Abstract
To protect the audiosensory organ from tissue damage from the immune system, the inner ear is separated from the circulating immune system by the blood-labyrinth barrier, which was previously considered an immune-privileged site. Recent studies have shown that macrophages are distributed in the cochlea, especially in the spiral ligament, spiral ganglion, and stria vascularis; however, the direct pathogen defence mechanism used by audiosensory receptor hair cells (HCs) has remained obscure. Here, we show that HCs are protected from pathogens by surrounding accessory supporting cells (SCs) and greater epithelial ridge (GER or Kölliker’s organ) cells (GERCs). In isolated murine cochlear sensory epithelium, we established Theiler’s murine encephalomyelitis virus, which infected the SCs and GERCs, but very few HCs. The virus-infected SCs produced interferon (IFN)-α/β, and the viruses efficiently infected the HCs in the IFN-α/β receptor-null sensory epithelium. Interestingly, the virus-infected SCs and GERCs expressed macrophage marker proteins and were eliminated from the cell layer by cell detachment. Moreover, lipopolysaccharide induced phagocytosis of the SCs without cell detachment, and the SCs phagocytosed the bacteria. These results reveal that SCs function as macrophage-like cells, protect adjacent HCs from pathogens, and provide a novel anti-infection inner ear immune system.
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Introduction
The inner ear was previously regarded as an immune-privileged site because the blood-labyrinthine barrier prevents the peripheral immune system accessing this site1. To minimize any collateral tissue damage induced by an immune reaction, delicate tissues, such as those of the central nervous system (CNS), sensory organs (eyes and ears) and gonads (testes and ovaries), are separated from the peripheral blood by a physical barrier2. In the mammalian inner ear, audiosensory receptor hair cells (HCs) are located over the basilar membrane in the organ of Corti, which vibrates in response to sound waves3. This sensory organ lies in the cochlear duct (known as the scala media) and is separated from the vestibular duct and the tympanic duct by the avascular Reissner’s membrane and a basilar membrane, respectively4. To offset the constant auditory sensation of heartbeats, the direct blood supply to the organ of Corti is sparse. The oxygen supply to HCs is provided by the dense capillary network of the stria vascularis, which is present in the lateral wall of the cochlear duct, constitutes the major feeding vessels1,5.
HCs transduce the mechanical force generated by sound waves into electrical signals6 and are aligned in four rows, one of which, the inner HCs (IHCs) detect sound, while the other three rows of outer HCs (OHCs) have amplitude and frequency-resolving capabilities3,6. OHCs are surrounded by supporting cells (SCs), termed Hensen’s cells and Claudius’ cells3. IHCs are surrounded by greater epithelial ridge (GER or Kölliker’s organ) cells (GERCs) in the immature neonatal inner ear, which develop later on into mature SCs and are important for HC development7,8. SCs are linked to each other and to HCs via tight and adherent junctions; they form rigid cytoskeletons and maintain the structural integrity of the audiosensory organs during sound stimulation and head movement6. Although SCs have several functions in the cochlea related to gap junctions containing connexin proteins including K+-recycling, nutrient and energy supply, and generation and maintenance of the unique electrochemical environments of the endolymph and perilymph9, their roles in the immune system have not been elucidated.
Macrophages and leukocytes are present in the cochlea of the avian inner ear10, especially within the hyaline/cuboidal cell region, which is located just below the sensory epithelium and near the basilar membrane11. A recent study reported that ionized calcium-binding adapter molecule 1 (Iba1)-positive resident macrophages were present in high numbers in the spiral ligament, spiral ganglion, and stria vascularis of the postnatal cochlea in mice12. Moreover, another study using mice with macrophages expressing green fluorescent protein (GFP) showed that very few macrophages (0–4/100 μm) were present in sensory epithelium, and that selective HC lesions increased the number of macrophages, which might have migrated from under the basilar membrane13. This suggests that macrophages migrate from outside the sensory epithelium in response to HC damage. In addition, macrophages accumulated around the nerve fibres at the habenula perforata, where nerves enter and exit the organ of Corti14, suggesting macrophages might enter from the habenular opening. In the stria vascularis, which supplies oxygen to the HCs15, vascular endothelial cells, pericytes and perivascular-resident macrophage-like melanocytes (PVM/Ms) form a blood-labyrinthine barrier1. For PVM/Ms, recent findings suggested that perivascular macrophages require more careful analysis to have melanocyte characteristics16, but these cells are critical regulatory cells in the fluid-blood barrier and may form the first line of immunological defence17. These cells were reported to inhibit pathogen entry via the stria vascularis by regulating the fluid-blood barrier, similar to what occurs in the CNS, and to function as macrophages that protect against pathogens1,18. A recent study using bone marrow chimeric mice showed that macrophages are present in the spiral ligament and spiral ganglion, but not in the sensory epithelium19. This suggests that there is a mechanism to prevent infectious agents such as viruses entering the organ of Corti. However, the defence mechanism around HCs when pathogens invade beyond these lines of defence awaits elucidation.
One of the earliest innate antiviral defence mechanisms is the type I interferon (IFN) system20. We previously found that Theiler’s murine encephalomyelitis virus (TMEV) infection in murine newborn cochlear sensory epithelium results in IFN-α/β production21. TMEV is a small RNA picornavirus commonly used as an experimental model system for blood-brain barrier disruption22. In the present study, we isolated murine newborn cochlear sensory epithelium and investigated the effects of viral infection on epithelial cells, because these cells can only be isolated from the relatively soft newborn temporal bone. Using this experimental system, we sought to identify whether a protection system against infection in the sensory epithelium of the organ of Corti exists.
