Embryonic and Neonatal Mouse Cochleae Are Susceptible to Zika Virus Infection.

Congenital Zika Syndrome (CZS) is caused by vertical transmission of Zika virus (ZIKV) to the gestating human fetus. A subset of CZS microcephalic infants present with reduced otoacoustic emissions; this test screens for hearing loss originating in the cochlea. This observation leads to the question of whether mammalian cochlear tissues are susceptible to infection by ZIKV during development. To address this question using a mouse model, the sensory cochlea was explanted at proliferative, newly post-mitotic or maturing stages. ZIKV was added for the first 24 h and organs cultured for up to 6 days to allow for cell differentiation. Results showed that ZIKV can robustly infect proliferating sensory progenitors, as well as post-mitotic hair cells and supporting cells. Virus neutralization using ZIKV-117 antibody blocked cochlear infection. AXL is a cell surface molecule known to enhance the attachment of flavivirus to host cells. While Axl mRNA is widely expressed in embryonic cochlear tissues susceptible to ZIKV infection, it is selectively downregulated in the post-mitotic sensory organ by E15.5, even though these cells remain infectible. These findings may offer insights into which target cells could potentially contribute to hearing loss resulting from fetal exposure to ZIKV in humans.

Self-complementarity in adeno-associated virus enhances transduction and gene expression in mouse cochlear tissues.

Sensorineural hearing loss is one of the most common disabilities worldwide. Such prevalence necessitates effective tools for studying the molecular workings of cochlear cells. One prominent and effective vector for expressing genes of interest in research models is adeno-associated virus (AAV). However, AAV efficacy in transducing cochlear cells can vary for a number of reasons including serotype, species, and methodology, and oftentimes requires high multiplicity of infection which can damage the sensory cells. Reports in other systems suggest multiple approaches can be used to enhance AAV transduction including self-complementary vector design and pharmacological inhibition of degradation. Here we produced AAV to drive green fluorescent protein (GFP) expression in explanted neonatal mouse cochleae. Treatment with eeyarestatin I, tyrphostin 23, or lipofectamine 2000 did not result in increased transduction, however, self-complementary vector design resulted in significantly more GFP positive cells when compared to single-stranded controls. Similarly, self-complementary AAV2 vectors demonstrated enhanced transduction efficiency compared to single stranded AAV2 when injected via the posterior semicircular canal, in vivo. Self-complementary vectors for AAV1, 8, and 9 serotypes also demonstrated robust GFP transduction in cochlear cells in vivo, though these were not directly compared to single stranded vectors. These findings suggest that second-strand synthesis may be a rate limiting step in AAV transduction of cochlear tissues and that self-complementary AAV can be used to effectively target large numbers of cochlear cells in vitro and in vivo.

[The study of AAV9 expression in cochleae of mice at different ages].

Objective: To determine the extent of transfection and expression of adeno-associated virus (AAV) serotype 9 (AAV9) in the cochleae of mice at different ages. Methods: AAV9-green fluorescent protein (GFP) was inoculated into the cochlea of mice via the round window membrane (RWM) or through cochleostomy at different ages. Four groups were divided according to ages and injection sites: P1SM group, AAV9-GFP was delivered to the scala media by cochleostomy at postnatal day 1; P1RW group, AAV9-GFP was delivered to the scala tympani via RWM at postnatal day 1; P9RW group: AAV9-GFP was injected through RWM at postnatal day 9; and P30RW group, adult mice (P30) were injected through RWM. GFP expression in cochlear whole mount was analyzed and auditory brainstem response (ABR) tests were conducted one month after virus injection (for each animal, only left cochlea was injected and the right side was used as a control). GraphPad Prism 5 statistical software was used for data analysis. Results: All of inner hair cells (IHCs) and most of outer hair cells (OHCs) were transfected via two approaches at P1 injection. There was no significant difference in ABR threshold between injected ears and untreated ears (P>0.05). All of the IHCs and parts of OHCs (69% in apical turn) were transfected via RWM at P9. The strongest GFP expression was observed near the apical turn. Cochlear inoculation via RWM at P30 led to transgene expression in only IHCs. The ABR threshold of injected ears in P9RW group and P30RW group was significantly higher than that of contralateral ears (P<0.01). Conclusions: AAV9 can be highly expressed in the inner and outer hair cells of the cochlea and hearing sensitivity can be preserved if virus injections are performed in neonatal mice. After AAV9 is transfected into the inner ear of adult mice, it is only expressed in the inner hair cells, which leads to the increase of the ABR response threshold of mice. Transfection efficiency is significant higher in neonate mice than in P9 and adult mice.

