Efficient reactivation of latent herpes simplex virus from mouse central nervous system tissues

For decades, numerous ex vivo studies have documented that latent herpes simplex virus (HSV) reactivates efficiently from ganglia, but rarely from the central nervous systems (CNS), of mice when assayed by mincing tissues before explant culture, despite the presence of viral genomes in both sites. Here we show that 88% of mouse brain stems reactivated latent virus when they were dissociated into cell suspensions before ex vivo explant culture. The efficient reactivation of HSV from the mouse CNS was demonstrated with more than one viral strain, viral serotype, and mouse strain, further indicating that the CNS can be an authentic latency site for HSV with the potential to cause recurrent disease.     

Role of specific innate immune responses in herpes simplex virus infection of the central nervous system

Herpes simplex virus 1 (HSV-1) causes a spectrum of disease, including herpes labialis, herpes keratitis, and herpes encephalitis, which can be lethal. Viral recognition by pattern recognition receptors plays a central role in cytokine production and in the generation of antiviral immunity. The relative contributions of different Toll-like receptors (TLRs) in the innate immune response during central nervous system infection with HSV-1 have not been fully characterized. In this study, we investigate the roles of TLR2, TLR9, UNC93B1, and the type I interferon (IFN) receptor in a murine model of HSV-1 encephalitis. TLR2 is responsible for detrimental inflammatory cytokine production following intracranial infection with HSV-1, and the absence of TLR2 expression leads to increased survival in mice. We prove that inflammatory cytokine production by microglial cells, astrocytes, neutrophils, and monocytes is mediated predominantly by TLR2. We also demonstrate that type I IFNs are absolutely required for survival following intracranial HSV-1 infection, as mice lacking the type I IFN receptor succumb rapidly following infection and have high levels of HSV in the brain. However, the absence of TLR9 does not impact survival, type I IFN levels, or viral replication in the brain following infection. The absence of UNC93B1 leads to a survival disadvantage but does not impact viral replication or type I IFN levels in the brain in HSV-1-infected mice. These results illustrate the complex but important roles that innate immune receptors play in host responses to HSV-1 during infection of the central nervous system.     

Selective spread of herpes simplex virus in the central nervous system after ocular inoculation.

The spread of herpes simplex virus (HSV) was studied in the mouse central nervous system (CNS) after ocular inoculation. Sites of active viral replication in the CNS were identified by autoradiographic localization of neuronal uptake of tritiated thymidine. Labeled neurons were first noted in the CNS at 4 days postinoculation in the Edinger-Westphal nucleus, ipsilateral spinal trigeminal nucleus, pars caudalis, pars interpolaris, and ipsilateral dorsal horn of the rostral cervical spinal cord. By 5 days postinoculation, additional sites of labeling included the seventh nerve nucleus, nucleus locus coeruleus, and the nuclei raphe magnus and raphe pallidus. None of these sites are contiguous to nuclei infected at 4 days, but all are synaptically related to these nuclei. By 7 days postinoculation, no new foci of labeled cells were noted in the brain stem, but labeled neurons were noted in the amygdala, hippocampus, and somatosensory cortex. Neurons in both the amygdala and hippocampus receive axonal projections from the locus coeruleus. On the basis of these findings, we conclude that the spread of HSV in the CNS after intracameral inoculation is not diffuse but is restricted to a small number of noncontiguous foci in the brain stem and cortex which become infected in a sequential fashion. Since these regions are synaptically related, the principal route of the spread of HSV in the CNS after ocular infection appears to be along axons, presumably via axonal transport rather than by local spread.     

Uncoating the herpes simplex virus genome

Initiation of infection by herpes simplex virus (HSV-1) involves a step in which the parental virus capsid docks at a nuclear pore and injects its DNA into the nucleus. Once "uncoated" in this way, the virus DNA can be transcribed and replicated. In an effort to clarify the mechanism of DNA injection, we examined DNA release as it occurs in purified capsids incubated in vitro. DNA ejection was observed following two different treatments, trypsin digestion of capsids in solution, and heating of capsids after attachment to a solid surface. In both cases, electron microscopic analysis revealed that DNA was ejected as a single double helix with ejection occurring at one vertex presumed to be the portal. In the case of trypsin-treated capsids, DNA release was found to correlate with cleavage of a small proportion of the portal protein, UL6, suggesting that UL6 cleavage may be involved in making the capsid permissive for DNA ejection. In capsids bound to a solid surface, DNA ejection was observed only when capsids were warmed above 4 degrees C. The proportion of capsids releasing their DNA increased as a function of incubation temperature with nearly all capsids ejecting their DNA when incubation was at 37 degrees C. The results demonstrate heterogeneity among HSV-1 capsids with respect to their sensitivity to heat-induced DNA ejection. Such heterogeneity may indicate a similar heterogeneity in the ease with which capsids are able to deliver DNA to the infected cell nucleus.     