Results
IFN-α/β produced by SCs and GERCs protects HCs against virus infection
As shown in Fig. 1a, the IFN (alpha and beta) receptor 1 (Ifnar1) and IFN (alpha and beta) receptor 2 (Ifnar2) subunits of IFN-α/β receptors23 were expressed in OHCs and IHCs. Infections with TMEV were mainly established in SCs, and infections in HCs were rarely observed from 9 h post-infection (Fig. 1b, left). Conversely, virus-infected HC numbers were seen to increase significantly in the Ifnar1-null24 sensory epithelium (Fig. 1b, right), demonstrating that the type I IFN system was present and functional in the studied sensory epithelium. The isolated sensory epithelium contained only HCs, SCs and GERCs, with no lateral wall containing stria vascularis, pericytes and PVM/Ms present21. Interestingly, expression of IFN-α/β and macrophage-associated marker mRNA was induced, suggesting the existence of macrophage-like cells in epithelial tissue (Fig. 1c). The macrophage markers F4/80, macrophage-1 antigen (Mac-1), Iba1 and IFN regulatory factor 5 (Irf5) from M1 macrophages, and jumonji domain containing-3 (Jmjd3) and others from M2 macrophages25,26,27, were also induced by the viral infection (Fig. 1d,e).
Virus-infected SCs and GERCs become detached from their cell layers
To identify which cells express macrophage-associated genes, we analysed the virus-infected sensory epithelium. The virus-infected SCs and GERCs became detached from their cell layers (Supplementary Videos 1 and 2). At 9 h post-infection with TMEV, several SCs left their cell layer and entered the HC layer (Fig. 2a; TMEV 9 h). Subsequently, the virus-infected GERCs also detached from their cell layer (Fig. 2a; TMEV 16 h and 24 h). The virus-infected sensory epithelia were then analysed by electron microscopy (Fig. 2b,c and Fig. S1a–c). Similar SC migration was also observed following infection with HSV-1, a major cause of virus-induced sudden sensorineural hearing loss (Fig. 2d,e). The ectopic expression of mitochondrial antiviral signalling (Mavs, also called IPS-1)28, a downstream signal activator of the retinoic acid inducible gene-I (RIG-I) and melanoma differentiation-associated gene 5 (MDA5), induced SC migration (Fig. S1d,e). These observations suggest that RIG-I-like receptors were able to detect the TMEV infection and induce the release of SCs from cell-cell adhesion constraints.
Virus-infected SCs and GERCs each show an activated macrophage phenotype
In the absence of the TMEV infection, SCs, but not GERCs, expressed low levels of F4/80, but upon infection these levels were significantly enhanced or induced the expression of F4/80 in the SCs or GERCs, respectively (Fig. 3a). In response to the virus infection, enhanced expression of Irf5 and Jmjd3 was seen in the SCs (Fig. 3b,c), indicative of both proinflammatory M1 and anti-inflammatory M2 macrophage types29. Conversely, the GERCs expressed Jmjd3, but not Irf5, during the virus infection (Fig. 3d), indicative of an anti-inflammatory M2 macrophage phenotype29. Moreover, the expression of other macrophage markers was induced by the virus infection (Fig. S2), and both virus-infected SCs and GERCs alike exhibited phagocytosis (Fig. 3e), a hallmark of functional macrophages. This suggests that SCs and GERCs function similarly to the tissue-resident macrophages previously reported to regulate tissue homeostasis by acting as sentinels responding to physiological changes and pathogenic microorganisms30,31. Conversely, the SCs and GERCs were anchored by tight junctions in the absence of the TMEV infection. Similar to the inner ear, the blood-brain barrier prevents access of the peripheral immune system to the CNS, where microglial cells (resident macrophages), which arise from yolk sac macrophages during foetal development, regulate brain development, maintenance of neuronal networks, and injury repair. Moreover, microglia function as macrophages by eliminating dead cells, microbes and other pathogens that may damage the CNS32,33.
The sensory epithelium’s immune system contains macrophage-like cells
Under steady-state conditions, microglial cell receptors, including CD200 receptor 1 (Cd200r1), interact with neural cell-surface ligands, resulting in the inhibition of microglial cell activity32,33. As shown in Fig. 4a, Cd200r1 was expressed in SCs and GERCs, and its ligand, cluster of differentiation 200 (Cd200), was mainly expressed in HCs, as well as in SCs and GERCs, suggesting that SCs and GERCs are inhibited by HCs and by each other. In response to virus infection, Cd200r1 expression was suppressed (Fig. 4a, lower right), suggesting the CD200-CD200R-mediated suppression of macrophage-like function32,33 was inhibited by virus-infection similar to the microglia system. SCs and GERCs differ from the typical microglia that patrol the brain microenvironment in that SCs and GERCs tightly adhere to each other and to HCs. SCs are thought to primarily separate the endolymph and perilymph via the tight junction architecture, thereby maintaining the integrity of the sensory epithelium against mechanical stress from the vibrations transmitted by sound waves34. As potential macrophage-like cells, this architecture may suppress the shape and function of the SCs and GERCs (Fig. S1a). However, upon virus infection, the SCs and GERCs altered their shapes to become more macrophage-like and were able to migrate (Fig. S1b,c). To conduct a faint sound wave, only a minimal structure is required in the sensory epithelium. Therefore, SCs and GERCs might play diverse roles in sound conduction, homeostasis and immunity. In the present study, we analysed viral infection in cochlear sensory epithelia isolated from newborn mice. In the SHIELD (Shared Harvard Inner-ear Laboratory Database35) database, we found that genes associated with macrophages and inflammation that target pathogens were expressed in the SC fractions during development (embryonic day E16, postnatal days P0, P4 and P7; Fig. S3), suggesting that macrophage-like SCs also exist in adult mouse cochleae.