Virus-induced cochlear inflammation in newborn mice alters auditory function.

Although human cytomegalovirus (HCMV) is a known cause of sensorineural hearing loss in infants with congenital HCMV (cCMV) infections, mechanisms that contribute to sensorineural hearing loss (SNHL) in infants with cCMV infection are not well defined. Using a murine model of CMV infection during auditory development, we have shown that peripheral infection of newborn mice with murine CMV (MCMV) results in focal infection of the cochlea and virus-induced cochlear inflammation. Approximately 50%-60% of infected mice exhibited increased auditory brainstem response (ABR) thresholds across a range of sound frequencies. Histological analyses of the cochlea in MCMV-infected mice with elevated ABR thresholds revealed preservation of hair cell (HC) number and morphology in the organ of Corti. In contrast, the number of spiral ganglion neurons (SGN), synapses, and neurites connecting the cochlear HC and SGN nerve terminals were decreased. Decreasing cochlear inflammation by corticosteroid treatment of MCMV-infected mice resulted in preservation of SGN and improved auditory function. These findings show that virus-induced cochlear inflammation during early auditory development, rather than direct virus-mediated damage, could contribute to histopathology in the cochlea and altered auditory function without significant loss of HCs in the sensory epithelium.

A synthetic AAV vector enables safe and efficient gene transfer to the mammalian inner ear.

Efforts to develop gene therapies for hearing loss have been hampered by the lack of safe, efficient, and clinically relevant delivery modalities. Here we demonstrate the safety and efficiency of Anc80L65, a rationally designed synthetic vector, for transgene delivery to the mouse cochlea. Ex vivo transduction of mouse organotypic explants identified Anc80L65 from a set of other adeno-associated virus (AAV) vectors as a potent vector for the cochlear cell targets. Round window membrane injection resulted in highly efficient transduction of inner and outer hair cells in mice, a substantial improvement over conventional AAV vectors. Anc80L65 round window injection was well tolerated, as indicated by sensory cell function, hearing and vestibular function, and immunologic parameters. The ability of Anc80L65 to target outer hair cells at high rates, a requirement for restoration of complex auditory function, may enable future gene therapies for hearing and balance disorders.

Partial corrosion casting to assess cochlear vasculature in mouse models of presbycusis and CMV infection.

Some forms of sensorineural hearing loss involve damage or degenerative changes to the stria vascularis and/or other vascular structures in the cochlea. In animal models, many methods for anatomical assessment of cochlear vasculature exist, each with advantages and limitations. One methodology, corrosion casting, has proved useful in some species, however in the mouse model this technique is difficult to achieve because digestion of non vascular tissue results in collapse of the delicate cast specimen. We have developed a partial corrosion cast method that allows visualization of vasculature along much of the cochlear length but maintains some structural integrity of the specimen. We provide a detailed step-by-step description of this novel technique. We give some illustrative examples of the use of the method in mouse models of presbycusis and cytomegalovirus (CMV) infection.

The spread of adenoviral vectors to central nervous system through pathway of cochlea in mimetic aging and young rats.

There is no definitive conclusion concerning the spread of viral vectors to the brain after a cochlear inoculation. In addition, some studies have reported different distribution profiles of viral vectors in the central auditory system after a cochlear inoculation. Thus, rats were grouped into either a mimetic aging group or a young group and transfected with adenoviral vectors (AdVs) by round window membrane injection. The distribution of AdV in central nervous system (CNS) was demonstrated in the two groups with transmission electron microscopy and immunofluorescence. We found that the AdV could disseminate into the CNS and that the neuronal damage and stress-induced GRP78 expression were reduced after transfection with PGC-1α, as compared with the control vectors, especially in the mimetic aging group. We also found that the host immune response was degraded in CNS in the mimetic aging group after transduction through the cochlea, as compared with the young group. These results demonstrate that viral vectors can disseminate into the CNS through the cochlea. Moreover, mimetic aging induced by D-galactose could facilitate the spread of viral vectors into the CNS from the cochlea. These findings may indicate a new potential approach for gene therapy against age-related diseases in the CNS.