Temporal association of the herpes simplex virus genome with histone proteins during a lytic infection

Previous work has determined that there are nucleosomes on the herpes simplex virus (HSV) genome during a lytic infection but that they are not arranged in an equally spaced array like in cellular DNA. However, like in cellular DNA, the promoter regions of several viral genes have been shown to be associated with nucleosomes containing modified histone proteins that are generally found associated with actively transcribed genes. Furthermore, it has been found that the association of modified histones with the HSV genome can be detected at the earliest times postinfection (1 h postinfection) and increases up to 3 h postinfection. However from 3 h to 6 h postinfection (the late phase of the replication cycle), the association decreases. In this study we have examined histone association with promoter regions of all kinetic classes of genes. This was done over the time course of an infection in Sy5y cells using sucrose gradient sedimentation, bromodeoxyuridine labeling, chromatin immunoprecipitation assays, Western blot analysis, trypsin and DNase digestion, and quantitative real-time PCR. Because no histones were detected inside HSV type 1 capsids, the viral genome probably starts to associate with histones after being transported from infecting virions into the host nucleus. Promoter regions of all gene classes (immediate early, early, and late) bind with histone proteins at the start of viral gene expression. However, after viral DNA replication initiates, histones appear not to associate with newly synthesized viral genomes.     

Complementary lethal invasion of the central nervous system by nonneuroinvasive herpes simplex virus types 1 and 2.

It is well-known that viral thymidine kinase (TK) expression is important for the maximum demonstration of virulence of herpes simplex virus (HSV). In this study, we have investigated interactions of a TK- mutant of virulent HSV type 2 (HSV-2) (syn+) and a nonneuroinvasive HSV-1 (syn) in mice. When the mice were inoculated with each virus alone in their rear footpads, no mice were killed even after infection with high doses of viruses (greater than 10(6) PFU per mouse), whereas 100% of the mice died when inoculated with 10(5) PFU of a 1:1 mixture of HSV-2 TK- mutant and nonneuroinvasive HSV-1. The 1:1 mixture exhibited even more virulence than the parental HSV-2; the mean survival time of coinfected mice was significantly shorter than that of mice inoculated with 10(5) PFU of the virulent HSV-2. We have also examined the genotypes and phenotypes of viruses isolated from the central nervous system of coinfected mice. Of 50 isolates, 7 were judged to be recombinants from their restriction endonuclease cleavage patterns, but all were nonneuroinvasive. In addition, all syn+ viruses (23 clones) tested were found to have TK- phenotypes, indicating that the majority of viruses present in the central nervous system were TK- viruses, since about 90% of viruses detected in spinal cords and brains exhibited syn+ phenotypes. These results strongly suggest that the lethal invasion of the central nervous system by HSV-2 TK- and nonneuroinvasive HSV-1 was the consequence of in vivo complementation between the two viruses.     

Intrauterine herpes simplex virus infection

Neonatal herpes simplex virus (HSV) infection usually is the consequence of intrapartum infection, with disease onset between 5 and 15 days of life. More recently, intrauterine HSV infection has been identified. Intrauterine infection is apparent within the first 24-48 hr of life and is associated with skin vesicles/scarring, chorioretinitis, and/or hydraencephaly. The recognition that babies with these findings can have disease caused by HSV should prompt enhanced physician awareness in the evaluation of newborns with suspected intrauterine infection. The frequency of intrauterine infection appears to be about 5% of all babies with neonatal HSV infection.     