Interestingly, we identified a row of cells that expressed the common microglial marker Iba132,36 under Deiters’ cells (DCs) and pillar cells (PCs)32 (Fig. 4b). However, these Iba1+ cells disappeared after viral infection (Fig. 4c), suggesting that they migrate in response to infection and function as typical microglial cells.
SCs and GERCs phagocytose bacteria without cell migration
To gain further insight into the mechanisms involved in the macrophage activation of SCs, we stimulated SCs with various pathogen-associated molecules known to activate macrophages. The induction of macrophage-associated markers and proinflammatory cytokines was observed following stimulation with lipopolysaccharide (LPS) and double-stranded (ds)RNA, both of which are recognised by Toll-like receptors37 (Fig. 5a,b and Fig. S4a–d). Moreover, the LPS-induced phagocytosis of SCs was observed (Fig. 5c), suggesting a protective role for SCs against pathogens other than viruses. Indeed, the SCs were able to phagocytose Escherichia coli in the absence of cell migration (Fig. 5d,e). Although Cd200r1 expression was suppressed by LPS and dsRNA stimuli (Fig. S4e,f), the SCs and GERCs did not migrate (Fig. S4g,h). In fact, our cDNA microarray analysis revealed the suppression of many cell adhesion proteins following virus infection, but not after LPS stimulation (Fig. S4i).
Role played by Irf5 in changing SCs into macrophage-like cells
In the sensory epithelium of Irf5−/− mice where M1 macrophage polarization is suppressed25,38, induction of the genes encoding F4/80, Mac-1 and Iba1 macrophage markers, suppression of Cd200r1 (Fig. 6b), and migration of the SCs in response to virus infection (Fig. 6a,c, compared to Fig. 2a) were all impaired. This indicates that virus-induced macrophage activation and SC migration are partly regulated by Irf5 (Fig. 6d). Conversely, the virus-induced migration of GERCs was still observed in the Irf5−/−sensory epithelium (Fig. 6a,c). Moreover, Irf5 knockout accelerated TMEV infection in cochlear sensory epithelia, suggesting that Irf5-mediated macrophage polarization is required for efficient protection against virus-infection (Fig. 6e–g). These results indicate that SCs and GERCs are distinct types of macrophage-like cells, and that different signalling mechanisms are required for macrophage activation and the migration of these cells.
Discussion
The present study provides initial evidence supporting the macrophage-like nature of cochlear SCs and their potential importance in anti-viral and anti-bacterial defences in the inner ear. Many tissue-resident macrophages, especially microglia, arise from the embryonic precursors that take residence prior to birth and maintain a local position throughout adulthood30,39. It has been shown that the third DC row and inner PCs adjacent to HCs (Fig. 4b,c) act as HC progenitors following injury40, suggesting that their origin is the same as that of HCs. Like HCs, SCs are also considered to be ectoderm cells, but our results suggest the possibility that some SCs, including Hensen’s cells and Claudius’ cells, have a mesodermal cell origin. Indeed, virus- or LPS-stimulated SCs displayed characteristics typical of macrophages, as determined by our analysis of macrophage marker protein expression, transcriptional profiles, and phagocyte activity and morphology, suggesting that SCs are tissue-resident macrophages. Moreover, under our experimental conditions, isolated sensory epithelium contained rows of Hensen’s cells and 4–6 rows of Claudius’ cells, both of which were infected with the virus and migrated with increased expressions of macrophage markers including F4/80, Irf5, and Jmjd3. This suggested that Hensen’s cells and Claudius’ cells function as macrophages. A notable difference between SCs and other resident macrophages, especially microglia, is that uninfected SCs show no typical features of macrophages, particularly in terms of their morphology, and are anchored by tight junctions in their resting state. However, it has been shown that tight junction proteins are expressed in lung epithelium macrophages41.
Here, we analysed viral infections in isolated cochlear sensory epithelia from the soft temporal bones of newborn mice, because it is difficult to obtain viable organs of Corti that have maintained their tissue structures from the temporal bones of adult mice. Therefore, our analyses have some limitations. During development, cochlear extension and coiling continue until approximately E19 or P0, by which time the duct has reached its mature shape. At the tissue level, cellular differentiation within the prosensory domain is observable in the mid-basal region of the cochlea between E14 and E15. Developing OHCs are observable by E15 to E16, and developing SCs become morphologically distinct around the same time. By E17, HCs and SCs along the length of the cochlear duct have become arranged into the characteristic pattern for the organ of Corti42,43. Although full cochlear function takes some time to complete after birth, it is considered that the cellular differentiation and organization of the organ of Corti is completed before birth. This is supported by our findings that show that the genes associated with macrophages and inflammation were expressed in the cochlear SC fractions after birth (P0, P4 and P7; Fig. S3). Therefore, although the neonatal organ of Corti is in a different functional state when compared with the adult mouse, our experimental results were at least obtained from tissues with the same cell composition as the adult mouse. Therefore, in the same way that microglial cells arise from embryonic precursors, it is conceivable that embryonic-stage macrophage-like cells play a role in infection prevention in the adult mouse.
