Induction of reactivation of herpes simplex virus in murine sensory ganglia in vivo by cadmium

Herpes simplex viruses maintained in a latent state in sensory neurons in mice do not reactivate spontaneously, and therefore the factors or procedures which cause the virus to reactivate serve as a clue to the mechanisms by which the virus is maintained in a latent state. We report that cadmium sulfate induces latent virus to reactivate in 75 to 100% of mice tested. The following specific findings are reported. (i) The highest frequency of induction was observed after two to four daily administrations of 100 micrograms of cadmium sulfate. (ii) Zinc, copper, manganese, or nickel sulfate administered in equimolar amounts under the same regimen did not induce viral reactivation; however, zinc sulfate in molar ratios 25-fold greater than those of cadmium induced viral replication in 2 of 16 ganglia tested. (iii) Administration of zinc, nickel, or manganese prior to the cadmium sulfate reduced the incidence of ganglia containing infectious virus. (iv) Administration of cadmium daily during the first week after infection and at 2-day intervals to 13 days after infection resulted in the recovery from ganglia of infectious virus in titers 10- to 100-fold higher than those obtained from animals given saline. Moreover, infectious virus was recovered as late as 11 days after infection compared with 6 days in mice administered saline. (v) Administration of cadmium immediately after infection or repeatedly after establishment of latency did not exhaust the latent virus harbored by sensory neurons, inasmuch as the fraction of ganglia of mice administered cadmium and yielding infectious virus was similar to that observed in mice treated with saline. We conclude that induction of cadmium tolerance precludes reactivation of latent virus. If the induction of metallothionein genes was the sole factor required to cause reactivation of latent virus, it would have been expected that all metals which induce metallothioneins would also induce reactivation, which was not observed. The results therefore raise the possibility that in addition to inducing the metallothionein genes, cadmium inactivates the factors which maintain the virus in latent state.

Vaccination of pigs against pseudorabies with highly attenuated vaccinia (NYVAC) recombinant viruses

Poxvirus recombinants, based on the highly attenuated NYVAC strain of vaccinia virus (Tartaglia et al., 1992), containing single gene inserts encoding the pseudorabies virus (PRV) gII, gIII, or gp50 glycoproteins were tested for their immunogenicity in pigs. Twenty-four pigs were randomly divided into six groups of four. Groups 1-3 were inoculated with 10(7) CCID50 of NYVAC/PRV gII, NYVAC/PRV gIII, or NYVAC/PRV gp50, respectively, while groups 4 and 5 received the NYVAC parent virus or an inactivated PRV vaccine control, respectively. Group 6 represented the sham vaccinated control group. All inoculations were given by the intramuscular route on weeks 0 and 4. The candidate vaccines were shown to be safe with no local or systemic reactions. At 4 weeks following the second inoculation, all pigs were challenged by an oronasal administration of a virulent PRV strain. Pigs were monitored before and after challenge for clinical manifestations resulting from vaccination and challenge exposure, respectively. Sera were analyzed for PRV neutralizing activity. Virological analyses after challenge included assessment of virus shedding and the development of latent PRV infections. All but one animal developed latent PRV infection following challenge exposure; however, significant protection against PRV-induced signs was afforded by vaccination with either the NYVAC/PRV gp50 or NYVAC/PRV gII recombinant viruses, as well as with the inactivated PRV vaccine. The NYVAC/PRV gp50 also reduced overall virus shedding after challenge. The extent of protection against PRV-induced clinical signs, in general, was associated with the level of pre-challenge virus neutralizing activity.

