Downregulation of Otospiralin, a Novel Inner Ear Protein, Causes Hair Cell Degeneration and Deafness

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The Journal of Neuroscience, March 1, 2002, 22(5):1718-1725

Downregulation of Otospiralin, a Novel Inner Ear Protein, Causes Hair Cell Degeneration and Deafness
Benjamin Delprat¹^,^*, Ana Boulanger¹^,^*, Jing Wang¹, Vicky Beaudoin², Matthieu J. Guitton¹, Stéphanie Ventéo³, Claude J. Dechesne³, Rémy Pujol¹, Mireille Lavigne-Rebillard¹, Jean-Luc Puel¹, and Christian P. Hamel¹
¹ Institut National de la Santé et de la Recherche Médicale U. 254, Laboratoire de Neurobiologie de l'Audition, 34090 Montpellier, France, ² Département de Chimie-Biologie, Université du Québec à Trois-Rivières, Trois-Rivières (Québec), Canada, G9A 5H7, and ³ Institut National de la Santé et de la Recherche Médicale U. 432, Neurobiologie et Développement du Système Audiovestibulaire, Université Montpellier II, 34095 Montpellier cedex 05, France

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Mesenchymal nonsensory regions of the inner ear are important structures surrounding the neurosensory epithelium that arebelieved to participate in the ionic homeostasis of the cochleaand vestibule. We report here the discovery of otospiralin, aninner ear-specific protein that is produced by fibrocytes fromthese regions, including the spiral ligament and spiral limbusin the cochlea and the maculae and semicircular canals in thevestibule. Otospiralin is a novel 6.4 kDa protein of unknown functionthat shares a protein motif with the gag p30 core shell nucleocapsidprotein of type C retroviruses. To evaluate its functional importance,we downregulated otospiralin by cochlear perfusion of antisenseoligonucleotides in guinea pigs. This led to a rapid thresholdelevation of the compound action potentials and irreversible deafness.Cochlear examination by transmission electron microscopy revealedhair cell loss and degeneration of the organ of Corti. This demonstratesthat otospiralin is essential for the survival of the neurosensoryepithelium.

Key words: otospiralin; cochlea; vestibule; hair cell; deafness; gene; antisense; inner ear

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In the mammalian inner ear, proper functioning of hair cells depends on the ionic composition of endolymph and perilymph.Structures that participate in the ionic balance are the striavascularis in the cochlea and the dark cells in the vestibulethat produce the potassium-rich endolymph, but also mesenchymalnonsensory regions, i.e., the spiral limbus proximal to the cochlearaxis and the spiral ligament behind the stria vascularis in thecochlea and the stroma lying beneath the sensory epithelium inthe vestibule. Indeed, the fibrocytes from these regions expressNa,K-ATPase, and carbonic anhydrases II and III (Spicer et al.,1990, 1997; Spicer and Schulte, 1991) as well as various channelsand transporters (Stankovic et al., 1995; Sakaguchi et al., 1998;Couloigner et al., 2001), extracellular matrix proteins (Tsuprunand Santi, 1999; Weinberger et al., 1999; Mothe and Brown, 2001),and regulatory molecules (Thomadakis et al., 1999). The findingthat some fibrocytes also express gap junction connexins 26, 30,and 31 (Lautermann et al., 1998; Kikuchi et al., 2000; Xia etal., 2000) and the chloride-iodide transporter pendrin (Everettet al., 1999; Scott et al., 1999) is a further indication of theirimportance in the fluid movements in the inner ear. These fibrocytesare a heterogenous cell population, classified in the spiral ligamentas types I-V on the basis of their location and marker expression,suggesting a certain level of diversity in the ion homeostasisfunction.

Recently, the search for preferentially expressed inner ear mRNAs has led to the discovery of novel proteins expressed inthe mesenchymal regions. Fdp/otoraplin is a secreted polypeptiderelated to a cartilage-derived protein expressed in all typesof fibrocytes from the spiral ligament, spiral limbus, and mesenchymalcells underlying the basilar membrane (Cohen-Salmon et al., 2000;Robertson et al., 2000; Rendtorff et al., 2001). Otoraplin couldinitiate the induction of chondrogenesis in the cochlea duringdevelopment (Cohen-Salmon et al., 2000). Cochlin is also a secretedprotein of unknown function found in the same regions as otoraplinin the cochlea and in the stroma underlying the sensory epitheliumin the vestibule (Robertson et al., 1998). Both proteins may participatein structural or regulatory functions in the inner ear, thus suggestingmore diversity and complexity of the mesenchymal tissues thanenvisionedpreviously.