Restricted infection of murine cytomegalovirus (MCMV) in neonatal mice with MCMV-induced sensorineural hearing loss.

BACKGROUND: Congenital infection with human Cytomegalovirus (HCMV) is known to be a causative agent of sensorineural hearing loss (SNHL). OBJECTIVES: To clarify the nongenetic etiology of SNHL by identifying the Cytomegalovirus (CMV)-infected region in the cochleae. STUDY DESIGN: We established an animal model of SNHL by injecting neonatal Balb/c mice with intracerebral murine Cytomegalovirus (MCMV) within 24h after delivery. RESULTS: At 3 weeks of age, unilateral and bilateral SNHL were observed in 24% (5/21) and 29% (6/21) of the mice, respectively. SNHL thereafter progressed, with 79% of mice developing bilateral SNHL by 6 weeks of age. MCMV antigens and DNA were detected in the spiral ganglion, and cells surrounding the meninges and scala tympani at 1 week of age. However, both MCMV antigens and DNA had completely disappeared by 2 weeks of age. It is possible that the MCMV reached the spiral ganglion via cerebrospinal fluid as the result of meningitis, as the stria vascularis was found to be MCMV antigen negative. Myosin VI expression in the outer hair cells was lost at 3 weeks of age. MCMV and myosin VI expression disappeared before and during SNHL progression, respectively. CONCLUSIONS: There was a definite lag time between the period in which MCMV antigens/DNA-positive cells were observed and that in which SNHL developed and myosin VI-negative hair cells were observed. Further study is needed to explore the role of MCMV in the loss of myosin VI expression in the outer hair cells.

Inner ear lesions in congenital cytomegalovirus infection of human fetuses.

Congenital cytomegalovirus (CMV) infection is the leading cause of non-hereditary congenital sensorineural hearing loss (SNHL). The natural course and the pathophysiology of inner ear lesions during human fetal CMV infection have not yet been reported. Inner ear lesions were investigated in six CMV-infected fetuses aged 19-35 postconceptional weeks and correlated with central nervous system (CNS) lesions. All the fetuses had high viral loads in the amniotic fluid and severe visceral and CNS lesions visible by ultrasound. Diffuse lesions consisting of both cytomegalic cells containing inclusion bodies and inflammation were found within all studied structures including the inner ear, brain, other organs, and placenta, suggesting hematogenous dissemination. Cochlear infection was consistently present and predominated in the stria vascularis (5/6), whereas the supporting cells in the organ of Corti were less often involved (2/6). Vestibular infection, found in 4/6 cases, was florid; the non-sensory epithelia, including the dark cells, were extensively infected. The endolymphatic sac was infected in 1 of 3 cases. The severity of inner ear infection was correlated with the CNS lesions, confirming the neurotropism of CMV. This study documenting infection of the structures involved in endolymph secretion and potassium homeostasis in fetuses with high amniotic fluid viral loads suggests that potassium dysregulation in the endolymphatic compartment of the inner ear may lead to secondary degeneration of the sensory structures. In addition, the occurrence of SNHL depends on the intensity and duration of the viral infection and inflammation.

Cytomegalovirus-induced sensorineural hearing loss with persistent cochlear inflammation in neonatal mice.

Congenital cytomegalovirus (CMV) infection is the leading cause of sensorineural hearing loss (SNHL) in children. During murine (M)CMV-induced encephalitis, the immune response is important for both the control of viral dissemination and the clearance of virus from the brain. While the importance of CMV-induced SNHL has been described, the mechanisms surrounding its pathogenesis and the role of inflammatory responses remain unclear. This study presents a neonatal mouse model of profound SNHL in which MCMV preferentially infected both cochlear perilymphatic epithelial cells and spiral ganglion neurons. Interestingly, MCMV infection induced cochlear hair cell death by 21 days post-infection, despite a clear lack of direct infection of hair cells and the complete clearance of the virus from the cochlea by 14 dpi. Flow cytometric, immunohistochemical, and quantitative PCR analysis of MCMV-infected cochlea revealed a robust and chronic inflammatory response, including a prolonged increase in reactive oxygen species production by infiltrating macrophages. These data support a pivotal role for inflammation during MCMV-induced SNHL.