Mechanism of pruritus and peracute death in mice induced by pseudorabies virus (PRV) infection

Mechanisms of postinfectious pruritus and peracute death in mice by pseudorabies virus (PRV) were investigated by inoculating the Yamagata-S81 strain of PRV peripherally or intracerebrally into 4-week-old ICR and BALB/c mice. Clinical signs developed most rapidly in mice inoculated intracerebrally, with intermediate speed in mice inoculated intraocularly, and slowly in mice inoculated subcutaneously. Since intraocularly inoculated mice showed an acute reaction and this is considered a peripheral route, the distribution of viral antigens in the nervous system of intraocularly inoculated mice was examined immunohistologically. Viral antigens were mainly detected along the trigeminal and the oculomotor nerves, but neither necrosis nor an inflammatory response was observed in these areas. The infectious virus was efficiently recovered from the viral antigen-positive tissues. In the pruritic skin lesions, viral antigens were not observed. These findings indicate that the main route of viral spread in intraocularly inoculated mice is the trigeminal and oculomotor nerves and that the virus in the trigeminal nerve may trigger pruritus.

Latent infection with the MS strain of herpes simplex virus type 2 in the mouse following intracerebral inoculation

Intracerebral inoculation of the MS strain of herpes simplex virus type 2 (HSV-2) into mice causes an acute encephalitis associated with multifocal demyelination and necrotizing retinitis. We have studied the distribution of latent virus in mice that had recovered from the acute encephalitis. Four weeks or longer after inoculation, HSV-2 could be recovered from the trigeminal ganglia of all mice examined by co-culture of explants in roller tubes. The virus could not be recovered from explants of retina or brain stem. HSV-2 latency associated transcript (LAT) was readily detected in the trigeminal ganglia by reverse transcriptase-PCR more than 4 months after inoculation. LAT was also demonstrated in the brain but this required nested PCR for consistent detection. Both LAT and ICP0 mRNA were detected in brain tissue during the acute encephalitis but, unlike LAT, ICP0 mRNA could not be amplified from the trigeminal ganglia or brain beyond 4 weeks after inoculation of the virus. In situ hybridisation with a double-stranded DNA probe to the ICP0/LAT overlap region of HSV-2 revealed signal in trigeminal ganglion neurons and occasional cells in the brain stem. These findings indicate that HSV-2 introduced by intracerebral inoculation becomes latent in the trigeminal ganglia and that transcription of LAT also persists within the brain.

Herpes simplex virus type 1 latency-associated transcript (LAT) promoter deletion mutants can express a 2-kilobase transcript mapping to the LAT region

The results of studies in several laboratories suggest that a TATA box-containing promoter located in the herpes simplex virus type 1 internal long repeat and long terminal repeat elements drives expression of the latency-associated transcripts (LATs). In the present study, we show that expression of a 2-kb LAT-related transcript can occur in the absence of this LAT TATA promoter, indicating the existence of a cryptic promoter. By Northern (RNA) blot analysis, we have examined LAT expression by herpes simplex virus type 1 variant strains KOS/29 and 1704, which contain deletions of the LAT promoter region. Our data indicate that KOS/29, despite lacking the 203-bp fragment which contains the LAT TATA box, can express a 2-kb LAT-related transcript during productive infection in tissue culture and in mouse trigeminal ganglia during acute infection and reactivation. Similarly, strain 1704, which contains a larger deletion in this promoter region, also expresses a 2-kb LAT-related transcript during tissue culture infection and reactivation of latently infected trigeminal ganglia. However, LATs are not expressed with either virus during latency. Northern blot analysis with a single-stranded, oligonucleotide probe demonstrates that the 2-kb LAT and LAT-related transcript are colinear and share a large area of sequence similarity. These findings suggest the existence of a second promoter in the LAT gene which can function during lytic infection and reactivation, at least in the absence of the LAT TATA promoter. We propose that this cryptic promoter is located either in a proximal region approximately 300 bp upstream of the start site of the 2-kb LAT or in a distal region starting over 1,226 bp upstream of this site.

Immunization with the immediate-early tegument protein (open reading frame 62) of varicella-zoster virus protects guinea pigs against virus challenge

The IE62 protein, the primary regulatory protein of varicella-zoster virus (VZV) and the major component of the virion tegument, was an effective immunogen in the guinea pig model of VZV infection, whereas the ORF 29 gene product, a nonstructural DNA replication protein, did not elicit protection. All animals immunized with the ORF 29 protein had cell-associated viremia compared with 2 of 11 guinea pigs given the IE62 protein (P = 0.005). VZV was detected in ganglia from 38% of the animals given the ORF 29 protein and 44% of the control animals compared with 9% of the animals immunized with the IE62 protein (P = 0.04). In contrast to the IE62 protein, immunization with the ORF 29 protein did not prime the animals for an enhanced T-cell response upon challenge with infectious virus. The VZV IE62 protein has potential value as a vaccine component.