Cytochemical analysis of DNA organization during encapsidation in herpes simplex virus

The organization of intranuclear Herpes simplex virus DNA in rabbit fibroblast cells infected for 7 hr with HSV type 1 was examined before and during encapsidation by electron microscopic cytochemistry. Most non-encapsidated viral deoxyribonucleoprotein fibers exhibited a non-nucleosomal configuration. Empty capsids within the virus-specific regions of infected nuclei were wrapped with portions of the viral genome which adhered tightly to their surfaces even under conditions that loosened and spread apart other nucleoprotein fibers. During encapsidation, the internal surface of the capsid shell also appeared to bind a part of the viral genome, specifically the outer cage portion, which is detectable in methanol-dehydrated cells. Variations in the amount of DNA within the capsids indicated that the insertion of HSV genome into the capsid is a progressive process. The cage and core cylinder portions of the viral nucleoid appear to form and develop simultaneously. We propose that there may be binding sites on both the external and internal surfaces of the capsid shells which might play a role in the encapsidation process.     

Involvement of apolipoprotein E in the hematogenous route of herpes simplex virus type 1 to the central nervous system

Apolipoprotein E (ApoE), a constituent of the lipoproteins, may be relevant in herpes simplex virus type 1 (HSV-1) infection of the central nervous system (CNS), since HSV-1 binds to human serum ApoE lipoproteins. This study demonstrates the involvement of ApoE in the hematogenous route of HSV-1 to the CNS.     

Herpes simplex virus glycoprotein D mediates interference with herpes simplex virus infection.

We showed that the expression of a single protein, glycoprotein D (gD-1), specified by herpes simplex virus type 1 (HSV-1) renders cells resistant to infection by HSV but not to infection by other viruses. Mouse (LMtk-) and human (HEp-2) cell lines containing the gene for gD-1 under control of the human metallothionein promoter II expressed various levels of gD-1 constitutively and could be induced to express higher levels with heavy metal ions. Radiolabeled viruses bound equally well to gD-1-expressing and control cell lines. Adsorbed viruses were unable to penetrate cells expressing sufficient levels of gD-1, based on lack of any cytopathic effects of the challenge virus and on failure to detect either the induction of viral protein synthesis or the shutoff of host protein synthesis normally mediated by a virion-associated factor. The resistance to HSV infection conferred by gD-1 expression was not absolute and depended on several variables, including the amount of gD-1 expressed, the dosage of the challenge virus, the serotype of the challenge virus, and the properties of the cells themselves. The interference activity of gD-1 is discussed in relation to the role of gD-1 in virion infectivity and its possible role in permitting escape of progeny HSV from infected cells.     

Molecular biology of herpes simplex virus type 1 latency in the nervous system

Herpes simplex virus (HSV) is one of the best studied examples of viral ability to remain latent in the human nervous system and to cause recurrent disease by reactivation. Intensive effort was directed in recent years to unveil the molecular viral mechanisms and the virus-host interactions associated with latent HSV infection. The discovery of the state of the latent viral DNA in nervous tissues and of the presence of latency-associated gene expression during latent infection, both differing from the situation during viral replication, provided important clues relevant to the pathogenesis of latent HSV infection. This review summarizes the current state of knowledge on the site of latent infection, the molecular phenomena of latency, and the mechanisms of the various stages of latency: acute infection, establishment and maintenance of latency, and reactivation. This information paved the way to recent trials aiming to use herpes viruses as vectors to deliver genes into the nervous system, an issue that is also addressed in this review.     

Cellular proteins expressed in herpes simplex virus transformed cells also accumulate on herpes simplex virus infection.

The cell proteins expressed in rat embryo cells transformed by herpes simplex virus (HSV) have been analysed by immunoprecipitation assays to determine those polypeptides which can be identified by immunoprecipitation with the sera of tumour-bearing animals and also with antisera to herpes simplex infected cells. Cell polypeptides commonly recognised by both these sera have been further characterised using a monoclonal antibody directed against a cellular polypeptide which accumulates on HSV-2 lytic infection. This monoclonal antibody recognises in HSV-transformed cells polypeptides of mol. wts. 90 000, 40 000 and 32 000. Further studies show that the accumulation of these polypeptides in HSV-transformed cells is not HSV specific but is a common feature of transformation or of cells which have been immortalised. We suggest that cellular polypeptides accumulating as a result of HSV infection may be of importance in the initiation of transformation by HSV, i.e., at the level of immortalisation of cells.