By systematic sequencing of rat cochlea cDNA libraries, we identified several genes preferentially expressed in cochlea andouter hair cells (Soto-Prior et al., 1997; Harter et al., 1999).One of these genes was selected for its inner ear-specific expression.We report here that it encodes otospiralin, a novel protein foundin fibrocytes of spiral limbus, spiral ligament, and subepithelialregions of the vestibule. Otospiralin shares a protein motif withthe gag p30 core shell nucleocapsid protein of type C retroviruses.In the guinea pig, transient downregulation of otospiralin byuse of antisense oligonucleotides leads to vestibular dysfunctionand irreversible deafness. Cochlear electrophysiology and transmissionelectron microscopy analysis indicate that hair cells were degeneratingin these deafanimals.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

DNA isolation and sequencing
pCO8, an incomplete cDNA clone from rat otospiralin, was found by systematic sequencing (Soto-Prior et al., 1997). To obtainthe 5' end of the rat otospiralin mRNA, we screened by PCR a cDNAphage library (G. Rebillard, unpublished results) using vectorprimers and a specific primer from the 5' end of the pCO8 cDNA(Soto-Prior et al., 1997). The resulting cDNA fragment was clonedinto pBluescript SK(+). For human and mouse otospiralin mRNAs,we PCR-amplified a 1.2 kb-long fragment from genomic DNA usingforward hgSG6S1 5'-ATGCAGCC-CTGTCTGCTGTGGTGG-3' and reverse hgSG6AS15'-GTCCTCCTG-GTAGGGAACATGGAA-3' primers from both ends of therat open reading frame and deduced the cDNAs by comparison withthe rat sequence. For the guinea pig otospiralin mRNA, we PCR-amplifieda 160 bp-long cDNA from genomic DNA in the 3' region conservedamong otospiralin orthologs with the forward hgSG6S2 5'-CATGCCTTACT-GGCCTTTTTCCACCTCTGA-3'and reverse hgSG6AS1 primers. This cDNA was digoxigenin labeled(DIG High Prime Labeling and Detection Kit, Boehringer Mannheim,Mannheim, Germany) and hybridized overnight at 68°C to membranereplicates of a guinea pig organ of Corti library (Wilcox andFex, 1992). Positive colonies were then amplified, and plasmidswere isolated. Rat and guinea pig cDNA clones and mouse genomicfragments were sequenced using the PRISM Ready Reaction Big dyeterminator cycle sequencing kit on an ABI 310 DNA Sequencer (PerkinElmerLife Sciences, Emeryville,CA).

Northern blot
Ten micrograms of total RNAs were extracted (Chomczynski and Sacchi, 1987) from 21-d-old rat organs including brain, cerebellum,cochlea, eye, kidney, liver, muscle, and testis. Extracts wereelectrophoresed in a 0.8% agarose formaldehyde gel and transferredto a neutral nylon membrane in denaturing conditions (Löw andRausch, 1994). After linearization of the plasmid, digoxigenin-labeledriboprobes were synthesized (SP6/T7 DIG RNA labeling kit, BoehringerMannheim) according to the manufacturer's instructions and hybridizedto the blot overnight at 68°C. As a control for RNA degradation,the blot was stripped and hybridized with a digoxigenin-labeledglyceraldehyde-3-P dehydrogenaseriboprobe.

In situ hybridization
Rat cochleas and vestibular end organs were removed and fixed as described previously (Knipper et al., 1998), embedded inOCT, and cut in 14 µm cryosections. Sense and antisense riboprobeswere obtained as described above (Northern blot), mixed with thehybridization buffer (Amersham Biosciences, Braunschweig, Germany)containing 50% formamide, and hybridized to slides overnight at55°C. The sections were washed twice in 0.1× SSC at 55°C for 30min and processed for digoxigenin immunodetection following themanufacturer's instructions (Roche Biochemicals, Mannheim,Germany).

Antibody production
The N terminus of the mature, cleaved rat otospiralin (NH₂-KPTPEEADPNAQ-COOH) was coupled to KLH and injected into rabbitsfor antisera production (Eurogentec, Seraing, Belgium). AntiserumSE1657 was obtained, and its specificity was checked by immunoblotanalysis using the preimmune serum as a negativecontrol.

Western blotting
Tissues were harvested in cold PBS and homogenized in sample buffer (Laemmli, 1970), and the lysates were centrifuged to removedetergent-insoluble material and separated on a 16.5% SDS-PAGEin Tris/Tricine (Schägger and Von Jagow, 1987). After gel electrophoresis,proteins were transferred electrophoretically to nitrocellulosemembranes. Blots were incubated with SE1657 anti-otospiralin antibodydiluted at 1:1000 according to Towbin et al. (1979) and visualizedby chemiluminescence using a peroxidase-conjugated secondary antibody(Boehringer Mannheim). Polypeptide range marker was used for calibration(Bio-Rad, Hercules,CA).