Characterization of an in vivo reactivation model of herpes simplex virus from mice trigeminal ganglia

Herpes simplex virus type 1 (HSV-1) is transcriptionally active during latent infection in human peripheral sensory ganglia. Viral gene expression includes the latency-associated transcripts (LATs) which have been linked to the ability of the virus to resume replication and reactivate. However, the molecular basis of reactivation and the mechanisms of action of these transcripts are unknown. In order to study these parameters, an in vivo reactivation model is needed. We investigated use of the mouse as the experimental animal, modifying the route of infection, the viral strain and the reactivation protocol. Following administration of human immunoglobulin 1 day prior to corneal infection, no infectious virus was detected in trigeminal ganglia (TG). However, latency was established in all infected animals as indicated by explant reactivation of TG, and in vivo reactivation was achieved in 30 to 40% of them. DNA quantification revealed that TG of immunized mice contained more HSV-1 DNA than did those of non-immunized mice. By in situ hybridization twice as many neuronal cells in TG of immunized mice were positive for LATs, compared with infected but non-immunized, mice. These findings suggest that suppression of primary infection facilitates reactivation by increasing HSV-1 copy number in latently infected nervous tissue.

Herpes simplex virus thymidine kinase and specific stages of latency in murine trigeminal ganglia

From marker rescue, sequencing, transcript, and latency analyses of the thymidine kinase-negative herpes simplex virus mutant dlsactk and studies using the thymidine kinase inhibitor Ro 31-5140, we infer that the virus-encoded thymidine kinase is required in murine trigeminal ganglia for acute replication and lytic gene expression, for increasing the numbers of cells expressing latency-associated transcripts, and for reactivation from latent infection.

An HSV-1 mutant lacking the LAT TATA element reactivates normally in explant cocultivation

In order to examine if mutations within the LAT promoter region of HSV-1 are sufficient to change the reactivation phenotype, a mutant (KOS/29) containing a deletion of the LAT TATA element was used to establish latent infections in mouse ganglia by corneal inoculation. During the acute phase of infection, KOS/29 replicated as efficiently as its wild-type parent. As previously noted, latent KOS/29 infections were totally devoid of LAT gene transcripts (Dobson A. T., Sederati F., Devi-Rao G., Flanagan J., Farrell M. J., Stevens J. G., Wagner E. K., and Feldman L. T., J. Virol. 63, 3844-3851 (1989))). However, unlike other null mutants, KOS/29 reactivated from explanted ganglia with a kinetics similar to that of the LAT competent parent. These data show that the deletion created in KOS/29, removing the LAT TATA promoter element and small upstream and downstream flanking sequences, is not enough to alter the reactivation phenotype and that efficient reactivation can occur in the absence of any detectable LAT expression during latency.

Detection of active and latent feline herpesvirus 1 infections using the polymerase chain reaction

A polymerase chain reaction (PCR) assay was developed to detect the thymidine kinase gene of feline herpesvirus 1 (FHV-1) and to study the active and latent carrier state in a group of naturally FHV-1 infected specific pathogen free (SPF) cats. The detection limit of PCR products on ethidium bromide stained gels was 390 fg or about 3 x 10(3) copies of the FHV-1 genome. The PCR was 25% more sensitive than conventional cell culture based virus isolation techniques in detecting FHV-1 in oral/ocular swabs and 100 times more sensitive in detecting virus in cell culture supernatants. Sites of FHV-1 latency in FHV-1 carriers as determined by PCR were mainly tissues of the head, especially the trigeminal ganglia, optic nerves, olfactory bulbs and corneas. Oral fauces, salivary glands, lacrimal glands, cerebellum and conjunctiva were less consistently positive. The cerebral cortex, thymus, trachea, lung, liver, spleen, kidney, and peripheral blood mononuclear cells were consistently negative for FHV-1 genome. The distribution of FHV-1 DNA in the tissues of the head was similar whether or not corticosteroid-induced virus shedding was occurring at the time the tissues were collected. Infectious virus was never recovered from tissue homogenates regardless of the PCR status of the tissues.