Guinea pig adenovirus infection does not inhibit cochlear transfection with human adenoviral vectors in a model of hearing loss.

Routine surveillance of guinea pigs maintained within a barrier facility detected guinea pig adenovirus (GPAdV) in sentinel animals. These guinea pigs served as models of induced hearing loss followed by regeneration of cochlear sensory (hair) cells through transdifferentiation of nonsensory cells by using human adenoviral (hAV) gene therapy. To determine whether natural GPAdV infection affected the ability of hAV vectors to transfect inner ear cells, adult male pigmented guinea pigs (n = 7) were enrolled in this study because of their prolonged exposure to GPAdV-seropositive conspecifics. Animals were deafened chemically (n = 2), received an hAV vector carrying the gene for green fluorescent protein (hAV-GFP) surgically without prior deafening (n = 2), or were deafened chemically with subsequent surgical inoculation of hAV-GFP (n = 3). Cochleae were evaluated by using fluorescence microscopy, and GFP expression in supporting cells indicated that the hAV-GFP vector was able to transfect inner ears in GPAdV-seropositive guinea pigs that had been chemically deafened. Animals had histologic evidence of interstitial pneumonia, attributable to prior infection with GPAdV. These findings confirmed that the described guinea pigs were less robust animal models with diminished utility for the overall studies. Serology tests confirmed that 5 of 7 animals (71%) were positive for antibodies against GPAdV at necropsy, approximately 7 mo after initial detection of sentinel infection. Control animals (n = 5) were confirmed to be seronegative for GPAdV with clinically normal pulmonary tissue. This study is the first to demonstrate that natural GPAdV infection does not negatively affect transfection with hAV vectors into guinea pig inner ear cells, despite the presence of other health complications attributed to the viral infection.

Efficient transduction of spiral ganglion cells using adenovirus type 5 vector in the rat.

CONCLUSIONS: The adenovirus-5 vector specifically transduced spiral ganglion cells with high efficiency, suggesting that it is a potential gene therapeutic tool for the survival of spiral ganglion cells with secondary injury. OBJECTIVES: This study aimed to find a suitable viral vector allowing efficient transduction to spiral ganglion cells. METHODS: Lentivirus, adeno-associated virus-2 and adenovirus-5 constructs habouring green fluorescence protein (GFP) gene were injected into scala tympani via the round window membrane of rat. Distribution and fluorescence intensity of GFP within the cochlea were estimated using a fluorescence microscope. RESULTS: The GFP expressions mediated by all three viral vectors were observed in multiple cell types of the cochlea. Compared with the other two viral vectors, the adenovirus-5 vector efficiently transduced cochlear spiral ganglion cells in vivo and was still present 2 weeks after viral vector injection.

[Distributions of cells infected by AD5-EGFP infused in different ways in guinea pig's cochlear].

OBJECTIVE: To explore the distribution of cells infected by AD5-EGFP infused in different ways in the cochlea of guinea pig. METHOD: AD5-EGFP was infused into the endolymphatic system through a hole on the lateral wall of the scala media or into the extralymphatic system through the round window membrane respectively. The infected cochlear cells confirmed by expression of EGFP were examined on the whole mount or cryostat sections. RESULT: In the cochleae in which AD5-EGFP was infused into the extralymphatic system through the round window membrane, expression of EFGP could be found in the type I, IV and V fibrocyte of the stria vascularis, superlimbal cells of the spiral lip, cells in Ressenal membrane, spiral ganglion neurons in Rosenthal hole and cells lining the inner wall of scala vestibular and scala tympani, indicating that these cells were infected by adenovirus. None of the inner, outer hair or supporting cells was found to be infected in these cochleae. In the cochleae in which AD5-EGFP was infused into the endolymphatic system through a hole on the lateral wall of scala media, expression of EFGP could be found in supporting cells in the organ of Corti and lining cells of the scala media. CONCLUSION: Adenovirus5 is a good and effective vector for delivering genes into cells in guinea pig's cochlea. The scope of infected cells will be very different when the vector is applied to the cochlea through different infusion ways. No cells in the endolymphatic system would be infected if the vector is infused into the extralymphatic system.

Multiple viral genome search in endolabyrinthic fluids of profoundly deaf patients: possible cytomegalovirus intracochlear reactivation.