Immunohistochemistry
For cochleas, 21-d-old rats were decapitated under deep anesthesia (Nembutal, 50 mg/kg), and their cochleas were quickly removed,pierced at their apex, and fixed overnight in 4% paraformaldehyde.They were then decalcified for 4 d in 10% EDTA, dehydrated inethanol, cleared, and embedded in paraffin. Paraffin sections(7 µm) were deparaffinized, blocked in 30% goat serum, and incubatedwith SE1657 anti-otospiralin antiserum diluted at 1:400. Boundprimary antibodies were revealed by colorimetry using immunoperoxidase-conjugatedsecondary antibody (1:100) following the manufacturer's instructions(Vector). For vestibules, 21-d-old rats were transcardially perfusedwith 4% paraformaldehyde and processed as described (Sage et al.,2000). Vibratome sections (50 µm) were incubated with SE1657 anti-otospiralinantibody diluted at 1:200. Bound primary antibodies were detectedusing Texas Red-conjugated anti-rabbit IgGs diluted at 1:200 (JacksonImmunoResearch, West Grove, PA). Sections were observed undera Bio-Rad MRC1024 laser scanning confocal microscope equippedwith a 40× oil-immersion objective lens of numerical aperture1.4.

Morphological studies
For each of two animals, morphological investigations were performed on the right antisense oligonucleotide-treated cochleaand on the left untreated cochlea as a control. After the lastelectrophysiological test, animals were heavily anesthetized,and the cochleas were removed quickly and perfused with a freshlyprepared fixative containing 3.5% glutaraldehyde in sodium cacodylatebuffer (0.1 M), pH 7.2. They were rinsed in cacodylate buffer,post-fixed in 2% osmic acid for 2 hr, rinsed twice again beforedehydration, and embedded in Spurr resin at 70°C. Blocks weretrimmed to separate the different cochlear coils and remountedfor transverse sections. Semithin sections were examined in Nomarskioptics before thin sections (80-100 nm) were cut using a Leica-Reichertultra-microtome. Grids, counterstained with uranyl acetate andlead citrate, were observed using a transmission electron microscope(Hitachi 7100). Three series of sections were taken from eachblock (two blocks per coil) so as to thoroughly examine at leastsix different levels of organ of Corti percochlea.

Antisense oligonucleotides
A 14-mer phosphorothioate oligonucleotide (cobAS6 5'-CAGTAGGG-CATGGC-3') corresponding to nucleotides c.116-c.103 of guineapig otospiralin cDNA sequence was synthesized and PAGE-purifiedfor the antisense experiments. As a control, we synthesized asecond oligonucleotide with the same base composition in whichthe position of 4 nucleotides were permutated (cobAS6R 5'-ACCTAGGGGATGGC-3').

Otospiralin downregulation in rats
Two rats were anesthetized intraperitoneally with 0.3 ml/kg of sodium pentobarbital at 6% (Sanofi, Montpellier, France). Theright bulla containing the cochlea and the middle ear was openedthrough a posterior auricular surgical procedure, and a gel foam(Gelita tampon, Braun) loaded with 2.5 µl of a 600 µM antisenseoligonucleotide solution was placed in the middle ear. Compoundaction potentials (CAPs) were recorded from an electrode placedon the round window 4 d after the antisense treatment. Rats werekilled at 5 d, and expression of otospiralin was examined in Westernblot.

Surgery for otospiralin downregulation in guinea pigs
Guinea pigs were anesthetized as above, and the vital parameters were tightly controlled (rectal temperature maintained at38 ± 1°C and heart rate monitored via EKG electrodes). The rightbulla was postauricularly approached and opened to expose thecochlea, and a recording electrode was applied on the bony edgeof the round window to prevent direct damage of the window membrane.A 0.2 mm diameter hole was then gently drilled in the basal turnof the scala tympani (2 mm below the round window). A ring ofglue was put on the tip of a glass pipette (0.1 mm diameter),and the tip was inserted into the hole using a micromanipulatoruntil the ring of glue gave a leak-proof seal between the pipetteand the cochlea, i.e., at 0.5 mm from the tip. The pipette wasconnected via a polyethylene tubing to an osmotic minipump (No.2001, Alzet Corporation, Palo Alto, CA) filled with oligonucleotidesdiluted in perilymph and placed under the skin of the back ofthe animal. A reference electrode placed in the neck muscle andthe round window electrode were soldered to a plug fixed on theskull. The perfusion was performed for 7 d at a rate of 1 µl/hr,delivering a total amount of 10 nmol ofoligonucleotides.

