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.     

Varicella-zoster virus complements herpes simplex virus type 1 temperature-sensitive mutants.

Varicella-zoster virus (VZV) can complement temperature-sensitive mutants of herpes simplex virus. Of seven mutants tested, two, carrying mutations in the immediate-early ICP4 and ICP27 proteins, were complemented. This complementation was not seen in coinfections with adenovirus type 5 or cytomegalovirus. Following transfection into CV-1 cells, a DNA fragment containing the VZV short repeat sequence complemented the ICP4 mutant. These data demonstrate a functional relationship between VZV and herpes simplex virus and have allowed localization of a putative VZV immediate-early gene.     

The immune response to ocular herpes simplex virus type 1 infection

Herpes simplex virus type 1 (HSV-1) is a prevalent microbial pathogen infecting 60% to 90% of the adult world population. The co-evolution of the virus with humans is due, in part, to adaptations that the virus has evolved to aid it in escaping immune surveillance, including the establishment of a latent infection in its human host. A latent infection allows the virus to remain in the host without inducing tissue pathology or eliciting an immune response. During the acute infection or reactivation of latent virus, the immune response is significant, which can ultimately result in corneal blindness or fatal sporadic encephalitis. In fact, HSV-1 is one of the leading causes of infectious corneal blindness in the world as a result of chronic episodes of viral reactivation leading to stromal keratitis and scarring. Significant inroads have been made in identifying key immune mediators that control ocular HSV-1 infection and potentially viral reactivation. Likewise, viral mechanisms associated with immune evasion have also been identified and will be discussed. Lastly, novel therapeutic strategies that are currently under development show promise and will be included in this review. Most investigators have taken full advantage of the murine host as a viable working in vivo model of HSV-1 due to the sensitivity and susceptibility to viral infection, ease of manipulation, and a multitude of developed probes to study changes at the cellular and molecular levels. Therefore, comments in this review will primarily be restricted to those observations pertaining to the mouse model and the assumption (however great) that similar events occur in the human condition.     

Biochemical transformation by temperature-sensitive mutants of herpes simplex virus type 1.

Biochemical transformation assays of herpes simplex virus type 1 temperature-sensitive (ts) mutants distinguished three groups of mutants with regard to their thymidine kinase (TK) transforming ability: those incapable of transferring the TK gene at either the permissive or restrictive temperatures (group I); those resembling the wild-type virus, and therefore able to transform at both the permissive and nonpermissive temperatures (group II); and those that failed to transform or exhibited very low transformation frequencies at the permissive temperature but were able to transform at the nonpermissive temperature (group III). Two mutants in group II exhibited greatly enhanced transformation efficiency at the permissive temperature. The ts lesions in the majority of the mutants tested map between 0.30 and 0.60 units on the viral genome. Mutants with TK-positive (TK+), but DNA-negative, phenotypes at the nonpermissive temperature produced no TK+ transformants at the permissive temperature and only unstable transformants at the nonpermissive temperature. This suggests that a function which is required for viral DNA synthesis is also required to obtain stable expression or to transfer the TK+ gene or both when transfer is mediated by the entire viral genome.     

Mutation spectra of herpes simplex virus type 1 thymidine kinase mutants

To examine whether the exonuclease activity intrinsic to the polymerase (Pol) of herpes simplex virus type 1 can influence the mutational spectra, we applied the denaturing gradient gel electrophoresis (DGGE) system combined with sequencing to characterize thymidine kinase mutants isolated from both the wild-type virus and a mutant deficient in exonuclease activity, Y7. Wild-type viruses produced predominantly frameshift mutations (67%), whereas Y7 replicated a significantly lower proportion of frameshifts (21%; P < 0.005). Furthermore, the majority of substitutions were transitional changes in both groups, although they distributed differently. The implications of these findings are discussed.     