The stria vascularis of the inner ear is a highly specialised capillary network that controls exchanges between blood and the intrastitial cochlea space, and is enriched in tight junctions1. In a murine model of cytomegalovirus (CMV)-induced hearing loss, cells expressing a CMV-encoded protein were detected in the stria vascularis44, suggesting that viruses invade the inner ear endolymph from the blood flow through the stria vascularis. If pathogens can invade the first line of defence in the stria vascularis, there is no immune protection mechanism in the endolymph because immune cells do not circulate in this region. In the audiosensory organ, massive cell movement might cause ectopic sound waves; therefore, newly identified anchored-phagocyte systems that surround HCs are useful for providing a silent protection system in audiosensory organs. However, with viral infections, virus-infected cell elimination may occur by inhibiting the expression of cell adhesion molecules via the MAVS-signalling cascade, and following the induction of virus-induced apoptosis in the infected cells. It is not currently clear that such cell migration is observed in the adult mouse. It is possible that SC migration in response to viral infection results in electrical leakage and electrolyte imbalance, and that this imbalance impairs cochlear function45. Thus, although this system works well for low-level viral infections, it may not be able to protect HCs from severe viral infections. In addition, activation of the macrophage-like function of SCs was followed by that of GERCs. Considering GERCs were relatively polarised to an anti-inflammatory M2 phenotype, these delayed activated GERCs might suppress inflammatory reactions and promote tissue repair in the organ of Corti.
Unlike viral infections, in bacterial infections, the expression of cell adhesion molecules in HCs does not change and bacterial phagocytosis occurs. This phenomenon seems to be a beneficial system to eliminate bacteria while causing minimal tissue damage. However, our current results only showed the phagocytic activity of SCs. Further analyses are required to elucidate the protective role of SCs against bacterial infection, using clinically known bacteria that cause inner ear infection. In addition, we showed that microglia-like Iba1-positive cells were present under the HC layer. These cells disappeared after viral infection, but we have no direct evidence that they migrated to the site of viral infection, at present. Moreover, it is still unclear whether these cells exist in adult mice. However, very few macrophages are present in the sensory epithelium13. Therefore, if an infection occurs near HCs, these pre-existing macrophages might traffic to the infected area to protect HCs from the pathogen in cooperation with the SCs. These double-defence mechanisms may protect audiosensory organs from viruses and other pathogens.
Methods
Experimental animals
Postnatal day 2 (sex: unknown) ICR mice (SLC), Ifnar1 null mice (B&K Universal), and Irf5 null mice38 were used in this study. All experimental procedures were performed in accordance with the NIH Guide for the Care and Use of Laboratory Animals. The Animal Research Committee of Nippon Medical School approved all experimental protocols.
Preparation and treatment of cochlear sensory epithelium explant cultures
Cochlear sensory epithelia were resected and cultured as previously described21. All experiments began after an overnight incubation of each cochlea with 300 µl medium to stabilize the explants. Each cochlea was then transferred to 400 µl medium containing 3.0 × 107 pfu/ml TMEV, which is an RNA virus. TMEV (GDVII strain) was propagated from viral cDNA and BHK21 cells46. Cultures were maintained for 9–12 h until TMEV began to infect the SCs. At 16–21 h, TMEV began to infect the GERCs and HC death was observed. HC death was almost completed by 24 h. To determine the characteristics of macrophage marker-positive SCs and GERCs, we analysed the phagocytosis of these cells using Zymosan A (Invitrogen), chemically or heat-killed Saccharomyces cerevisiae conjugated with Alexa Fluor 488. At 9 or 19 h after TMEV or lipopolysaccharide (LPS) incubation, Zymosan A (16 µl) diluted 1:100 with phosphate-buffered saline (PBS) was added to the medium for 1 h. To determine whether SCs acquired phagocytosis capabilities during virus and bacterial infection, we used EGFP-E. coli. EGFP cDNA was cloned into a GST expression vector, pGEX6P-1 (GE Healthcare). The E. coli strain, BL21(DE3)-RIL (Agilent Technologies) was transformed with the pGEX6P-1-EGFP plasmid and shaking-cultured in LB medium at 37 °C, 200 rpm for 2 h. EGFP protein expression was induced by the addition of 1 mM IPTG for 1.5 h. After shaking-culture, LB medium with transformed E. coli was diluted 20 times with Dulbecco’s modified Eagle’s medium (DMEM) without any antibiotics. Cochlear sensory epithelia were cultured in this medium for 16 h. To evaluate the influence of retinoic acid inducible gene-I (RIG-I)-like receptor (RLR) stimulation by virus infection and toll-like receptor (TLR) stimulation, we used LPS and poly I:C. The explants were transferred to medium containing 100 ng/ml or 1000 ng/ml LPS (Sigma-Aldrich) for up to 24 h or 20 µg/ml or 200 µg/ml poly I:C (Sigma-Aldrich) for up to 48 h. To determine whether RNA virus and DNA virus induced SC and GERC activation as macrophages, we used herpes simplex virus 1 (HSV-1) carrying GFP (YK333)47. This recombinant virus possesses a complete set of viral genes and exhibits the same growth properties as the wild-type virus. In cells infected with GFP-HSV-1, GFP expression is driven by the host early growth response 1 (Egr-1) promoter48. GFP-HSV-1 was produced by Vero cells49 in the absence of antibiotics to exclude the possibility that administered antibiotics could injure cochleae. The explants were infected with 1.0 × 107 pfu/ml GFP-HSV-1 for up to 24 h. The common downstream molecule after TMEV and HSV-1 infection is interferon-β promoter stimulator 1 (IPS-1)47, which is not upregulated by LPS or poly I:C stimulation. We hypothesized that IPS-1 is a key molecule involved in SC migration during virus infection. Based on this, we transfected SCs with IPS-1 lentivirus vector. Mouse IPS-1 cDNA was synthesized from murine embryonic fibroblasts by RT-PCR. The N-terminal 2 human influenza hemagglutinin (HA)-tagged mouse IPS-1 (2HA-IPS-1) was constructed by cloning the above IPS-1 cDNA into the pCDH-EF1-MCS-IRES-Puro vector (System Biosciences). The constructs were transfected into 293 T packaging cells along with the packaging plasmids. Initially, the cochlear explants were incubated for 24 h in the above lentivirus-containing supernatants diluted two times with DMEM, to which 8 µg/ml polybrene was added, and cultured for the next 48 h in the supernatants prepared anew in the same way.