Guinea pig electrophysiology
Compound action potential of the auditory nerve. Tone bursts with a 1 msec rise/fall time and an 8 msec total duration generatedby an arbitrary function generator (type 9100R, Lecroy Instruments)were used to elicit CAPs. The signals were passed through a programmableattenuator and presented to the ear in free field via a JBL 075earphone. Nine frequencies (2, 4, 6, 8, 10, 12, 16, 20, and 26kHz) were examined, with each frequency increasing levels in 5dB steps from 0 to 100 dB sound pressure level (SPL) at a presentationrate of 10 bursts per second. Cochlear responses were amplified(gain 2000) by a differential amplifier (Grass P511K), and thesignals were filtered (bandpass 100 Hz-3 kHz) and averaged (256tests) on a PC Pentium computer, 100 MHz (Dell Dimension). Thesampling rate of the analog to digital converter was 50 kHz, witha dynamic range of 12 bits and 1024 samples per record. CAPs weremeasured peak-to-peak between the negative (N1) and the followingpositive value (P1). The thresholds were defined as the levelof dB SPL needed to elicit a measurable response range from 2to 5 µV.
Distortion product acoustic emissions. Distortion product acoustic emissions (DPOAEs) were recorded using the CUBeDIS system.Continuous pure tones were elicited (f2/f1 = 1.2; intensity off1 = f2 = 60 dB SPL reference 2.10-5 Pa; f2 varying between 20kHz and 2 kHz with 4 points per octave) and recorded with a three-channelacoustic probe (ER-10C, Etymotic Research) placed in the externalauditory canal. The acoustic signal was amplified by a preamplificator(ER-10C DPOAE probe driver preamp, Etymotic Research), and datawere analyzed with the CUBeDISsoftware.
Endocochlear potential measurement. after a ventrolateral approach of the cochlea, the bone over the basal turn scala mediawas shaved to perform a small fenestra through the thinned bone.A glass microelectrode filled with 3 M KCl and connected to adirect current amplifier (model KS-700, World Precision Instrument)was passed through the fenestra and into the scala media to recordthe endocochlearpotential.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Otospiralin is a novel inner ear protein

Part of the otospiralin mRNA was initially identified by systematic sequencing of a rat cochlea cDNA library (Soto-Prior etal., 1997). Using this sequence information, we screened cDNAlibraries and PCR-amplified genomic DNA to obtain the full-lengthmRNA sequences of human (AY062256), rat (AY062254), mouse (AY062257),and guinea pig (AY062255) otospiralin, and found in ExpressedSequence Tag databases that of bovine (BE722880) species. ThesemRNAs encode an 89 amino acid-long polypeptide except for theguinea pig, which lacks the 28th amino acid (Fig. 1A). In allspecies the protein has a 21 amino acid-long peptide signal showingcharacteristic uncharged and hydrophobic residues. In addition,the AXA peptidase consensus (Folz et al., 1988) is present inhuman, bovine, rat, and mouse sequences. Cleavage of this signalpeptide leaves a 68-residue mature protein (67 in guinea pig)that is hydrophilic on average (Fig. 1B), with no evidence ofeither transmembrane domain or glycophosphatidyl inositol anchoragesequence, indicating that it is likely to be secreted.

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Figure 1. Sequence of human otospiralin compared with mammal and fish orthologs; hydropathic profile. A, The human otospiralin amino acid sequence is shown aligned with bovine, guinea pig, rat, mouse, and tetraodon sequences. Only changed amino acids are indicated in nonhuman sequences. Conserved amino acids in all six sequences are depicted in gray. The question mark indicates that the putative N-terminal sequence of tetraodon (until amino acid 32) is unknown. The signal peptide is boxed, and the 12 amino acid stretch homologous with the p30 core shell nucleocapsid protein from retroviruses is underlined. Peptide 1657 used for antibody production is underlined in the rat sequence. B, Hydrophobicity profile of human otospiralin according to Kyte and Doolittle (1982) analyzed with a window of 17. N-terminal hydrophobic domain corresponds to the signal peptide.

The overall identity of the uncleaved human otospiralin with the four other mammalian species ranges from 87.6% (bovine) to79.8% (mouse). However, most of the mature, cleaved protein ishighly conserved, in particular residues 35-50 with 100% identityand residues 58-86 with 100% similarity (only three conservativechanges). We found an additional protein sequence translated fromthe Tetraodon nigroviridis fish genomic clone AL267179 thatappears as an N-terminal-truncated otospiralin ortholog sequence(Fig. 1A). Comparison with the human otospiralin reveals thatthe most conserved region is also located between residues 35and 50 (87.5% identity). In addition, in this stretch, residues39-50 are similar to a motif found in the p30 core shell nucleocapsidprotein (GAG polypeptide) from the endogenous type C retroviruses,the function of which is presentlyunknown.

Otospiralin is produced by mesenchymal inner ear fibrocytes

Because adult human cochlear tissue was not available, we studied the mRNA and protein expression of otospiralin in the rat.Northern blot analysis revealed a single 0.62-kb-long mRNA stronglyexpressed in the cochlea (Fig. 2A) but absent in brain, cerebellum,eye, kidney, liver, muscle, and testis. Western blot analysisof cochlear extracts disclosed a 6.4 kDa product detected as earlyas postnatal day (P) 4 and gradually increasing until P16 (Fig.2B). It was consistently found at the adult stage (data not shown).Otospiralin was also detected in the vestibule (Fig. 2C) but wasabsent from various parts of the brain (olfactory bulb, diencephalon,striatum, hippocampus, cortex, cerebellum), from cochlear nerveand nucleus, and from spinal cord, eye, muscle, heart, liver,kidney, spleen, testis, lung, small intestine, thyroid, and skin(Fig. 2D) (data not shown). Otospiralin is thus strictly confinedto cochlear and vestibular peripheral organs.

