Differential Involvement during Latent Herpes Simplex Virus 1 Infection of the Superior and Inferior Divisions of the Vestibular Ganglia: Implications for Vestibular Neuritis.

Controversy still surrounds both the etiology and pathophysiology of vestibular neuritis (VN). Especially uncertain is why the superior vestibular nerve (SVN) is more frequently affected than the inferior vestibular nerve (IVN), which is partially or totally spared. To address this question, we developed an improved method for preparing human vestibular ganglia (VG) and nerve. Subsequently, macro- and microanatomical as well as PCR studies were performed on 38 human ganglia from 38 individuals. The SVN was 2.4 mm longer than the IVN, and in 65% of the cases, the IVN ran in two separate bony canals, which was not the case for the SVN. Anastomoses between the facial and cochlear nerves were more common for the SVN (14/38 and 9/38, respectively) than for the IVN (7/38 and 2/38, respectively). Using reverse transcription-quantitative PCR (RT-qPCR), we found only a few latently herpes simplex virus 1 (HSV-1)-infected VG (18.4%). In cases of two separate neuronal fields, infected neurons were located in the superior part only. In summary, these PCR and micro- and macroanatomical studies provide possible explanations for the high frequency of SVN infection in vestibular neuritis.IMPORTANCE Vestibular neuritis is known to affect the superior part of the vestibular nerve more frequently than the inferior part. The reason for this clinical phenomenon remains unclear. Anatomical differences may play a role, or if latent HSV-1 infection is assumed, the etiology may be due to the different distribution of the infection. To shed further light on this subject, we conducted different macro- and microanatomical studies. We also assessed the presence of HSV-1 in VG and in different sections of the VG. Our findings add new information on the macro- and microanatomy of the VG as well as the pathophysiology of vestibular neuritis. We also show that latent HSV-1 infection of VG neurons is less frequent than previously reported.

Superior Versus Inferior Vestibular Neuritis: Are There Intrinsic Differences in Infection, Reactivation, or Production of Infectious Particles Between the Vestibular Ganglia?

HYPOTHESIS: Intrinsic differences in neurons of the vestibular ganglia result in the increased likelihood of superior vestibular ganglion involvement in vestibular neuritis. BACKGROUND: Vestibular neuritis is hypothesized to result from herpes simplex type I (HSV1) infection or reactivation in vestibular ganglia. Involvement of the inferior vestibular ganglion is extremely rare in patients with vestibular neuritis. METHODS: Primary cultures of rat superior and inferior vestibular ganglion neurons (VGNs) were cultivated separately. Neurons were lytically and latently infected with HSV1 with a US11-green fluorescent protein (GFP) chimera. Percentage lytic infection and baseline reactivation was assessed by microscopy for GFP fluorescence. Trichostatin-A (TSA) was used to stimulate HSV1 reactivation. Virion production was assessed by viral titers. Relative numbers of latency-associated (LAT) transcripts were determined by real-time reverse-transcription polymerase chain reaction (real-time RT-PCR). RESULTS: Lytic infection rates were equivalent between the two ganglia (p > 0.05). Lytic infections yielded similar amounts of plaque-forming units (p > 0.05). Relative amounts of LAT transcripts did not differ between latently infected superior and inferior VGNs. Latently infected cultures showed no differences in rates of baseline and TSA-induced HSV1 reactivation (p > 0.05). Production of virions was not significantly different between reactivated, latently infected superior versus inferior VGNs (p = 0.45). CONCLUSION: Differences in prevalence of superior and inferior vestibular neuritis do not result from intrinsic differences in HSV1 infection or virion production of these neurons. Other factors, such as the length and width of the bony canal containing the ganglia and nerves, account for the greater involvement of the superior vestibular ganglion in vestibular neuritis.

The role of cyclooxygenase in multiplication and reactivation of HSV-1 in vestibular ganglion neurons.