Genetic and phenotypic analysis of herpes simplex virus type 1 mutants conditionally resistant to immune cytolysis

Nine temperature-sensitive (ts) mutants of herpes simplex virus type 1 selected for their inability to render cells susceptible to immune cytolysis after infection at the nonpermissive temperature have been characterized genetically and phenotypically. The mutations in four mutants were mapped physically by marker rescue and assigned to functional groups by complementation analysis. In an effort to determine the molecular basis for cytolysis resistance, cells infected with each of the nine mutants were monitored for the synthesis of viral glycoprotein in total cell extracts and for the presence of these glycoproteins in plasma membranes. The four mutants whose ts mutations were mapped were selected with polypeptide-specific antiserum to glycoproteins gA and gB; however, three of the four mutations mapped to DNA sequences outside the limits of the structural gene specifying these glycoproteins. Combined complementation and phenotypic analysis indicates that the fourth mutation also lies elsewhere. The ts mutations in five additional cytolysis-resistant mutants could not be rescued with single cloned DNA fragments representing the entire herpes simplex virus type 1 genome, suggesting that these mutants may possess multiple mutations. Complementation tests with the four mutants whose ts lesions had been mapped physically demonstrated that each represents a new viral gene. Examination of mutant-infected cells at the nonpermissive temperature for the presence of viral glycoproteins in total cell extracts and in membranes at the cell surface demonstrated that (i) none of the five major viral glycoproteins was detected in extracts of cells infected with one mutant, suggesting that this mutant is defective in a very early function; (ii) cells infected with six of the nine mutants exhibited greatly reduced levels of all the major viral glycoproteins at the infected cell surface, indicating that these mutants possess defects in the synthesis or processing of viral glycoproteins; and (iii) in cells infected with one mutant, all viral glycoproteins were precipitable at the surface of the infected cell, despite the resistance of these cells to cytolysis. This mutant is most likely mutated in a gene affecting a late stage in glycoprotein processing, leading to altered presentation of glycoproteins at the plasma membrane. The finding that the synthesis of both gB and gC was affected coordinately in cells infected with six of the nine mutants suggests that synthesis of these two glycoproteins, their transport to the cell surface, or their insertion into plasma membranes is coordinately regulated.     

Inhibition of herpes simplex virus type 1 replication in temperature-sensitive cell cycle mutants.

Herpes simplex virus type 1 DNA synthesis and infections progeny production were studied in five different conditional hamster (BHK-21) cell cycle mutants. At the nonpermissive temperature (39.5 degrees C), both events were strongly inhibited in four of these cell lines. The degree of inhibition was a reproducible characteristic of each cell mutant and in two cases was dependent upon the multiplicity of infection. Experiments involving shifts to the nonpermissive temperature at least 3 h postinfection at 33.5 degrees C suggested that the defects in viral replication were not due to faulty adsorption, penetration, or uncoating, whereas experiments involving shifts of infected cells from the nonpermissive temperature to 33.5 degrees C revealed the reversible nature of the inhibition.     

ND10 components relocate to sites associated with herpes simplex virus type 1 nucleoprotein complexes during virus infection

Infections with DNA viruses commonly result in the association of viral genomes and replication compartments with cellular nuclear substructures known as promyelocytic leukemia protein (PML) nuclear bodies or ND10. While there is evidence that viral genomes can associate with preexisting ND10, we demonstrate in this study by live-cell microscopy that structures resembling ND10 form de novo and in association with viral genome complexes during the initial stages of herpes simplex virus type 1 (HSV-1) infection. Consistent with previous studies, we found that the major ND10 proteins PML, Sp100, and hDaxx are exchanged very rapidly between ND10 foci and the surrounding nucleoplasm in live cells. The dynamic nature of the individual protein molecule components of ND10 provides a mechanism by which ND10 proteins can be recruited to novel sites during virus infection. These observations explain why the genomes and replication compartments of DNA viruses that replicate in the cell nucleus are so commonly found in association with ND10. These findings are discussed with reference to the nature, location, and potential number of HSV-1 prereplication compartments and to the dynamic aspects of HSV-1 genomes and viral products during the early stages of lytic infection.     