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Figure 2. Otospiralin is inner ear specific and expressed from P4 in rats. A, Northern blot hybridized to a digoxigenin-labeled antisense riboprobe (pCO8) spanning the whole coding sequence of rat otospiralin. Ten µg/lane of total RNA from rat tissues were loaded as follows: 1, brain; 2, cerebellum; 3, eye; 4, kidney; 5, cochlea; 6, liver; 7, muscle; 8, testis. A single 0.62 kb mRNA is visible in the cochlea. The bottom panel shows the same blot hybridized with a G3PDH riboprobe with a 1.4 kb mRNA in every tissue. B, Western blot with rat cochleas at various postnatal (P) stages indicated above each lane and incubated with SE1657 anti-otospiralin antiserum. A 6.4 kDa signal is detectable from P4 and progressively increases until P16. C, Western blot as in B shows expression of otospiralin in vestibule (1) and cochlea (2). D, Western blot as in B with various rat tissues. 1, Cochlear nucleus; 2, cochlear nerve; 3, cochlea; 4, spinal cord; 5, muscle; 6, eye; 7, cerebral cortex; 8, cerebellum; 9, diencephalon; 10, olfactory bulb.

To determine which cell type produces otospiralin in the inner ear structures, we performed in situ hybridization on rat tissues.In the cochlea, numerous cells from the spiral ligament residingbehind the stria vascularis and from the spiral limbus expressedthe mRNA (Fig. 3A). The glial cells surrounding the spiral ganglionneurons also expressed the mRNA but to a lower level than thespiral ligament and spiral limbus. In the vestibule, the mRNAwas present in cells located to the stroma underlying the utricleand crista sensory epithelia, around vestibular nerve fibers (Fig.3F). It was also present in the cristae beneath the transitionalepithelium and dark cell areas, and in the subepithelial zoneof the walls of semicircular canals (Fig. 3C) and maculae. Nosignal was observed in the dark cells. In both the cochlea andvestibule, no mRNA was detected in the sensory cells or the endolymph-producingcells.

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Figure 3. Expression of otospiralin in rat cochlea and vestibule. In situ hybridization (A, C, F) and immunohistochemistry (B, D, E, G, H) of cochlea (A, B), utricle (C, D), and crista and semicircular canal (F, G, H). In the cochlea (A), digoxigenin-labeled antisense riboprobe (pCO8) hybridized to tissue sections shows otospiralin mRNA in fibrocytes of spiral limbus and spiral ligament, and to a lesser extent in glial cells from the spiral ganglion. In the vestibule (C, F), the same probe detects the mRNA in fibrocytes from subepithelial regions of the utricle (C) and crista (F). Otospiralin mRNA is also present in cells of the semicircular canal walls (F, arrow). In the cochlea (B), SE1657 antiserum detects otospiralin in fibrocytes of the spiral limbus, spiral ligament, and suprastrial zone. No protein is found in the spiral ganglion, organ of Corti, or stria vascularis. In the vestibule, otospiralin is detected in the stroma beneath the sensory epithelia of the utricle (D) and cristae (H). In the utricular and semicircular canal walls (G), fibrocytes are immunostained. The stained fibroblasts have a stellar (E) or elongated (G) shape. Scale bar, 20 µm. DC, Dark cell area; GS, spiral ganglion; L, spiral limbus; OC, organ of Corti; RM, Reissner's membrane; SE, sensory epithelium; SL, spiral ligament; SV, stria vascularis; TE, transitional epithelium.

Expression studies of the protein by immunohistochemistry were compared with the results of in situ hybridization. As expected,in the cochlea, cells from the spiral ligament and spiral limbuswere intensely stained (Fig. 3B). However, glial cells from thespiral ligament were unstained, indicating that they do not produceotospiralin (Fig. 3B). In the vestibule, the immunostaining wasobserved in cells located to the stroma below the macular andcrista sensory epithelia and in the subepithelial layer of thewalls of semicircular canals and maculae (Fig. 3D,G,H), matchingthe mRNA expression found by in situ hybridization. In both organs,the immunostained cells appeared as fibrocytes that display aheterogeneous morphology from stellar to elongated shapes (Fig.3E,G).

Otospiralin downregulation causes vestibular syndrome and deafness

To downregulate the expression of otospiralin in the inner ear, we used antisense oligonucleotides directed against the otospiralinmRNA. In a first set of experiments in rats, a piece of gel foamloaded with oligonucleotides (1.6 nmol in 2.5 µl) was placed directlyon the round window, allowing for the diffusion to the cochleaand vestibule. A vestibular syndrome (head tilt) was first observable2 d after the surgery and became prominent at 4 d after surgery,with a head tilt (45° on the side of the operated ear) and a waltzingbehavior (animals circling around the side of the operated ear).In addition, the rats showed an increased threshold of 40-60 dBSPL across frequencies (data not shown). As seen in Western blot,the cochlea from the treated ear of one rat harvested 5 d afterapplication of oligonucleotides contained significantly less otospiralinthan that of the untreated ear (Fig. 4A), whereas the Coomassieblue protein patterns were similar in both ears. This indicatedthat the antisense treatment of otospiralin mRNA specificallydownregulated the otospiralin protein.