Reactivation of latent herpes simplex type 1 (HSV-1) and nerve inflammation have been shown to be involved in vertigo-related vestibular pathogenesis. Treatments of such diseases have been less than perfect. Nonsteroidal anti-inflammatory drugs (NSAIDs) have been reported to suppress reactivation of HSV-1 in trigeminal ganglions. However, whether this drug can affect reactivation of HSV-1 in vestibular ganglions is unclear. Due to the difficulties of constructing in vivo animal models, in this study, we developed a vestibular ganglion culture system, in which vestibular neurons were latently or lytically infected with HSV-1. Indomethacin and celecoxib were selected to measure their effects on HSV-1. Trichostatin A was used to reactivate HSV-1 in latently infected neurons. Cycloxygenase-2, which is the target of NSAIDs, was induced by HSV-1 in the lytically infected cultures, with an increase of 14-fold. Although it appeared that indomethacin and celecoxib showed limited but concentration-dependent inhibition effects on viral production under our condition, indomethacin decreased reactivation rate of HSV-1 by about 20%. Though more in vitro or in vivo studies are needed to confirm the effects of the drugs, our study may provide a potential way to investigate the mechanism of HSV-related vestibular pathogenesis as well as new treatments of vertigo-related diseases.

Cultured vestibular ganglion neurons demonstrate latent HSV1 reactivation.

OBJECTIVES/HYPOTHESIS: Vestibular neuritis is a common cause of both acute and chronic vestibular dysfunction. Multiple pathologies have been hypothesized to be the causative agent of vestibular neuritis; however, whether herpes simplex type I (HSV1) reactivation occurs within the vestibular ganglion has not been demonstrated previously by experimental evidence. We developed an in vitro system to study HSV1 infection of vestibular ganglion neurons (VGNs) using a cell culture model system. STUDY DESIGN: basic science study. RESULTS: Lytic infection of cultured rat VGNs was observed following low viral multiplicity of infection (MOI). Inclusion of acyclovir suppressed lytic replication and allowed latency to be established. Upon removal of acyclovir, latent infection was confirmed with reverse-transcription polymerase chain reaction and by RNA fluorescent in situ hybridization for the latency-associated transcript (LAT). A total of 29% cells in latently infected cultures were LAT positive. The lytic ICP27 transcript was not detected by reverse-transcription polymerase chain reaction (RT-PCR). Reactivation of HSV1 occurred at a high frequency in latently infected cultures following treatment with trichostatin A (TSA), a histone deactylase inhibitor. CONCLUSIONS: VGNs can be both lytically and latently infected with HSV1. Furthermore, latently infected VGNs can be induced to reactivate using TSA. This demonstrates that reactivation of latent HSV1 infection in the vestibular ganglion can occur in a cell culture model, and suggests that reactivation of HSV1 infection a plausible etiologic mechanism of vestibular neuritis.

Auditory and vestibular defects induced by experimental labyrinthitis following herpes simplex virus in mice.

CONCLUSION: Our herpes simplex virus (HSV) labyrinthitis mouse model suggests that HSV infection induces vestibular neuritis and sudden deafness. OBJECTIVE: Viral labyrinthitis has been postulated to play a role in vestibular neuritis and sudden deafness. We established a mouse model to investigate the pathogenesis of HSV-induced labyrinthitis. The relationship between HSV infection and apoptosis in the labyrinth was assessed. METHODS: HSV types 1 and 2 were inoculated into the middle ear of mice, and the function of the cochlear and vestibular nerves was assessed. Histopathological changes were examined with hematoxylin and eosin staining. Anti-HSV immunohistochemistry staining and TUNEL staining were done to investigate the relationship between HSV-infected cells and apoptotic cells. RESULTS: Hearing loss and vestibular dysfunction were observed in all mice after inoculation of HSV type 1 or 2. In the cochlear duct, columnar epithelial cells in the stria vascularis were infected with HSV, but only a portion of the infected cells underwent apoptosis. In contrast, many uninfected cells in the spiral organ of Corti were apoptotic. Vestibular dysfunction was observed when vestibular ganglion cells were largely infected, but not apoptotic. These findings recapitulate sudden deafness and vestibular neuritis described in patients.

Latency of herpes simplex virus type-1 in human geniculate and vestibular ganglia is associated with infiltration of CD8+ T cells.