Evidence for a novel regulatory pathway for herpes simplex virus gene expression in trigeminal ganglion neurons

Thymidine kinase (TK)-negative (TK-) mutant strains of herpes simplex virus type 1 (HSV-1) show reduced expression of alpha and beta viral genes during acute infection of trigeminal ganglion neurons following corneal infection (M. Kosz-Vnenchak, D. M. Coen, and D. M. Knipe, J. Virol. 64:5396-5402, 1990). It was surprising that a defect in a beta gene product would lead to decreased alpha and beta gene expression, given the regulatory pathways demonstrated for HSV infection of cultured cells. In this study, we have examined viral gene expression during reactivation from latent infection in explanted trigeminal ganglion tissue. In explant reactivation studies with wild-type virus, we observed viral productive gene expression over the first 48 h of explant incubation occurring in a temporal order (alpha, beta, gamma) similar to that in cultured cells. This occurred predominantly in latency-associated transcript-positive neurons but was limited to a fraction of these cells. In contrast, TK- mutant viruses showed greatly reduced alpha and beta gene expression upon explant of latently infected trigeminal ganglion tissue. An inhibitor of viral TK or an inhibitor of viral DNA polymerase greatly decreased viral lytic gene expression in trigeminal ganglion tissue latently infected with wild-type virus and explanted in culture. These results indicate that the regulatory mechanisms governing HSV gene expression are different in trigeminal ganglion neurons and cultured cells. We present a new model for viral gene expression in trigeminal ganglion neurons with implications for the nature of the decision process between latent infection and productive infection by HSV.

A mouse model for varicella-zoster virus latency

Following primary infection with varicella-zoster virus (VZV), the virus establishes a latent infection in humans. The molecular pathogenesis of VZV latency is not well understood, mainly due to the lack of an adequate animal model. We report here that we have developed a mouse model for VZV infection that involves corneal inoculation of mice. Although infected animals showed no signs of disease, most of the animals could not eliminate the virus early after infection. By PCR, we demonstrated that at 33 days post-infection (p.i.), viral DNA was still present in more than 60% of the animals (14/21). VZV DNA was most frequently detected in the trigeminal ganglia (7/14) followed by the brain stem (10/21), kidneys (4/21), spleen (3/20), liver (2/21) and brain (1/21). By in situ hybridization, a few cells positive for VZV mRNA were detected in the trigeminal ganglia, brain stem, cerebellum and spleen of a small number of the infected animals as late as 33 days p.i. No viral proteins were detected at the site of inoculation or in any other tissue by immunostaining. Our results suggest that VZV spreads in mice by both viraemia and axonal transport and establishes a non-productive (latent) infection.

Intranuclear foci containing low abundance herpes simplex virus latency-associated transcripts visualized by non-isotopic in situ hybridization

During latent infection of neurons with herpes simplex virus type 1 (HSV-1), several RNA transcripts of varying abundance arise from a single locus within the virus repeats. The functions of latency-associated transcripts (LATs) are unknown and the relationship between the various RNA species requires further clarification. Reported here is a novel approach to the study of HSV transcripts during latency, based on the increasing realization that cellular and viral RNAs are synthesized and processed by macromolecular complexes that occupy discrete compartments within the nucleoplasm of a cell. High resolution non-isotopic in situ hybridization was used to study the intranuclear topology of HSV-1 LATs in primary sensory neurons of latently infected mice and humans. Low abundance (minor) LATs were localized to sharply defined intranuclear foci of 1 to 3 microns in diameter. On average, there were 2.6 to 2.8 foci/LAT+ neuronal profile (5 microns), representing 13 to 14 foci/cell. In contrast to the focal deployment of minor LATs, the more abundant latency-associated RNAs were distributed diffusely throughout the nucleoplasms of latency infected neurons, with prominent sparing of nucleolar regions. These data establish a foundation for studying the synthesis, processing and transport of LATs in vivo. It should now be possible to investigate the nature of those cellular products which associate with HSV-1 encoded LATs in vivo and thereby determine whether minor LATs are associated with previously characterized macromolecular complexes, such as those responsible for processing of pre-messenger RNA.