Viral DNA synthesis in cells infected with temperature-sensitive mutants of herpes simplex virus type 1.

Temperature-sensitive mutants of herpes simplex virus type 1 representing eight DNA-negative complementation groups were grouped into the following three categories based on the viral DNA synthesis patterns after shift-up from the permissive to the nonpermissive temperature and after shift-down from the nonpermissive to the permissive temperature in the presence and absence of inhibitors of RNA and protein synthesis. (i) Viral DNA synthesis was inhibited after shift-up in cells infected with tsB, tsH, and tsJ. After shift-down, tsB- and tsH-infected cells synthesized viral DNA in the absence of de novo RNA and protein synthesis whereas tsJ-infected cells synthesized no viral DNA in the absence of protein synthesis. The B, H, and J proteins appear to be continuously required for the synthesis of viral DNA. (ii) Viral DNA synthesis continued after shift-up in cells infected with tsD and tsK whereas no viral DNA was synthesized after shift-down in the absence of RNA and protein synthesis. Mutants tsD and tsK appear to be defective in early regulatory functions. (iii) Cells infected with tsL, tsS, and tsU synthesized viral DNA after shift-up and after shift-down in the absence of RNA and protein synthesis. The functions of the L, S, and U proteins cannot yet be determined.     

Host range temperature-sensitive mutants of herpes simplex virus type 2.

Two small-plaque mutants of herpes simplex virus type 2 (HSV-2) (strain 333), whose growth at 39 C was blocked in certain cell types (cell-dependent temperature sensitivity), were compared compared with parental virus in a number of biological assays. One mutant (no. 69) was found to produce a large number of morphologically normal, but noninfectious, particles; under nonpermissive conditions, these mutant particles were able to interfere with the replication of wild-type HSV-2. The other mutant (no. 74), which is known to belong to a different complementation group, appeared to direct little virus DNA synthesis, even at the permissive temperature. Progeny production and virus DNA synthesis in cells infected by mutant 74 were delayed in comparison with wild-type virus-infected cells. Both mutants were found to be more sensitive to UV irradiation than the parental virus; this was especially marked in the case of mutant 74. Moreover, this mutant was found to have a high transforming efficiency at much lower doses of irradiation than those needed to abolish the cytopathic effect of wildtype HSV-2.     

Temperature-sensitive host range mutants of herpes simplex virus type 2.

Herpesviruses are capable of several types of infection of a host cell. To investigate the early events which ultimately determine the nature of the virus-host cell interaction, a system was established utilizing temperature-sensitive mutants of herpes simplex virus type 2. Four mutants have been isolated which fail to induce cytopathic effects and do not replicate at 39 C in hamster embryo fibroblast cells. At least one mutant is virus DNA negative. Since intracellular complementation is detectable between pairs of mutants, a virus function is known to be temperature sensitive. However, all four mutants induce cytopathic effects and replicate to parental virus levels in rabbit kidney cells at 39 C. This suggests that a host cell function, lacking or nonfunctional in HEF cells but present in rabbit kidney cells at 39 C, is required for the replication of these mutants in hamster embryo fibroblasts cells at 39 C. Therefore, we conclude that these mutants are both temperature sensitive and exhibit host range properties.     

Ribonucleotide reductase of herpes simplex virus type 2 resembles that of herpes simplex virus type 1.