Herpes simplex virus type-1 latency and CD8+ T-cell occurrence were investigated in the trigeminal, geniculate, and vestibular ganglia from seven deceased humans. The HSV-1 "latency-associated transcript" was assessed by in situ hybridization and quantitative RT-PCR. Infiltration of CD8+ T cell was detected by immunohistochemistry and quantitative RT-PCR. The data show that HSV-1 latency and CD8+ T-cell infiltration are not solely confined to the trigeminal ganglia but can also occur in other cranial ganglia along the neuroaxis. However, the HSV-1 latency transcripts in the geniculate and vestibular ganglia were expressed at a very low level. The difference in CD8 transcript levels among HSV-1 latently infected trigeminal ganglia, geniculate, and vestibular ganglia was less conspicuous. Colocalization of latent HSV-1 and CD8+ T cells in geniculate and vestibular ganglia supports further the hypothesis that HSV-1 reactivation is possible in these ganglia and is the cause of Bell's palsy and vestibular neuritis.

Evidence of feline herpesvirus-1 DNA in the vestibular ganglion of domestic cats.

In humans, herpes simplex virus type-1 has recently been detected in the vestibular ganglion (VG) and labyrinth (VL) and may be associated with vestibular signs. Feline herpesvirus-1 (FHV-1) is widespread amongst cat populations and affects many different tissues. The aim of this pilot study was to investigate the presence of FHV-1 DNA in the VG and VL of randomly selected domestic cats using PCR. FHV-1 DNA was detected in the VG of 14% of the cats. There was no detectable FHV-1 DNA in the VL of any cat. None of the infected cats had vestibular signs related to the VG infection.

Evidence for a viral neuropathy in recurrent vertigo.

The concept that reactivation of latent neurotropic viruses (i.e. Herpesviridae group) in the vestibular ganglion is responsible for recurrent vestibulopathies is presented. A similar histopathologic degeneration of vestibular ganglion cells in vestibular neuronitis (VN), Ménière's disease and benign paroxysmal positional vertigo is presented to support this concept. The clinical response (relief of vertigo) to the administration of antiviral medication in these syndromes provides practical evidence of a viral neuropathy in patients with recurrent vertigo. Relief of vertigo after this treatment was 90% in VN, Ménière's disease and VN. The relief of positional vertigo (benign paroxysmal positional vertigo) was 66%.

Herpes virus and Ménière's disease.

OBJECTIVE: The main goal of this study was to examine the vestibular ganglia from patients with intractable classic Ménière's disease (MD) for the presence or absence of DNA from three neurotropic viruses herpes simplex virus 1 and 2 (HSV1, HSV2) and varicella zoster virus (VZV) and to investigate the hypothesis that MD is associated with virus reactivation within Scarpa's ganglion. STUDY DESIGN: Polymerase chain reaction (PCR) was performed with nested primer sets specific for viral genomic DNA of HSV1, HSV2 and VZV in biopsies of the ganglion scarpae of patients with MD who underwent vestibular neurectomy. Included were patients with MD classified as definite MD according to American Academy of Otolaryngology/Head and Neck Surgery criteria. The ganglion scarpae and ganglion geniculi harvested at autopsy from patients without history of MD or facial palsy served as control specimens. RESULTS: No viral DNA was detected in the vestibular ganglion of 7 patients with definite MD. In 34% of the vestibular ganglia of the control group we detected either HSV1 or VZV. Only one Scarpa's ganglion had both viruses present at the same time. Thirty-two out of 34 ganglia from the geniculate segment of the facial nerve contained either HSV1 and/or VZV genomic DNA. Eight specimens contained both viruses simultaneously. Altogether viral DNA was found in 94% of ganglia. Viral genomic DNA of HSV2 was not detected. CONCLUSION: Although HSV and VZV appear to be present in many ganglion cells throughout the human body, we were unable to find genomic DNA of these viruses in patients with definite MD and disabling vertigo, who underwent vestibular neurectomy. Based on these results, reactivation of HSV1 and VZV in the vestibular ganglion does not seem to play a role in the pathogenesis of MD.

Do viruses cause inner ear disturbances?

The association of viral infection to inner ear disease is controversial. Experiments on animals show that several viruses are capable of causing hearing loss, if applied into the perilymph. Some of these have specific affinity to the cellular type of the inner ear, as sensory epithelia and cochlear nerve. Some viruses as adenoviruses and Coxsackie virus B have specific CAR receptors that are identified in different cell types, whereas other act by attaching onto nonspecific cellular surface receptors. Some viruses such as varicella zoster virus (VZV) do not cause disease in rodents. We assessed 273 patients with clinical, serological, neuro-otologic and endoscopic evaluations. Of the 273 patients, 43 served as control subjects. The patients either had Ménière's disease (n = 158), recurrent vertigo of unknown etiology (n = 56), or hearing loss (n = 17). Antibodies against neurotropic and common viruses were evaluated. VZV, influenza B, CBV5 and RSV titers were significantly elevated in patients with inner ear disease when compared with the control group. In analyzing the internal relationship, VZV and influenza B were intercorrelated. We did not find a correlation between hearing loss and viral titers. In conclusion, VZV, Coxsackie virus B5 and influenza B virus may be the main causes of inner ear disorder. The spiral and Scarpa's ganglion are potential sites harboring viral DNA for possible latent infection.