A quantitative technique for the study of the latency of Aujeszky virus

Latency represents a challenge for any herpesvirus vaccine. Vaccines could differ in their ability to minimize latency of pseudorabies virus (PRV). To study this possibility, a quantitative and differential PRV-specific polymerase chain reaction (PCR) was developed by the authors. Efficiency of amplification in different tubes is measured by co-amplification with the viral targets (either gI or gp50 genes) of the porcine gene nuclear factor 1. The criteria used to select this approach to a quantitative PCR, as well as for the selection of the standard, are discussed. The amplified products are measured by Southern blot or, alternatively, high performance liquid chromatography. Sensitivity and reproducibility of the technique are evaluated. The ability of this technique to discriminate between the level of latency established by two different PRV strains in trigeminal ganglia is also evaluated. Using this technique, the authors are currently studying whether different vaccines could possess differing levels of ability to minimize, by interference, establishment of wild-type latency.

Age distribution of latent herpes simplex virus 1 and varicella-zoster virus genome in human nervous tissue

Latency in nervous tissue caused by herpes simplex virus 1 (HSV-1) and by varicella-zoster virus (VZV) is an intriguing feature of herpes-virus' neurotropism. HSV-1 and VZV latency are the causes of ophthalmic zoster and recurrent HSV infections in the distributions of the trigeminal branches. HSV-1 neuronal latency may play a role in the etiopathogenesis of HSV encephalitis. We attempted to determine the prevalence and age distribution of VZV and HSV latency. We applied nested polymerase chain reaction (PCR) assays to detect HSV-1 and VZV genome in trigeminal ganglia and olfactory bulbs which were obtained from 109 human corpses at forensic postmortems. HSV-1 latency was found in 72.5% of trigeminal ganglia and in 15.5% of olfactory bulbs. VZV latency was 63.3% in trigeminal ganglia and 1% in olfactory bulbs. Simultaneous latency of VZV and HSV genome occurs in 48.8% of trigeminal ganglia. The age-group specific prevalence of HSV neuronal latency increases from 18.2% in 0-20 years to reach finally 100% in persons older than 60 years. Age specific prevalences of VZV peaked for a first time with 82% between 21-30 years, fell to 50% for 40-50 years, and rose to 89% for 71-80 years. If the latent trigeminal ganglion HSV-1 genome were the source of endogenously acquired encephalitis, the peak incidence of HSV encephalitis in older subjects correlates with our findings. Increased VZV latency prevalence in nervous tissue of younger people without subsequent disease indicates sufficient immune surveillance.

Neuropathology of herpes simplex virus encephalitis in a rat seizure model

Herpes simplex virus type 1 (HSV-1) is the cause of a serious and often fatal encephalitis. Patients who survive herpes simplex encephalitis (HSE) experience behavioral abnormalities including profound cognitive dysfunctions. We have developed a rat model of acute HSE to investigate the cognitive impairments caused by HSV-1 central nervous system (CNS) infection. Following intranasal inoculation of Lewis rats with a neurovirulent strain of HSV-1, animals shed virus in both ocular and nasal secretions and developed clinical signs of infection, including partial complex motor seizures that eventually generalized. Homogenization assays demonstrated infectious virus in the trigeminal ganglia, olfactory bulbs, and the piriform and entorhinal cortices. Histopathological assessment revealed inflammatory and hemorrhagic lesions in the trigeminal ganglia, olfactory bulbs, amygdala, hippocampus, the piriform and entorhinal cortices, and the spinal trigeminal nuclei. Viral antigens and nucleic acids were also detected within these structures by immunofluorescence microscopy and in situ hybridization, respectively. Viral-induced astrocytic hypertrophy in the CNS was demonstrated by glial fibrillary acidic protein immunoreactivity. Together, these results indicate that HSV-1 has the ability to invade, replicate, and induce site-specific CNS damage in the Lewis rat.