BACKGROUND: The cause of about 30% of bilateral sensorineural hearing loss (SNHL) is still unknown. A viral etiology is among the most frequently proposed ones and the supposed diagnosis is only based upon few clinical and laboratory data. The detection of viral presence within a damaged compartment may represent a way to supply interesting data for confirmation of viral etiology and to explain pathogenic mechanisms. OBJECTIVES: The aim of our study was to identify the possible presence of pathogenic viruses in the inner ear extracellular compartment in patients with bilateral severe sensorineural deafness of unknown etiology who underwent cochlear implant surgery. METHODS: 4 patients, aged from 2 to 7 years and affected by SNHL underwent cochlear implantation surgery and, at the same time, endolabyrinthine fluid sampling. The samples were subsequently sent for viral nucleic acid extraction and polymerase chain reaction (PCR) treatment: multiplex PCR and realtime-PCR were used. In each endolabyrinthine fluid sample, cytomegalovirus (CMV), Epstein-Barr virus (EBV), varicella-zoster virus (VZV), herpes simplex virus type 1 and 2 (HSV-1, HSV-2) and enterovirus genomes were searched for. RESULTS: One patient was positive for intracochlear CMV, as confirmed by another base-pair segment PCR. EBV, VZV, HSV and enterovirus were detected in none of the 4 patients. CONCLUSIONS: Our finding of CMV genome within the cochlea of a deaf patient without any evidence of acute and prenatal CMV infection suggests its possible role in postnatal inner ear injury through reactivation of latent virus within the cochlea. This hypothesis could also be considered valid for some patients with anti-CMV-IgG-positive serology and absence of endolabyrinthine viral genome since viruses can be in an inactive state at the time of fluid collection. PCR has proved to be a very useful tool in order to investigate infectious causes of deafness even for more than one virus type at a time and in a limited quantity of sample, such as the small volume of endolabyrinthine liquid collected from children during cochlear implant surgery.

Efficient and specific transduction of cochlear supporting cells by adeno-associated virus serotype 5.

Congenital deafness, affecting 1 in 1000 neonates, can lead to major problems in speech, cognitive and psychosocial development. Congenital deafness is mainly caused by mutations in connexins, hemi-channel proteins forming gap-junctions between supporting cells in the sensory epithelia. We describe a high tropism of AAV5 serotype for the supporting cells of the cochlea, both in vitro in postnatal day 4 mouse explants, and in vivo in the adult guinea-pig inner ear, through scala media perfusion. AAV5 transduction correlates with PDGFRalpha expression, previously reported as AAV5 receptor. This vector could be of major interest in addressing gene therapy approaches to deafness as well as for studying basic aspects of inner-ear development and hearing mechanisms.

Noninvasive in vivo delivery of transgene via adeno-associated virus into supporting cells of the neonatal mouse cochlea.

There are a number of genetic diseases that affect the cochlea early in life, which require normal gene transfer in the early developmental stage to prevent deafness. The delivery of adenovirus (AdV) and adeno-associated virus (AAV) was investigated to elucidate the efficiency and cellular specificity of transgene expression in the neonatal mouse cochlea. The extent of AdV transfection is comparable to that obtained with adult mice. AAV-directed gene transfer after injection into the scala media through a cochleostomy showed transgene expression in the supporting cells, inner hair cells (IHCs), and lateral wall with resulting hearing loss. On the other hand, gene expression was observed in Deiters cells, IHCs, and lateral wall without hearing loss after the application of AAV into the scala tympani through the round window. These findings indicate that injection of AAV into the scala tympani of the neonatal mouse cochlea therefore has the potential to efficiently and noninvasively introduce transgenes to the cochlear supporting cells, and this modality is thus considered to be a promising strategy to prevent hereditary prelingual deafness.

The role of CMV inflammatory genes in hearing loss.