Bell's palsy and Herpes simplex virus: fact or mystery?

HYPOTHESIS AND BACKGROUND: In recent years, progress has been made in the understanding of Bell's palsy, the most common form of acute facial weakness. Herpes simplex virus (HSV) reactivation within the geniculate ganglion with subsequent inflammation and entrapment of the nerve at the meatal foramen has been proposed to be the pathogenetic mechanism. We challenged its accuracy by analyzing our own data on the presence of viral genomic DNA of HSV-1 and 2, human herpes virus (HHV)-6A/B, as well as varizella zoster virus (VZV) in patients with Bell's palsy and in control patients without the disease. METHODS: Polymerase chain reaction was performed with primer sets specific for viral genomic DNA of HSV-1, HSV-2, and VZV in facial muscle biopsy specimens from patients with Bell's palsy. As control specimens, the Scarpa's ganglion of patients with Meniere's disease and the geniculate ganglion harvested at autopsy from patients without history of facial palsy. In a second study, we used polymerase chain reaction with primers specific for HSV-1, -2, and HHV-6A, -6B to analyze for the presence of these viruses in tear fluid samples from control patients and patients with acute Bell's palsy. RESULTS: HSV-1 and VZV genomic DNA were detected in 86 and 43%, respectively, of geniculate ganglion preparations from control specimen. We were not able to detect the presence of HSV-1, HSV-2, or VZV genomic DNA in ganglion scarpae or muscle biopsy results in control and Bell's palsy patients. HHV-6A could be detected in tear fluid samples in 40% of control patients and 30% of Bell's palsy patients. CONCLUSIONS: The sole presence of HSV genomic DNA within the sensory ganglion along the facial nerve does not explain the direct association with Bell's palsy. The missing link would be the identification of an active replicating virus, an investigation that has not yet been carried out.

Herpes simplex virus and Meniere's disease.

OBJECTIVE/HYPOTHESIS: This study was designed to investigate the hypothesis that Meniere's disease is associated with herpes simplex virus (HSV) reactivation in the vestibular ganglion. STUDY DESIGN: Case control study. METHODS: Vestibular ganglia were obtained from archival surgical pathology specimens from patients undergoing vestibular neurectomy for vertigo caused by Meniere's disease. All patients met criteria for classification as definite Meniere's disease according to American Academy of Otolaryngology/Head and Neck Surgery (AAO-HNS) criteria. Control specimens were obtained from willed body donors. Sections from each ganglion were studied for prevalence of viral DNA using a nested polymerase chain reaction designed to amplify the HSV DNA polymerase gene. Quantitative analysis determined the number of viral copies per standard unit of ganglionic DNA. RESULTS: HSV DNA was more prevalent in paraffin embedded ganglia from patients with Meniere's disease (100%) than in fresh-frozen control ganglia (81%) (P =.02). Fixation and paraffin embedding substantially reduced recovery of HSV virus in selected control specimens. Quantitative analysis found no correlation between viral copy number in control ganglia processed frozen versus formalin fixed and paraffin embedded. CONCLUSIONS: HSV is more commonly isolated from vestibular ganglia of patients with Meniere's disease than the general population. The routine histologic preparation of formalin fixation and paraffin embedding significantly altered the quantity of virus detected though not in a predictable manner. The study provides supportive evidence for a viral etiology in Meniere's disease.

Prevalence of HSV-1 LAT in human trigeminal, geniculate, and vestibular ganglia and its implication for cranial nerve syndromes.