Quantitation of latent varicella-zoster virus DNA in human trigeminal ganglia by polymerase chain reaction

Competitive polymerase chain reaction was used to quantitate latent varicella-zoster virus (VZV) DNA in human trigeminal ganglia. Ganglionic DNA from five subjects was amplified with oligonucleotide primers specific for VZV gene 28. Two of the samples were also analyzed with primers specific for VZV gene 62. Our results indicated that there are 6 to 31 copies of the VZV genome in every 100,000 ganglionic cells.

Polymerase chain reaction for detection of herpesvirus simiae (B virus) in clinical specimens

A polymerase chain reaction (PCR) was designed which is specific to Macaca fascicularis (cynomolgus monkey) isolates of B virus. The PCR primers produced the expected 188 basepair product from the Cyno 2 strain and seven other cynomolgus monkey isolates of B virus. Oligomer hybridization with a 31-mer oligonucleotide was used to confirm the origin of this product. The PCR failed to amplify DNA of Epstein-Barr virus, cytomegalovirus, varicella-zoster virus, and other alphaherpesviruses (herpes simplex virus types 1 and 2, four SA 8 isolates and three rhesus isolates of B virus). PCR testing of swabs obtained from four orally-infected cynomolgus monkeys confirmed the presence of B virus DNA in samples previously shown to be positive by culture. In addition, PCR detected B virus in several swabs from infected monkeys that were culture negative. Total DNA extracts from the trigeminal and sacral ganglia of these animals were tested by nested PCR and B virus DNA was detected in the trigeminal ganglia of 3 of the 4 orally-infected cynomolgus monkeys. Nested PCR did not detect B virus DNA in total DNA extracts obtained from the brains of the four monkeys.

Induction of bilateral retinal necrosis in mice by unilateral intracameral inoculation of a glycoprotein-C deficient clinical isolate of herpes simplex virus type 1

Herpes simplex virus can cause acute retinal necrosis, a blinding retinal disease in man. A unilateral intracameral inoculation of herpes simplex virus type 1 (HSV-1) in mice induces retinal necrosis primarily in the contralateral eye and provides an experimental model for the disease. Previous studies suggested that a major envelope glycoprotein of HSV-1, glycoprotein C (gC), is required for retinal necrosis. We studied HSV-1 strain TN-1, a gC-deficient clinical isolated from a lesion of herpetic keratitis, for its pathogenicity in mice with an intracameral inoculation of the virus and found that TN-1 could induce severe necrotizing retinitis in both inoculated and uninoculated eyes of BALB/c mice. Inoculation with a lower dose of TN-1 resulted in a unilateral necrotizing retinitis in the uninoculated eyes. Tissue virus titration of infected mice killed at various times after inoculation detected an infectious virus in various organs including the eyeballs, trigeminal ganglia, brain and adrenal glands. Anterior chamber-associated immune deviation (ACAID) was observed in TN-1-inoculated mice as well as in mice inoculated with gC-positive laboratory strain KOS 7 days postinoculation. Our findings suggested that gC of HSV-1 is not necessary for either the induction of retinal necrosis, neural spread of the virus, or ACAID.

Varicella-zoster virus transcription in human trigeminal ganglia

Our laboratory previously reported in situ hybridization analyses showing varicella-zoster virus (VZV)-specific RNA transcripts in latently infected human trigeminal ganglia. These transcripts were found exclusively in non-neuronal cells and emanated from at least three separate regions of the VZV genome, those encompassing restriction fragments BamHI-EY, EcoRI-B, and BamHI-J. Extending these in situ studies, we now report that VZV RNAs colinear with open reading frames (ORFs) 29 and 62 are demonstrable in non-neuronal cells; however, neither VZV RNA colinear with ORF 28 nor antisense RNAs of ORFs 29 and 62 are detected. Northern hybridization analyses of poly(A)+ RNA from human trigeminal ganglion pools also reveal VZV-specific transcripts corresponding to ORFs 29 and 62, but not those of ORFs 28 or 61. The ORF 29- and 62-specific transcripts are similar to those expressed in productive infection, with regard to size and polyadenylation. The cumulative findings suggest that VZV latency is characterized by selected expression of multiple genes, which appear to include some but not all putative immediate-early and early genes.