The ribonucleotide reductase (ribonucleoside-diphosphate reductase; EC 1.17.4.1) induced by herpes simplex virus type 2 infection of serum-starved BHK-21 cells was purified to provide a preparation practically free of both eucaryotic ribonucleotide reductase and contaminating enzymes that could significantly deplete the substrates. Certain key properties of the herpes simplex virus type 2 ribonucleotide reductase were examined to define the extent to which it resembled the herpes simplex virus type 1 ribonucleotide reductase. The herpes simplex virus type 2 ribonucleotide reductase was inhibited by ATP and MgCl2 but only weakly inhibited by the ATP X Mg complex. Deoxynucleoside triphosphates were at best only weak inhibitors of this enzyme. ADP was a competitive inhibitor (K'i, 11 microM) of CDP reduction (K'm, 0.5 microM), and CDP was a competitive inhibitor (K'i, 0.4 microM) of ADP reduction (K'm, 8 microM). These key properties closely resemble those observed for similarly purified herpes simplex virus type 1 ribonucleotide reductase and serve to distinguish these virally induced enzymes from other ribonucleotide reductases.     

Expression of herpes simplex virus type 1 glycoprotein D deletion mutants in mammalian cells.

Glycoprotein D (gD) is a viron envelope component of herpes simplex virus types 1 and 2. We have previously defined seven monoclonal antibody (MAb) groups which recognize distinct epitopes on the mature gD-1 protein of 369 amino acids. MAb groups VII, II, and V recognize continuous epitopes at residues 11-19, 272-279, and 340-356, respectively. MAb groups I, III, IV, and VI recognize discontinuous epitopes. Recent studies have focused on epitopes I, III, and VI. Using truncated forms of gD generated by recombinant DNA methods and proteolysis, epitopes III, IV, and VI were located within amino acids 1-233. A portion of discontinuous epitope I was located in a region within residues 233-275. For this study, we used recombinant DNA methods to create mutations in the gD-1 gene and studied the effects of those mutations on gD as expressed in mammalian cells. Plasmid pRE4, containing the coding sequence of gD-1 and the Rous sarcoma virus long terminal repeat promoter, was transfected into mammalian cells. The expressed protein, gD-1-(pRE4), was identical in size and antigenic properties to gD-1 from infected cells. Six in-frame deletion mutations were subsequently constructed by using restriction enzymes to excise portions of the gD-1 gene. Plasmids carrying these mutated forms were transfected into cells, and the corresponding proteins were examined at 48 h posttransfection for antigenicity and glycosylation patterns. Three deletions of varying size were located downstream of residue 233. Analysis of these mutants showed that amino acids within the region 234-244 were critical for binding of DL11 (group I), but not for other MAb groups. Three other deletion mutants lost all ability to bind MAbs which recognize discontinuous epitopes. In addition, much of the gD expressed by these mutants was observed to migrate as high-molecular-weight aggregated forms in nondenaturing gels. Each of these mutations involved the loss of a cysteine residue, suggesting that disulfide linkages play an essential role in the formation of discontinuous epitopes. The extent of glycosylation of the mutant gD molecules accumulated at 48 h posttransfection suggested altered carbohydrate processing. In one case, there was evidence for increased O-linked glycosylation. Those proteins which had lost a cysteine residue as part of the deletion did not accumulate molecules processed beyond the high-mannose stage. The results suggest that carbohydrate processing during synthesis of gD is very sensitive to alterations in structure, particularly changes involving cysteine residues.     

Linker histones are mobilized during infection with herpes simplex virus type 1

Histones interact with herpes simplex virus type 1 (HSV-1) genomes and localize to replication compartments early during infections. However, HSV-1 genomes do not interact with histones in virions and are deposited in nuclear domains devoid of histones. Moreover, late viral replication compartments are also devoid of histones. The processes whereby histones come to interact with HSV-1 genomes, to be later displaced, remain unknown. However, they would involve the early movement of histones to the domains containing HSV-1 genomes and the later movement away from them. Histones unbind from chromatin, diffuse through the nucleoplasm, and rebind at different sites. Such mobility is upregulated by, for example, phosphorylation or acetylation. We evaluated whether HSV-1 infection modulates histone mobility, using fluorescence recovery after photobleaching. All somatic H1 variants were mobilized to different degrees. H1.2, the most mobilized, was mobilized at 4 h and further so at 7 h after infection, resulting in increases in its "free" pools. H1.2 was mobilized to a "basal" degree under conditions of little to no HSV-1 protein expression. This basal mobilization required nuclear native HSV-1 genomes but was independent of HSV-1 proteins and most likely due to cellular responses. Mobilization above this basal degree, and increases in H1.2 free pools, however, depended on immediate-early or early HSV-1 proteins, but not on HSV-1 genome replication or late proteins. Linker histone mobilization is a novel consequence of cell-virus interactions, which is consistent with the dynamic interactions between histones and HSV-1 genomes during lytic infection; it may also participate in the regulation of viral gene expression.     