Herpes simplex virus type 1 (HSV-1) enters sensory neurons and can remain latent there until reactivation. During latency restricted HSV-1 gene expression takes place in the form of latency-associated transcripts (LAT). LAT has been demonstrated to be important not only for latency but also for reactivation, which may cause cranial nerve disorders. Tissue sections of the trigeminal ganglia (TG), geniculate ganglia (GG), and the vestibular ganglia (VG) from seven subjects were examined for the presence of LAT using the in situ hybridization technique. LAT was found on both sides in allTG (100%), on both sides of five subjects (70%) in the GG, and in none of the VG. Using a second more sensitive detection method (RT-PCR), we found LAT in the VG of seven of ten other persons (70%). This is the first study to demonstrate viral latency in the VG, a finding that supports the hypothesis that vestibular neuritis is caused by HSV-1 reactivation. The distribution of LAT in the cranial nerve ganglia indicates that primary infection occurs in the TG and GG and subsequently spreads along the faciovestibular anastomosis to the VG.

Herpes simplex virus in the vestibular ganglion and the geniculate ganglion-role of loose myelin.

This study presents the first direct evidence for herpes simplex virus type 1 (HSV-1) infection in the neurons of the vestibular ganglion. Although many investigators have reported electron microscopic evidence of HSV-1 infection in sensory ganglia, HSV-1 infection in the vestibular ganglion has not been described. Vestibular ganglion neurons have a unique structure, with a loose myelin sheath instead of the satellite cell sheath that is seen in other ganglia. This loose myelin is slightly different from compact myelin which is known as too tight for HSV-1 to penetrate. The role of loose myelin in terms of HSV-1 infection is completely unknown. Therefore, in an attempt to evaluate the role of loose myelin in HSV-1 infection, we looked for HSV-1 particles, or any effects mediated by HSV-1, in the vestibular ganglion as compared with the geniculate ganglion. At the light microscopic level, some neurons with vacuolar changes were observed, mainly in the distal portion of the vestibular ganglion where the communicating branch from the geniculate ganglion enters. At the electron microscopic level, vacuoles, dilated rough endoplasmic reticulum and Golgi vesicles occupied by virus were observed in both ganglia neurons. In contrast, viral infections in Schwann and satellite cells were observed only in the geniculate ganglion, but not in the vestibular ganglion. These results suggest that loose myelin is an important barrier to HSV-1 infection, and it must play an important role in the prevention of viral spread from infected neurons to other cells.

Distribution of herpes simplex virus type 1 in human geniculate and vestibular ganglia: implications for vestibular neuritis.

Vestibular neuritis is a common cause of partial unilateral vestibular paralysis, which usually spares posterior semicircular canal function. The cause is assumed to be a viral reactivation of latent herpes simplex virus type 1 (HSV-1) in human vestibular ganglia. The existence of an anastomosis between the intermediate nerve and the superior vestibular nerve suggests the question of whether selective affliction of the superior vestibular nerve is the result of migration of HSV-1 from the geniculate ganglion along this faciovestibular anastomosis. We determined the distribution of HSV-1 among geniculate ganglia, vestibular ganglia, and within Scarpa's ganglion by examining 35 human temporal bones by polymerase chain reaction. HSV-1 was found in 66% of geniculate ganglia and 60% of vestibular ganglia; all examined parts of vestibular ganglia were almost equally HSV-1 infected. Our data provided no support for viral migration along this anastomosis or for a preferential latency of HSV-1 in the superior vestibular nerve. We suggest that the common double innervation of the posterior ampulla by two nerves running in two separate bony canals could offer an alternative explanation for the regular sparing of posterior canal function in vestibular neuritis.

Highly variable distribution of HSV-1-specific DNA in human geniculate, vestibular and spiral ganglia.

Viral reactivation in temporal ganglia is the suspected cause of Bell's palsy, vestibular neuritis and sudden hearing loss. Since the distribution of latent herpes simplex type 1 (HSV-1) in geniculate, vestibular and spiral ganglia of individual human temporal bones could have implications for the explanation of isolated as well as combined disorders of these three cranial nerves, we examined these ganglia in 18 human temporal bones of adults by nested polymerase chain reaction. In all of the temporal bones HSV-1 specific DNA was detected: 10/18 (56%) of the geniculate, 11/18 (61%) of the vestibular and 9/18 (50%) of the spiral ganglia samples were positive. All combinations of positive and negative ganglia were found in individual temporal bones at roughly equal frequencies. These data support a viral etiology of all three conditions, especially their occasional combinations.

Detection of viral DNA in vestibular ganglia tissue from patients with Menière's disease.