Herpes simplex virus type 1 transcription is not detectable in quiescent human stromal keratitis by in situ hybridization

PURPOSE

The purpose of this study was to determine whether herpes simplex virus (HSV) transcripts are present in the corneas of patients with chronic herpetic stromal keratitis.

METHODS

Corneal buttons from patients with a history of stromal keratitis, but no ongoing active disease, together with positive and negative control tissues, were analyzed by in situ hybridization using single-stranded RNA probes for all three classes of viral lytic cycle transcripts as well as for the latency-associated transcripts (LATs). Tissues also were screened for presence of HSV genomic DNA using the polymerase chain reaction (PCR).

RESULTS

HSV DNA was detected in 7 of 13 quiescent corneas by PCR, but no viral transcripts were detected in any of these corneas by in situ hybridization.

CONCLUSIONS

At the level of detection afforded by in situ hybridization, HSV persistent in scarred human corneas after stromal keratitis appears to be transcriptionally dormant. This contrasts with the situation in neurons of latently infected sensory ganglia, in which LATs are present at high levels.

Immunohistochemical identification of trigeminal ganglion neurons that innervate the mouse cornea: relevance to intercellular spread of herpes simplex virus

Inoculation of the scarified cornea with herpes simplex virus (type 1) leads to herpetic infection of trigeminal ganglion cells. A recent study of the susceptibility of ganglion cells revealed that there may be at least four populations of trigeminal ganglion cells that are infectable by herpes. Two classes were identified by their neuropeptide content: Substance P or calcitonin gene-related peptide. One class was identified by its affinity for a monoclonal antibody, SSEA-3. The fourth class was recognized by its common affinity for both the monoclonal antibody LD2 and for the lectin Bandeiraea simplicifolia isolectin. However, there has been no direct evidence of which types are infected directly as a result of retrograde transport from the corneal site and which may be infected by cell-to-cell spread. The aim of this study was to determine which classes of neurons, which are known to become infected with HSV after ocular inoculation, supply corneal innervation. We have identified four classes of trigeminal ganglion neurons that supply axons to the central cornea of the mouse, on the basis of their ability to transport Fluoro-Gold retrograde from axons in the central corneal epithelium and stroma. About 40% of the neurons that innervate the cornea contain Substance P or calcitonin gene-related peptide; about 60% of the neurons that innervate the cornea react with the monoclonal antibody SSEA-3. About 36% of all neurons in the whole ophthalmic division react with the LD2 or Bandeiraea simplicifolia isolectin, and Fluoro-Gold labels only 2% of them.(ABSTRACT TRUNCATED AT 250 WORDS)

Herpes simplex virus type 1 mutant strain in1814 establishes a unique, slowly progressing infection in SCID mice

Ocular infection of immunocompetent (BALB/c) mice with wild-type herpes simplex virus type 1 (HSV-1) 17+ may lead to acute fatal encephalitis; however, in surviving animals, a latent (nonproductive) infection of the nervous system is established. In contrast, 17+ infection invariably kills mice with severe combined immunodeficiency (SCID mice) within 2 weeks. Ocular infection of immunocompetent mice with a mutant HSV-1 strain, in1814, which does not produce a functional alpha-transinducing protein, results in no detectable viral replication in the nervous system during the time corresponding to the acute phase of infection, no mortality, and the establishment of latency. In SCID mice, however, the in1814 virus establishes a unique, slowly progressing infection. In studying the courses of in1814 infection in SCID and BALB/c mice, we found that although intact B- and/or T-lymphocytic functions were required for the control of viral replication in the nervous system, some of the infected neurons of SCID mice seemed to be able to restrict in1814 replication and harbor the virus in a latent state.