Immunohistochemistry
For whole-mount immunohistochemistry, samples were fixed at room temperature (RT) for 15 min in 4% paraformaldehyde in 0.1 M phosphate buffer (pH 7.4), then rinsed with PBS. Samples for cryosections were fixed at RT for 15 min in 4% paraformaldehyde in 0.1 M phosphate buffer (pH 7.4). After rinsing with PBS, they were embedded in OCT compound (Tissue Tek), and sections including planes around the centre of the concentric circle were prepared. All specimens were incubated in blocking solution at RT for 30 min in 10% goat serum with 0.2% Triton X-100 for all antibodies except Cd200r1 and HA or for 15 min in 0.2% Triton X-100 and 15 min in 1% BSA in 0.2% Triton X-100 when co-labelled with Cd200r1 or HA. The primary antibodies used in this study were as follows: rabbit polyclonal anti-Myosin VIIA (Myo7a) (25–6790; 1:1000) from Proteus Biosciences, rabbit polyclonal anti-Ifnar1 (ab62693; 1:50) from Abcam, rabbit polyclonal anti-Ifnar2 (orb100572; 1:100) from Biorbyt, mouse monoclonal anti-double-stranded RNA (dsRNA) (J2; 1:800, K1; 1:2000) from English & Scientific Consulting, rabbit polyclonal anti-Jmjd3 (ab38113; 5 µg/ml) from Abcam, mouse monoclonal anti-Irf5 (10T1; 1:50) from Abcam, rat monoclonal anti-F4/80 (A3-1; 1:50) from AbD Serotec, rabbit polyclonal anti-Cd200 (ab203887; 1:500) from Abcam, goat polyclonal anti-Cd200r1 (AF2554; 5 µg/ml) from R&D Systems, rat monoclonal anti-GFP (GF090R; 1:500) from Nacalai Tesque, and rat monoclonal anti-HA (3F10; 1:500) from Roche. Actin filaments were visualized with Alexa 594- or 633-labelled phalloidin (1:100, Invitrogen). The primary antibodies were visualized with Alexa 488- or 546-conjugated anti-rabbit, anti-mouse, or anti-rat goat IgG or Alexa 488-conjugated anti-goat donkey IgG (1:1000, Invitrogen). Samples with nuclear staining were then incubated in PBS containing 1 μg/ml DAPI (Invitrogen). Fluorescent images were captured using an Olympus FV1200 confocal microscope. The computational section images were reconstructed by FV10-ASW (Olympus) after capturing images every 0.2–0.5 µm. The whole-mount images of HCs were obtained by superposing images from the bottom to the top of HCs after capturing images every 0.5 µm. The whole-mount images of virally infected, activated SCs or GERCs were obtained from single slices or several slices overlapped at the SC or GERC level after capturing images every 0.5 µm.
Cell counts
The numbers of dsRNA and Myo7a double-positive inner and outer HCs in the sensory epithelium were counted in one high-power field (318 × 318 µm) in the basal- to mid-turn of each explant. As described above, we estimated from the basal- to mid-turn of the cochlea, because Hensen’s cells and Claudius’ cells in the apical turn overlapped with the inner side of the basal-turn.
Electron microscopy
Electron microscopy analysis was performed as described previously50,51, with slight modification. Mouse inner ears were observed by transmission and scanning electron microscopy (SEM). The specimens were fixed with 2% glutaraldehyde in 0.1 M phosphate buffer (pH 7.4) for 60 min, washed five times in 0.1 M phosphate buffer, and post-fixed with 1% osmium tetroxide for 60 min at 4 °C. For transmission electron microscopy (TEM), the fixed inner ears were dehydrated with a graded ethanol series, and embedded in EponA2 according to the conventional method. Thin sections were cut with a diamond knife, stained with uranyl acetate and lead citrate, and examined with a JEM-1010 transmission electron microscope (JEOL) at an accelerating voltage of 80 kV. For SEM, the fixed inner ears were dehydrated with a graded ethanol series and then freeze-dried (Hitachi ES-2020, Hitachi) in t-butyl alcohol. After coating with osmium tetroxide (approximately 10 nm thick) using an osmium plasma coater (NL-OPC80, Nippon Laser & Electronics Lab.), the specimens were examined with a Hitachi S-4500 field emission SEM at an accelerating voltage of 10 kV.