Repression of gene expression upon infection of cells with herpes simplex virus type 1 mutants impaired for immediate-early protein synthesis.

Herpes simplex virus type 1 (HSV-1) mutants defective in immediate-early (IE) gene expression do not readily enter productive replication after infection of tissue culture cells. Instead, their genomes are retained in a quiescent, nonreplicating state in which the production of viral gene products cannot be detected. To investigate the block to virus replication, we used the HSV-1 triple mutant in1820K, which, under appropriate conditions, is effectively devoid of the transactivators VP16 (a virion protein), ICP0, and ICP4 (both IE proteins). Promoters for the HSV-1 IE ICP0 gene or the human cytomegalovirus (HCMV) major IE gene, cloned upstream of the Escherichia coli lacZ coding sequences, were introduced into the in1820K genome. The regulation of these promoters and of the endogenous HSV-1 IE promoters was investigated upon conversion of the virus to a quiescent state. Within 24 h of infection, the ICP0 promoter became much less sensitive to transactivation by VP16 whereas the same element, when used to transform Vero cells, retained its responsiveness. The HCMV IE promoter, which is not activated by VP16, also became less sensitive to the HCMV functional homolog of VP16. Both elements remained available for transactivation by HSV-1 IE proteins at 24 h postinfection, showing that the in1820K genome was not irreversibly inactivated. The promoters controlling the HSV-1 ICP4, ICP22, and ICP27 genes also became essentially unresponsive to transactivation by VP16. The ICP0 promoter was induced when hexamethylene bisacetamide was added to cultures at the time of infection, but the response to this agent was also lost by 24 h after infection. Therefore, promoter elements within the HSV-1 genome are actively repressed in the absence of IE gene expression, and repression is not restricted specifically to HSV-1 IE promoters.     

Temperature-sensitive mutants of herpes simplex virus type 1 defective in lysis but not in transformation.

Twelve temperature-sensitive (ts) mutants of herpes simplex virus type 1 (HSV-1), representing seven complementation groups, were isolated subsequent to 5-bromodeoxyuridine mutagenesis. These mutants were identified by their inability to replicate in a line of monkey (CV-1) cells at 39 C. Seven of these mutants, representing six complementation groups, induced thymidine kinase (tk) and transformed Ltk- cells, a line of mouse L cells lacking tk, to a tk+ phenotype at both the permissive (34 C) and nonpermissive (39 C) temperatures. Thus, the defective cistrons in these six complementation groups, although necessary for lysis, have no essential function in this transformation system. Transformation by these 12 mutants was dependent on prior UV irradiation. Infection of cells with unirradiated virus under conditions which did not permit virus replication was not sufficient to allow cell transformation. Five mutants, representing two complementation groups, were tk- and were incapable of causing the tk--to-tk+ transformation at either 34 C of 39 C. The tk defects in these mutants are probably unrelated to the ts defects, since one of these complementation groups contains a tk+ member. Therefore, transformation of Ltk- cells to a tk+ phenotype by HSV-1 requires an active viral tk gene. One complementation group was represented by a single tk- member. The role of this cistron in transformation remains undetermined since the primary block to transformation is presumed to be the tk- phenotype. Mutants representing the seven complementation groups were unable to replicate at 39 C in two lines of HSV-1-transformed cells, indicating that the activities of resident wild-type copies of the defective cistrons, if present, could not be detected by complementation.