional pathogenic viral isolates demonstrates that this gene is highly conserved among diverse ASFV isolates and that the gene product exists in either a long (184 amino acids as in 23-NL) or a short form (70 to 72 amino acids in other examined ASFV isolates). The short form of the gene, NL-S, encodes the complete highly conserved, hydrophilic, carboxyl-terminal domain of 56 amino acids common to 23-NL, MyD116, and ICP34.5. Recombinant NL-S gene deletion mutants and their revertants were constructed from the pathogenic ASFV isolate E70 and an E70 monkey cell culture-adapted virus, MS44, to study gene function. Although deletion of NL-S did not affect viral growth in primary swine macrophages or Vero cell cultures in vitro, the null mutant, E70/43, exhibited a marked reduction in pig virulence. In contrast to revertant or parental E70 where mortality was 100%, all E70/43-infected animals survived infection. With the exception of a transient fever response, E70/43-infected animals remained clinically normal and exhibited a 1,000-fold reduction in both mean and maximum viremia titers. All convalescent E70/43-infected animals survived infection when challenged with parental E70 at 30 days postinfection. These data indicate that the highly conserved NL-S gene of ASFV, while nonessential for growth in swine macrophages in vitro, is a significant viral virulence factor and may function as a host range gene.     

Replication of ICP0-null mutant herpes simplex virus type 1 is restricted by both PML and Sp100

Herpes simplex virus type 1 (HSV-1) mutants that fail to express the viral immediate-early protein ICP0 have a pronounced defect in viral gene expression and plaque formation in limited-passage human fibroblasts. ICP0 is a RING finger E3 ubiquitin ligase that induces the degradation of several cellular proteins. PML, the organizer of cellular nuclear substructures known as PML nuclear bodies or ND10, is one of the most notable proteins that is targeted by ICP0. Depletion of PML from human fibroblasts increases ICP0-null mutant HSV-1 gene expression, but not to wild-type levels. In this study, we report that depletion of Sp100, another major ND10 protein, results in a similar increase in ICP0-null mutant gene expression and that simultaneous depletion of both proteins complements the mutant virus to a greater degree. Although chromatin assembly and modification undoubtedly play major roles in the regulation of HSV-1 infection, we found that inhibition of histone deacetylase activity with trichostatin A was unable to complement the defect of ICP0-null mutant HSV-1 in either normal or PML-depleted human fibroblasts. These data lend further weight to the hypothesis that ND10 play an important role in the regulation of HSV-1 gene expression.     

ICP0 is not required for efficient stress-induced reactivation of herpes simplex virus type 1 from cultured quiescently infected neuronal cells

Viral genes sufficient and required for herpes simplex virus type 1 (HSV-1) reactivation were identified using neuronally differentiated PC12 cells (ND-PC12 cells) in which quiescent infections with wild-type and recombinant strains were established. In this model, the expression of ICP0, VP16, and ICP4 from adenovirus vectors was sufficient to reactivate strains 17⁺ and KOS. The transactivators induced similar levels of reactivation with KOS; however, 17⁺ responded more efficiently to ICP0. To identify viral transactivators required for reactivation, we examined quiescently infected PC12 cell cultures (QIF-PC12 cell cultures) established with HSV-1 deletion mutants R7910 (ΔICP0), KD6 (ΔICP4), and in1814, a virus containing an insertion mutation in VP16. Although growth of these mutant viruses was impaired in ND-PC12 cells, R7910 and in1814 reactivated at levels equivalent to or better than their respective parental controls following stress (i.e., heat or forskolin) treatment. After treatment with trichostatin A, in1814 and 17⁺ reactivated efficiently, whereas the F strain and R7910 reactivated inefficiently. In contrast, KD6 failed to reactivate. In experiments with the recombinant KM100, which contains the in1814 mutation in VP16 and the n212 mutation in ICP0, spontaneous and stress-induced reactivation was observed. However, two strains, V422 and KM110, which lack the acidic activation domain of VP16, did not reactivate above low spontaneous levels after stress. These results demonstrate that in QIF-PC12 cells ICP0 is not required for efficient reactivation of HSV-1, the acidic activation domain of VP16 is essential for stress-induced HSV-1 reactivation, and HSV-1 reactivation is modulated uniquely by different treatment constraints and phenotypes.     

Pseudorabies virus protein homologous to herpes simplex virus type 1 ICP18.5 is necessary for capsid maturation.