RNA extraction, qRT-PCR, and microarray
For qRT-PCR, the RNeasy Micro Kit (Qiagen) was used to extract total RNA from three cochlear sensory epithelia, which were cultivated under the following conditions for 9 or 16 h: DMEM alone; DMEM with TMEV; DMEM with LPS; and DMEM with poly I:C, respectively. cDNA was synthesized from DNase-treated total RNA using the PrimeScript RT reagent Kit (Takara Bio). Synthesized cDNA was subsequently mixed with TaqMan Universal PCR Master Mix (Applied Biosystems) in the presence of commercial TaqMan primer-probe sets of interest (Applied Biosystems). Real-time PCR quantification was performed using the ABI StepOnePlus Real-Time PCR System (Applied Biosystems). All reactions were performed in triplicate. The relative mRNA amounts were calculated using the ΔΔCt method. For the invariant control, we used actin beta (Actb). For microarray, total RNA was extracted from nine mock explants, nine explants treated with 1000 ng/ml LPS for 16 h, or 14 explants infected with TMEV for 16 h using the RNeasy Micro Kit. TMEV infection for 16 h induced cochlear cell death in HCs and SCs; therefore, a greater number of TMEV-infected cochleae was needed compared with the mock and LPS-treated cochleae to equalize the amount of total RNA. Filgen (a biological technical service company) performed the microarray analysis using the GeneChip Mouse Gene 2.0 ST Array (Affymetrix).
Live imaging
TMEV-infected cochleae were cultivated on a collagen-coated 35-mm glass-bottom dish (MatTek) for live imaging. For visualizing activated SCs and GERCs as macrophages, a Leica SP8 confocal laser-scanning microscope equipped with a HC PL APO 63×/1.40 CS2 oil objective was used. Images were captured every 5 min, from 8 to 25 h after TMEV infection, using a 488-nm argon laser with 10% intensity. While capturing images, the explant was maintained in a CO2 (5%) stage-top incubator (INUBG2F-GSI2, Tokai Hit) at 37 °C. The movies were constructed using Leica LAS AF software (9–14 h and 14–21 h, respectively).
Statistical analysis
The data are expressed as the mean ± standard error. Unpaired t-tests were used for Myo7a and dsRNA double-positive HCs, in which P-values <0.05 were considered statistically significant. Unpaired t-tests were used for cell numbers or sum of dsRNA signal intensity in WT and Irf5 KO cochleae infected with TMEV for 9 h, in which P-values <0.05 were considered statistically significant. In all qRT-PCR analyses, unpaired t-tests were used, in which P-values <0.05 were considered statistically significant.
References
Shi, X. Pathophysiology of the cochlear intrastrial fluid-blood barrier (review). Hear Res 338, 52–63, https://doi.org/10.1016/j.heares.2016.01.010 (2016).
Mellor, A. L. & Munn, D. H. Creating immune privilege: active local suppression that benefits friends, but protects foes. Nat Rev Immunol 8, 74–80, https://doi.org/10.1038/nri2233 (2008).
Wan, G., Corfas, G. & Stone, J. S. Inner ear supporting cells: rethinking the silent majority. Semin Cell Dev Biol 24, 448–459, https://doi.org/10.1016/j.semcdb.2013.03.009 (2013).
Raphael, Y. & Altschuler, R. A. Structure and innervation of the cochlea. Brain Res Bull 60, 397–422 (2003).
Nakashima, T. et al. Disorders of cochlear blood flow. Brain Res Brain Res Rev 43, 17–28 (2003).
Goutman, J. D., Elgoyhen, A. B. & Gomez-Casati, M. E. Cochlear hair cells: The sound-sensing machines. FEBS Lett 589, 3354–3361, https://doi.org/10.1016/j.febslet.2015.08.030 (2015).
Dayaratne, M. W., Vlajkovic, S. M., Lipski, J. & Thorne, P. R. Kolliker’s organ and the development of spontaneous activity in the auditory system: implications for hearing dysfunction. Biomed Res Int 2014, 367939, https://doi.org/10.1155/2014/367939 (2014).
Tritsch, N. X., Yi, E., Gale, J. E., Glowatzki, E. & Bergles, D. E. The origin of spontaneous activity in the developing auditory system. Nature 450, 50–55, https://doi.org/10.1038/nature06233 (2007).
Wingard, J. C. & Zhao, H. B. Cellular and Deafness Mechanisms Underlying Connexin Mutation-Induced Hearing Loss - A Common Hereditary Deafness. Front Cell Neurosci 9, 202, https://doi.org/10.3389/fncel.2015.00202 (2015).
Warchol, M. E. Macrophage activity in organ cultures of the avian cochlea: demonstration of a resident population and recruitment to sites of hair cell lesions. J Neurobiol 33, 724–734 (1997).
Warchol, M. E., Schwendener, R. A. & Hirose, K. Depletion of resident macrophages does not alter sensory regeneration in the avian cochlea. PLoS One 7, e51574, https://doi.org/10.1371/journal.pone.0051574 (2012).
Kishimoto, I., Okano, T., Nishimura, K., Motohashi, T. & Omori, K. Early Development of Resident Macrophages in the Mouse Cochlea Depends on Yolk Sac Hematopoiesis. Front Neurol 10, 1115, https://doi.org/10.3389/fneur.2019.01115 (2019).