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Figure 4. Downregulation of otospiralin leads to deafness. A, Coomassie blue-stained SDS-PAGE (1, 2) and Western blot (3, 4) incubated with SE1657 anti-otospiralin antiserum. Extracts from the right cochlea treated with antisense mRNA oligonucleotides (1, 3) and from the left untreated cochlea (2, 4) of the same rat were analyzed. As shown on Coomassie blue-stained gel, equal amounts of material from both cochleas were loaded, but much less otospiralin was detected in the treated cochlea as compared with the untreated one. B, Intracochlear application of 10 nmol of antisense oligonucleotide directed against otospiralin for 7 d in guinea pigs via an osmotic minipump. Diagram shows the compound action potential (CAP) thresholds in dB SPL plotted with the frequency from one animal. There is an elevation of the CAP threshold of the auditory nerve 2 d after the perfusion start (Day 2). Virtually no CAP could be measured at Day 5. C, Guinea pig treated as in B with 10 nmol of oligonucleotides of the same base composition but differing by permutations of four nucleotides. There is no significant effect on the CAP thresholds. D, Same guinea pig as in B. Diagram shows the amplitude of the distortion product otoacoustic emissions (DPOAEs) plotted with the f2 frequency. The DPOAE amplitudes decreased at Day 1 and fell into the noise floor at Day 3. E, Same guinea pig as in C. There is no effect on the DPOAE audiogram during the time course of the perfusion and up to 1 month after the micropump implantation.

To further examine the implications of the loss of otospiralin, we used guinea pigs, because cochlear perfusion was not possiblein rats. Using an osmotic minipump, we perfused the right cochleaof six animals for 7 d with a total of 10 nmol of antisense oligonucleotides.The CAP audiogram was measured before and after 1, 2, 3, 5, 10,15, and 30 d after minipump implantation in awake animals. Thevariance analysis and Newman-Keuls multiple range test showeda significant change in the CAP thresholds the first day afterthe beginning of cochlear perfusion in the high-frequency sideof the audiogram, extending to all frequencies on the followingdays in all six animals (Table 1). In four of six animals, theCAPs were irreversibly abolished within the time course of theperfusion (Fig. 4B). By contrast, the cochlear perfusion of fourguinea pigs with an oligonucleotide of the same base compositionas the antisense one but differing by permutations of four nucleotidesdid not result in any significant change in the CAP thresholds(Table 2, Fig. 4C).


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Table 1. Mean threshold shift and SE during application of antisense otospiralin oligonucleotides


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Table 2. Mean threshold shift and SE during application of random oligonucleotides

To assess possible effects of otospiralin downregulation on outer hair cell physiology, we measured the distortion productsof acoustic emissions that are generated by the active mechanisms(electromotility) of these cells. From the three tested animalsperfused with the antisense oligonucleotide, the amplitude ofthe 2f1-f2 distortion product was decreased on day 1 after perfusionand fell into the noise floor by day 3, whatever the pace of theCAP threshold increase, indicating that outer hair cells werenot functioning (Fig. 4D). In three control animals, the amplitudeof the 2f1-f2 product remained unchanged during the time courseof the perfusion (7 d) and up to 1 month after the micropump implantation(Fig. 4E). In one deaf animal after 5 d of perfusion, the endolymphaticpotential was measured and found to be normal (i.e., +86 mV),suggesting that deafness was not caused by the lack of potassiumin the endolymph but, taking into account the profound deafnessand absence of distortion products, by a loss of hair cellfunction.