HYPOTHESIS: The purpose of this study is to test the hypothesis that virally encoded immunomodulatory genes play a role in cytomegalovirus (CMV)-related hearing loss. OBJECTIVE: Cytomegalovirus is the leading cause of infectious-related congenital sensorineural hearing loss worldwide. Unfortunately, little is known about the pathophysiology of CMV-related injury to the developing ear. METHODS: Viral mutagenesis techniques were developed that allow the deletion of a specific viral immunomodulatory gene, macrophage inflammatory protein (MIP) 1alpha homolog. We assessed the extent to which this gene product contributed to auditory pathologic findings in the guinea pig (GP) model. Eighteen weanling GPs (250-350 g) were used under an Institutional Animal Control and Use Committee-approved protocol. We analyzed preinoculation hearing using auditory brainstem response recordings. Intracochlear inoculations were performed on one group of six GPs with sterile viral media, 6 GPs with wild-type (WT) CMV virus, and 6 GPs with mutant "knockout" (KO) virus (with deleted MIP-1alpha homolog). Auditory brainstem responses were then obtained on postinoculation Days 7, 14, 21, and 28. RESULTS: There was a significant difference in hearing between the KO group and the WT group, with significantly better hearing in the KO group. A comparison of the KO group to the sham group revealed no significant hearing differences between the groups. The WT group had significant threshold shifts by dose at all frequencies meeting our criteria of hearing loss (>30 dB). There were no statistical differences in the sham or KO group. CONCLUSION: Virally encoded immunomodulatory genes such as MIP-1alpha seem to play a significant role in CMV-related hearing loss. This study is the first demonstration of the role of specific viral immune modulation genes in the in vivo pathogenesis of CMV-induced hearing loss in a relevant animal model.

Coxsackie adenovirus receptor and alpha nu beta3/alpha nu beta5 integrins in adenovirus gene transfer of rat cochlea.

This study was designed to determine whether Coxsackie adenovirus receptor (CAR) and alpha nu beta3/alpha nu beta5 integrin co-receptors are involved in adenovirus gene transfer in the rat cochlea. We find that CAR and integrin co-receptors are expressed in every cell subtype transduced by the adenoviral vector Ad5 DeltaE1-E3/cytomegalovirus/green fluorescent protein (GFP) on cochlear slices in vitro. The spiral ganglion neurons, which do not express CAR, were not transduced by the virus. Blocking these receptors by monoclonal antibodies decreased transgene expression, whereas disrupting tight junctions with ethylenediaminetetraacetic acid led to an increased transgene expression. However, sensory hair cells and strial cells also expressing CAR and alpha nu integrins were not transduced by the vector. GFP expression was also studied in vivo. Perilymphatic perfusion of adenovirus in vivo did not affect hearing and only cells lining the perilymphatic spaces were transduced. Endolymphatic perfusion resulted in low-frequency hearing loss and although some cells of the organ of Corti were efficiently transduced, the sensory and the strial cells were not. Transduced sensory and strial cells were occasionally observed in cochleas after single shot of adenovirus. Pretreatment with anti-CAR and anti-alpha nu antibodies decreases GFP expression in vivo, suggesting that the CAR/alpha nu integrin pathway is involved in adenovirus transduction in the cochlea.

[Varicella-zoster infection with isolated cochleovestibular affectation (without facial palsy)]. / Infección por herpes zoster con afectación cocleovestibular aislada (sin parálisis facial).

Otological complications of Ramsay Hunt syndrome include facial paralysis, tinnitus, hearing loss, vertigo, dysgeusia, and skin eruption. The lower cranial nerves sometimes are affected by this neuritis. A case is reported of a man without immune-system impairment who had a cranial mononeuritis with unilateral involment of the VIII and VII cranial nerves after infection with varicella-zoster without herpetic lesions.

Infección por herpes zoster con afectación cocleovestibular aislada (sin parálisis facial) / Varicella-Zoster infection with isolated cochleovestibular affectation (without facial palsy)

El virus varicela zoster puede causar complicaciones otológicas (síndrome de Ramsay Hunt) que incluyen parálisis facial, hipoacusia, vértigo, disgeusia y erupción vesicular cutánea. En ocasiones esta neuritis puede afectar a los pares bajos y cursar sin erupción. Se presenta el caso de un paciente inmunocompetente con afectación del nervio vestíbulo- coclear y de la rama cutánea del nervio facial, sin involucrar las ramas motoras

Otological complications of Ramsay Hunt syndrome include facial paralysis, tinnitus, hearing loss, vertigo, dysgeusia, and skin eruption. The lower cranial nerves sometimes are affected by this neuritis. A case is reported of a man without immune-system impairment who had a cranial mononeuritis with unilateral involment of the VIII and VII cranial nerves after infection with varicella-zoster without herpetic lesions