Kaur, T. et al. Fractalkine Signaling Regulates Macrophage Recruitment into the Cochlea and Promotes the Survival of Spiral Ganglion Neurons after Selective Hair Cell Lesion. J Neurosci 35, 15050–15061, https://doi.org/10.1523/JNEUROSCI.2325-15.2015 (2015).
Liu, W., Molnar, M., Garnham, C., Benav, H. & Rask-Andersen, H. Macrophages in the Human Cochlea: Saviors or Predators-A Study Using Super-Resolution Immunohistochemistry. Front Immunol 9, 223, https://doi.org/10.3389/fimmu.2018.00223 (2018).
Nyberg, S., Abbott, N. J., Shi, X., Steyger, P. S. & Dabdoub, A. Delivery of therapeutics to the inner ear: The challenge of the blood-labyrinth barrier. Sci Transl Med 11, https://doi.org/10.1126/scitranslmed.aao0935 (2019).
Jiang, Y. et al. Lipopolysaccharide disrupts the cochlear blood-labyrinth barrier by activating perivascular resident macrophages and up-regulating MMP-9. Int J Pediatr Otorhinolaryngol 127, 109656, https://doi.org/10.1016/j.ijporl.2019.109656 (2019).
Zhang, J. et al. Lipopolysaccharide-induced middle ear inflammation disrupts the cochlear intra-strial fluid-blood barrier through down-regulation of tight junction proteins. PLoS One 10, e0122572, https://doi.org/10.1371/journal.pone.0122572 (2015).
Engelhardt, B., Vajkoczy, P. & Weller, R. O. The movers and shapers in immune privilege of the CNS. Nat Immunol 18, 123–131, https://doi.org/10.1038/ni.3666 (2017).
Okano, T. et al. Bone marrow-derived cells expressing Iba1 are constitutively present as resident tissue macrophages in the mouse cochlea. J Neurosci Res 86, 1758–1767, https://doi.org/10.1002/jnr.21625 (2008).
Ivashkiv, L. B. & Donlin, L. T. Regulation of type I interferon responses. Nat Rev Immunol 14, 36–49, https://doi.org/10.1038/nri3581 (2014).
Hayashi, Y. et al. Virus-induced expression of retinoic acid inducible gene-I and melanoma differentiation-associated gene 5 in the cochlear sensory epithelium. Microbes Infect 15, 592–598, https://doi.org/10.1016/j.micinf.2013.04.008 (2013).
Johnson, H. L., Jin, F., Pirko, I. & Johnson, A. J. Theiler’s murine encephalomyelitis virus as an experimental model system to study the mechanism of blood-brain barrier disruption. J Neurovirol 20, 107–112, https://doi.org/10.1007/s13365-013-0187-5 (2014).
Ng, C. T., Mendoza, J. L., Garcia, K. C. & Oldstone, M. B. Alpha and Beta Type 1 Interferon Signaling: Passage for Diverse Biologic Outcomes. Cell 164, 349–352, https://doi.org/10.1016/j.cell.2015.12.027 (2016).
Muller, U. et al. Functional role of type I and type II interferons in antiviral defense. Science 264, 1918–1921 (1994).
Krausgruber, T. et al. IRF5 promotes inflammatory macrophage polarization and TH1-TH17 responses. Nat Immunol 12, 231–238, https://doi.org/10.1038/ni.1990 (2011).
Ley, K., Pramod, A. B., Croft, M., Ravichandran, K. S. & Ting, J. P. How Mouse Macrophages Sense What Is Going On. Front Immunol 7, 204, https://doi.org/10.3389/fimmu.2016.00204 (2016).
Satoh, T. et al. The Jmjd3-Irf4 axis regulates M2 macrophage polarization and host responses against helminth infection. Nat Immunol 11, 936–944, https://doi.org/10.1038/ni.1920 (2010).
Yoneyama, M., Onomoto, K., Jogi, M., Akaboshi, T. & Fujita, T. Viral RNA detection by RIG-I-like receptors. Curr Opin Immunol 32, 48–53, https://doi.org/10.1016/j.coi.2014.12.012 (2015).
Lawrence, T. & Natoli, G. Transcriptional regulation of macrophage polarization: enabling diversity with identity. Nat Rev Immunol 11, 750–761, https://doi.org/10.1038/nri3088 (2011).
Ginhoux, F. & Guilliams, M. Tissue-Resident Macrophage Ontogeny and Homeostasis. Immunity 44, 439–449, https://doi.org/10.1016/j.immuni.2016.02.024 (2016).
Wynn, T. A., Chawla, A. & Pollard, J. W. Macrophage biology in development, homeostasis and disease. Nature 496, 445–455, https://doi.org/10.1038/nature12034 (2013).
Kettenmann, H., Hanisch, U. K., Noda, M. & Verkhratsky, A. Physiology of microglia. Physiol Rev 91, 461–553, https://doi.org/10.1152/physrev.00011.2010 (2011).
Ransohoff, R. M. & Cardona, A. E. The myeloid cells of the central nervous system parenchyma. Nature 468, 253–262, https://doi.org/10.1038/nature09615 (2010).
Hou, J. The role of claudin in hypercalciuric nephrolithiasis. Curr Urol Rep 14, 5–12, https://doi.org/10.1007/s11934-012-0289-2 (2013).
Scheffer, D. I., Shen, J., Corey, D. P. & Chen, Z. Y. Gene Expression by Mouse Inner Ear Hair Cells during Development. J Neurosci 35, 6366–6380, https://doi.org/10.1523/JNEUROSCI.5126-14.2015 (2015).