In pseudorabies virus (PrV), an open reading frame that partially overlaps the gene for the essential glycoprotein gII has been shown to encode a protein homologous to the ICP18.5 polypeptide of herpes simplex virus type 1 (N. Pederson and L. Enquist, Nucleic Acids Res. 17:3597, 1989). To study the function of this protein during the viral replicative cycle, a PrV mutant which carries a beta-galactosidase expression cassette interrupting the ICP18.5(PrV) gene was constructed. This mutant could be propagated only on cell lines that were able to provide ICP18.5(PrV) in trans after transformation with a corresponding genomic PrV DNA fragment. Detailed analysis showed that inactivation of the ICP18.5(PrV) gene did not impair infection of noncomplementing cells, nor did it impair early or late gene expression, as shown by immunoprecipitation of glycoproteins gII, gIII, and gp50. Surface localization of glycoproteins as demonstrated by fluorescence-activated cell sorting analyses was also not affected. Southern blot hybridizations, however, showed that cleavage of replicative concatemeric viral DNA did not occur in noncomplementing cells infected by the ICP18.5 mutant PrV. In addition, electron microscopic analysis revealed an accumulation of empty capsids in the nucleus of mutant-infected noncomplementing cells. We conclude that the ICP18.5(PrV) protein is necessary for viral replication and plays an essential role in the process of mature capsid formation.     

Glutamine deprivation causes enhanced plating efficiency of a herpes simplex virus type 1 ICP0-null mutant

Isoleucine deprivation of cellular monolayers prior to infection has been reported to result in partial complementation of a herpes simplex virus type 1 (HSV-1) ICP0 null (ICP0⁻) mutant. We now report that glutamine deprivation alone is able to enhance the plating efficiency of an ICP0⁻ virus and that isoleucine deprivation has little or no effect. Because a low glutamine level is associated with stress and because stress is known to induce reactivation, low levels of glutamine may be relevant to the reactivation of HSV-1 from latency. Additionally, we demonstrate that arginine and methionine deprivation result in partial complementation of the ICP0⁻ virus.     

Intercellular trafficking of herpes simplex virus type 2 UL14 deletion mutant proteins

The UL14 gene product of herpes simplex virus is a 32kDa protein expressed late in infection and is a minor component of the virion tegument. We recently showed that the wild-type UL14 protein has heat shock protein (HSP)-like and/or molecular chaperone-like functions. In this study, the intracellular localization of UL14 wild-type and deletion mutant proteins was examined in transfected cells by immunofluorescence. We found that N-terminus deleted but not wild-type/C-terminus deleted mutant proteins showed a significant number of cytoplasmic, multi-cellular stains in transfected Vero cells. The effect was greatly intensified by subjecting cells to heat shock at 43 degrees C, whereas it was obstructed by treatment with the microfilament-disrupting drug cytochalasin D. The staining patterns of UL14 antigen-positive cells after heat shock suggested a cell-to-cell spread of the protein. Although the mechanism is unclear, the phenomenon seems to be an unprecedented type of intercellular trafficking.     

Cytotoxicity of a replication-defective mutant of herpes simplex virus type 1.

Replication-defective mutants of herpes simplex virus type 1 (HSV-1) may prove useful as vectors for gene transfer, particularly to nondividing cells. Cgal delta 3 is an immediate-early gene 3 (IE 3) deletion mutant of HSV-1 that expresses the lacZ gene of Escherichia coli from the human cytomegalovirus immediate-early control region but does not express viral early or late genes. This vector was able to efficiently infect and express lacZ in cells refractory to traditional methods of gene transfer. However, 1 to 3 days postinfection, Cgal delta 3 induced cytopathic effects (CPE) in many cell types, including neurons. In human primary fibroblasts Cgal delta 3 induced chromosomal aberrations and host cell DNA fragmentation. Other HSV-1 strains that caused CPE, tested under conditions of viral replication-inhibition, included mutants of the early gene UL42, the virion host shutoff function, single mutants of IE 1, IE 2, and IE 3, and double mutants of IE 3 and 4 and IE 3 and 5. Inhibition of viral gene expression by UV irradiation of virus stocks or by preexposure of cells to interferon markedly reduced the CPE. We conclude from these studies that HSV-1 IE gene expression is sufficient for the induction of CPE, although none of the five IE gene products appear to be solely responsible. After infection of human fibroblasts with Cgal delta 3 at a low multiplicity of infection, we were able to recover up to 6% of the input virus 2 weeks later by a superinfection-rescue procedure, even though the virally transduced human cytomegalovirus-lacZ transgene was not expressed at this time. It is therefore likely that inhibition or inactivation of viral IE gene expression, either for establishing latency or for the long-term transduction of foreign genes by HSV-1 vectors, is essential to avoid the death of infected cells.