Deafness is caused by degeneration of hair cells

Both cochleas from two guinea pigs with abolished CAPs were examined by electron microscopy. The first deaf guinea pig waskilled after 5 d of perfusion. All sections randomly made allover the cochlear spiral from the antisense-treated side showeda severe degeneration of the organ of Corti, accounting for theabsence of responses at all frequencies. By contrast, the tectorialmembrane and the stria vascularis, often involved in early degeneratingprocesses, were not affected. The spiral ligament and spiral limbusstructures were also preserved, but fibrocytes were damaged. Insemithin sections, the organ of Corti appeared as a compact epitheliumin which the tunnel and other spaces were filled by cellular materialwith no distinguishable hair cells or Deiters' cells (Fig. 5A),whereas the contralateral organ of Corti from the untreated sidedid not show any lesion (Fig. 5B). Thin sections of the treatedcochlea observed in transmission electron microscopy revealedvirtually no outer hair cells or supporting cells but a denselypacked cellular material, with pieces of outer pillars, and someapoptotic nuclei (Fig. 5D). On the luminal side, remnants of theouter hair cell cuticular plates and stereocilia were sparse.The inner hair cell area was slightly less damaged. In some places,close to a twisted inner pillar and a hypertrophied phalange cell,inner hair cells were still identifiable, but the cuticular platesbore abnormal stereocilia (Fig. 5C). A striking feature, foundin some sections, was the presence of an abnormal cell type withinthe inner spiral bundle sending processes interposed between afferentneurites and inner hair cells. Auditory nerve endings, after losingtheir target, were seen reaching the lumen (Fig. 5C). In the spirallimbus and spiral ligament from the treated cochlea, fibrocytesshowed cytoplasmic vacuolization and shrinkage accompanying chromatincondensation in the nucleus (Fig. 5E), whereas fibrocytes fromthe untreated cochlea remained normal (Fig. 5F). The second guineapig became deaf at the end of the perfusion time course (7 d)and did not show any sign of functional restoration in the followingweeks. It was killed at day 30 after implantation. Degenerationof the organ of Corti with the same features as in the primaryanimal was also observed (data not shown). We concluded that theloss of otospiralin was dramatically affecting the organ of Corti,with some damage to spiral ligament and spiral limbus fibrocytes.

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Figure 5. Degeneration of hair cells and organ of Corti in guinea pig cochleas with downregulated otospiralin. The top panel shows semithin (3 µm) sections at the base of the second turn of the organ of Corti from antisense oligonucleotide-treated (A) and untreated (B) cochleas of the same guinea pig. As compared with the normal side, the organ of Corti in A is totally degenerated. At this magnification, only remnants of the pillars (arrowhead) are recognizable underneath a normal-looking tectorial membrane. The untreated side in B shows the normal organ of Corti, with one inner hair cell (i) and three outer hair cells (o) on each side of the pillars forming the tunnel of Corti (asterisk). Scale bar, 30 µm. The middle panel shows transmission electron micrographs at the level of the organ of Corti from the antisense oligonucleotide-treated cochlea. C, The dark cytoplasm of a degenerating inner hair cell (i) is recognizable, together with remnants of its stereocilia (arrowhead). Nerve endings (auditory dendrites) still surround the cell body split in two parts in this section. However, as shown in higher magnification (inset), a thin process from a supporting cell, possibly glial (thin arrows), separates the inner hair cell from neurites, preventing synaptic contact. Note the twisted inner pillar (dotted line) and a hypertrophied phalangeal cell (p). D, On the outer hair cell side, neither outer hair cells nor Deiters' cells are recognizable. Only remnants of the outer hair cell cuticular plates and stereocilia (arrows) can be distinguished on the top of a compact epithelium. The outer pillar is broken, and its twisted route can be followed up to the head of the inner pillar (dotted line). The space of the tunnel of Corti (t) is filled with cellular material. One apoptotic nucleus is shown (curved arrow). Scale bars, 5 µm. Bottom panel shows transmission electron micrographs at the level of the spiral limbus from the antisense oligonucleotide-treated (E) and untreated (F) cochleas from the same guinea pig. E, Fibrocytes show severe degenerating changes with retraction and vacuolization of the cytoplasm and nucleus resembling the first stage of apoptosis. F, Fibrocytes have a normal appearance, although cytoplasm retraction is sometimes observed. Scale bars, 5 µm.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We report on the discovery of otospiralin, a small inner ear-specific protein produced by fibrocytes of the spiral ligamentand spiral limbus in the cochlea and subepithelial regions ofthe maculae and semicircular canals in the vestibule. Severalfeatures indicate that otospiralin is involved in a dedicatedfunction of the inner ear fibrocytes that must be important forcochleovestibular physiology. Indeed, otospiralin is specificfor the inner ear. In addition, downregulation of otospiralinin guinea pigs causes a rapid and severe degeneration of the organof Corti leading to an irreversible deafness. Elucidation of thefunction of otospiralin will thus help in deciphering the rolesof these intriguingfibrocytes.

Analysis of the sequence of otospiralin shows that this novel protein does not match any well characterized protein, exceptfor a small part (12 residues) that is homologous to a motif presentat the N-terminal end of the p30 core shell nucleocapsid protein(gag) from type C retroviruses. Remarkably, these 12 residuesare part of the 16 amino acid stretch that is very conserved infish and mammals, suggesting that this region is of primary importancefor the function. p30 is necessary for virion assembly (Schwartzberget al., 1984), and mutations in a conserved domain located inthe central region of the protein lead to a loss of the infectioncapacity (Miller and Verma, 1984). The function of the N-terminalend of p30 remains unknown, however. Mutagenesis experiments inthis part of p30 addressing the question of its role in retroviralinfection may be of help in understanding the function ofotospiralin.