Imai, Y. & Kohsaka, S. Intracellular signaling in M-CSF-induced microglia activation: role of Iba1. Glia 40, 164–174, https://doi.org/10.1002/glia.10149 (2002).
Kawai, T. & Akira, S. The role of pattern-recognition receptors in innate immunity: update on Toll-like receptors. Nat Immunol 11, 373–384, https://doi.org/10.1038/ni.1863 (2010).
Takaoka, A. et al. Integral role of IRF-5 in the gene induction programme activated by Toll-like receptors. Nature 434, 243–249, https://doi.org/10.1038/nature03308 (2005).
Okabe, Y. & Medzhitov, R. Tissue biology perspective on macrophages. Nat Immunol 17, 9–17, https://doi.org/10.1038/ni.3320 (2016).
Bramhall, N. F., Shi, F., Arnold, K., Hochedlinger, K. & Edge, A. S. Lgr5-positive supporting cells generate new hair cells in the postnatal cochlea. Stem Cell Reports 2, 311–322, https://doi.org/10.1016/j.stemcr.2014.01.008 (2014).
Blank, F. et al. Macrophages and dendritic cells express tight junction proteins and exchange particles in an in vitro model of the human airway wall. Immunobiology 216, 86–95, https://doi.org/10.1016/j.imbio.2010.02.006 (2011).
Kelley, M. W. Cellular commitment and differentiation in the organ of Corti. Int J Dev Biol 51, 571–583, https://doi.org/10.1387/ijdb.072388mk (2007).
Kelley, M. W., Driver, E. C. & Puligilla, C. Regulation of cell fate and patterning in the developing mammalian cochlea. Curr Opin Otolaryngol Head Neck Surg 17, 381–387, https://doi.org/10.1097/MOO.0b013e3283303347 (2009).
Bradford, R. D. et al. Murine CMV-induced hearing loss is associated with inner ear inflammation and loss of spiral ganglia neurons. PLoS Pathog 11, e1004774, https://doi.org/10.1371/journal.ppat.1004774 (2015).
Ikeda, R. et al. Effect of vestibular labyrinth destruction on endocochlear potential and potassium concentration of the cochlea. Hear Res 265, 90–95, https://doi.org/10.1016/j.heares.2009.12.027 (2010).
Fu, J. L. et al. Neurovirulence determinants of genetically engineered Theiler viruses. Proc Natl Acad Sci USA 87, 4125–4129 (1990).
Tanaka, M., Kodaira, H., Nishiyama, Y., Sata, T. & Kawaguchi, Y. Construction of recombinant herpes simplex virus type I expressing green fluorescent protein without loss of any viral genes. Microbes Infect 6, 485–493, https://doi.org/10.1016/j.micinf.2004.01.011 (2004).
Satoh, T. et al. PILRalpha is a herpes simplex virus-1 entry coreceptor that associates with glycoprotein B. Cell 132, 935–944, https://doi.org/10.1016/j.cell.2008.01.043 (2008).
Menasria, R. et al. Both TRIF and IPS-1 adaptor proteins contribute to the cerebral innate immune response against herpes simplex virus 1 infection. J Virol 87, 7301–7308, https://doi.org/10.1128/JVI.00591-13 (2013).
Suzuki, H. et al. Redistribution of alpha-granule membrane glycoprotein IIb/IIIa (integrin alpha IIb beta 3) to the surface membrane of human platelets during the release reaction. J Electron Microsc (Tokyo) 43, 282–289 (1994).
Uehara, T. et al. Pathogenetic basis of Takenouchi-Kosaki syndrome: Electron microscopy study using platelets in patients and functional studies in a Caenorhabditis elegans model. Sci Rep 9, 4418, https://doi.org/10.1038/s41598-019-40988-7 (2019).
Acknowledgements
We thank H. Ozawa for helpful advice and T. Taniguchi and T.W. Mac for providing Irf5 KO mice. We also thank Y. Abe, M. Shimizu, and C. Iwabuchi for discussions, and M. Kawagoe, Y. Asano, and T. Takatera for technical support. This work was supported by Grants-in-Aid from the Ministry of Education, Culture, Sports, Science and Technology of Japan and the Clinical Rebiopsy Bank Project for Comprehensive Cancer Therapy Development in Nippon Medical School. This work was also supported by KAKENHI (a Grant-in-Aid for Young Scientists (B) (15K20240) and a Grant-in-Aid for Research Activity start-up (25893299)) to YH. We thank Sandra Cheesman, PhD, from Edanz Group (www.edanzediting.com/ac) for editing a draft of this manuscript.
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Y.H. and N.T. designed the experiments. Y.H. performed most experiments. W.N., I.U. and A.T. supported the experiments. H.S. and Y.H. performed electron microscopy. T.K., Y.H. and S-I.K. performed live imaging. N.K., Y.H. and Y.K. performed the GFP-HSV-1-infection assay. T.H., S.K., K.O., H.K., M.Y. and T.F. prepared TMEV. K.O., H.K., M.Y. and T.F. provided valuable advice. Y.H. and N.T. wrote the manuscript.
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Hayashi, Y., Suzuki, H., Nakajima, W. et al. Cochlear supporting cells function as macrophage-like cells and protect audiosensory receptor hair cells from pathogens. Sci Rep 10, 6740 (2020). https://doi.org/10.1038/s41598-020-63654-9
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DOI: https://doi.org/10.1038/s41598-020-63654-9
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