OBJECTIVE: The main goal of this study was to examine the vestibular ganglia from 11 patients with intractable classic Menière's disease (MD) for the presence or absence of DNA from three neurotropic viruses (herpes simplex virus, cytomegalovirus, and varicella zoster virus) using exquisitely sensitive molecular biologic techniques. STUDY DESIGN: This was a prospective controlled study with vestibular ganglia from patients with MD and from patients with small vestibular schwannomas undergoing resection. Polymerase chain reaction was used for viral DNA detection from the ganglia along with known positive and negative polymerase chain reaction control subjects. SETTING: The study was performed in an academic tertiary referral center. PATIENTS: Patients for inclusion had medically uncontrolled MD, including documented fluctuating sensorineural hearing loss, episodic vertigo, and tinnitus who elected to undergo vestibular nerve section. Control patients were undergoing vestibular schwannoma removal. INTERVENTIONS: The intervention was vestibular nerve section with removal of vestibular ganglion. MAIN OUTCOME MEASURES: The presence or absence of viral DNA (herpes simplex virus, cytomegalovirus, and varicella zoster virus) in vestibular ganglion tissues detected by polymerase chain reaction. RESULTS: No viral DNA was detected in the vestibular ganglia of patients with MD (p = 0.028) nor in the control group. The likelihood of a type II or beta type error was < 10%. CONCLUSIONS: In patients with MD requiring surgical intervention, infection with herpes simplex virus, cytomegalovirus, or varicella zoster virus of the vestibular ganglia does not appear to play a major role in the pathoetiology of the disease.

Molecular temporal bone pathology: II. Ramsay Hunt syndrome (herpes zoster oticus).

In 1907 J. Ramsay Hunt suggested that herpes zoster oticus resulted from a geniculate ganglionitis; however, many contemporary authors believe that this disorder represents a neuritis or polycranial neuropathy. Herpes varicella-zoster viral (VZV) DNA was identified, using the polymerase chain reaction, in archival celloidin-embedded temporal bone sections from two patients who clinically had Ramsay Hunt syndrome (herpes zoster oticus). The presence of VZV was confirmed by sequencing the PCR products. These experiments demonstrated that VZV genomic DNA was present in the geniculate ganglion of the side with facial paralysis and cutaneous recrudescence in both patients and in the clinically unaffected side in patient 1. In addition, patient 2 had a sudden hearing loss and was found to have VZV genomic DNA in sections from the affected side containing the spiral ganglion, Scarpa's ganglion, organ of Corti, and macula of the saccule. No VZV genomic DNA was identified in temporal bone sections from five patients with Bell's palsy and ten patients without evidence of otologic disease. In this study, the histopathology of these two cases yielded complementary information regarding the role of VZV in herpes zoster oticus. These data suggest that in patients with Ramsay Hunt syndrome, latent VZV is located in the geniculate ganglia and may be present in the auditory and vestibular primary afferent ganglia in some patients.

[Detection of latent herpes simplex virus in human vestibular ganglia].

Viral infections are considered to be one of the possible etiologies of vestibular neuronitis. Herpes simplex virus type 1 (HSV-1) is a likely candidate agent as this virus has a strong neurotropism, and can establish latent infections in the nervous system. However the existence of infections in the vestibular ganglia has not been established. In this study, 31 vestibular ganglia from autopsied adults were investigated. Polymerase chain reaction (PCR) was used to detect HSV-1 viral genomes, and reverse transcription-PCR (RT-PCR) and in situ hybridization (ISH) methods were employed to demonstrate latency associated transcripts (LAT) of HSV-1, which has been known to be latency specific. HSV-1 DNA was detected in 6 of 10 (60%) vestibular ganglia using the PCR method, and HSV-1 LAT was detected in 5 of 8 (63%) vestibular ganglia using the RT-PCR method. However, ISH showed that only 1 of 13 (7.7%) vestibular ganglia was HSV-1 LAT positive. In total only 1 of 3,830 (0.03%) neurons from 13 vestibular ganglia was found to be positive. The results indicate with certainty that HSV-1 does produce latent infections in human vestibular ganglia, and that the percentage of HSV-1 infected neurons is less than that of trigeminal ganglia. The results of this study also suggest that the rare presence of HSV-1 LAT in the ganglia may possibly correspond to the less frequent occurrence of vestibular neuronitis resulting from reactivation of HSV-1.