The decrease in otospiralin content of the inner ear causes loss in cochlea sensitivity, as shown by the dramatic increasein the CAP thresholds and also by the absence of acoustic otoemissionsthat more specifically reflect outer hair cell dysfunction. Examinationof the cochleas in electron microscopy revealed that outer haircells and, for the most part, inner hair cells disappeared. Thereare many situations in which hair cells degenerate. Loss of thesecells occurs in acoustic trauma (Spoendlin and Braun, 1973) andin ototoxic drug administration (Hawkins, 1959) in a dose-dependentmanner (Lenoir and Puel, 1987). In addition, genetic defects affectingstereocilia (Osako and Hilding, 1971; Shnerson et al., 1983; Sjöströmand Anniko, 1990; Probst et al., 1998; Self et al., 1999; Alagramamet al., 2000; Littlewood Evans and Müller, 2000; Zheng et al.,2000) and ion transport in hair cells (Street et al., 1998) orin stria vascularis (Vetter et al., 1996; Delpire et al., 1999)cause the degeneration of the organ of Corti. The pace at whichhair cells and supporting cells in the organ of Corti degenerateis variable, being as short as 1-2 weeks in disorders affectingprimarily the stria vascularis (Vetter et al., 1996; Delpire etal., 1999). In this latter case, a collapse of tectorial and Reissnermembranes over the organ of Corti is observed that could acceleratethe degenerating process. In the present study, the otospiralindeprivation must have been highly insulting because most of thehair cells were lost by 5 d after the beginning of the antisensetreatment in one representativeanimal.

Apart from the presence of an abnormal cell type interposed between neurites and inner hair cells that could correspond toa repair response, which perhaps is characteristic of this pathologicalmodel, the degeneration observed followed a classical pattern,because outer hair cells and supporting structures were more affectedthan inner hair cells. Signs of apoptosis and phalangeal cellhypertrophy as encountered in drug-induced ototoxicity (Lenoiret al., 1999) were also present. There are several pathologicalmechanisms that could generate such a pattern of degeneration.One possibility is that downregulation of otospiralin could causea modification in the endolymph composition. In our experiment,the structures of the stria vascularis and of Reissner and tectorialmembranes were unchanged, suggesting that there was no dramaticchange in production and volume of the endolymphatic compartment.In addition, the normal endolymphatic potential found in one deafanimal suggested that potassium was not lacking. One cannot excludehowever that the absence of otospiralin could change other ionicor non-ionic components of the endolymph, which would not havea direct effect on fluid circulation in the endolymphatic compartmentbut would perturb hair cell metabolism. A second possibility isthat downregulation of otospiralin could impair hair cell functioningby itself. Indeed, because otospiralin is probably secreted, itcould reach the neuroepithelium and exert its action, either directlyon hair cells or through supporting cells or neurons. Noteworthyis the fact that no abnormality was seen on either afferent orefferent neurites within the organ of Corti or in myelinated fibersand spiral ganglion neurons. Finally, the lack of otospiralincould alter the fibrocytes themselves or their environment, whichin turn may modify important factors for hair cells, or ion homeostasis.The vacuolization of some fibrocytes from the spiral ligamentand spiral limbus, perhaps the otospiralin-producing cells, isrelevant to this hypothesis. Future experiments searching fora receptor or protein partners of otospiralin will help in decidingwhat are its target cells and in deciphering the pathologicalmechanism that occurs in otospiralindeprivation.

Interestingly, some features of otospiralin resemble observations made with cochlin. Cochlin is another putatively secreted,novel inner protein with unknown function expressed in mesenchymalnonsensory tissues surrounding the neuroepithelium in chicken(Robertson et al., 1998). In addition, mutations in the cochlingene cause nonsyndromic human deafness and vestibular dysfunction(Robertson et al., 1998; Fransen et al., 1999). On the basis ofthese observations, we anticipate that genetic defects leadingto otospiralin loss of function could cause human deafness andvestibulardysfunction.

  FOOTNOTES

Received Sept. 19, 2001; revised Dec. 10, 2001; accepted Dec. 10, 2001.

^* B.D. and A.B. contributed equally to this work

B.D. has a fellowship from Caisse d'Epargne, Montpellier and Région Languedoc-Roussillon, France. We are grateful to G. Rebillardand E. Wilcox for providing cDNA libraries. We thank N. Daudet,M. Eybalin, M. Gallego, G. Humbert, and N. Renard for immunohistochemistry,C. Gervais d'Aldin and J. Ruel for their help in physiologicalstudies, and J.-L. Pasquier for artwork.

Correspondence should be addressed to Christian P Hamel, Institut National de la Santé et de la Recherche Médicale U. 254,71 rue de Navacelles, 34090 Montpellier, France, E-mail: hamel{at}montp.inserm.fr.,or Jean-Luc Puel, same address, E-mail: puel{at}montp.inserm.fr.

A. Boulanger's present address: Laboratory of Retinal Cell and Molecular Biology, Building 6, Room 339, National Eye Institute/NationalInstitutes of Health, 6 Center Drive, MSC 2740, Bethesda, MD 20892-2740.

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