Abstract
After noise- or drug-induced hair-cell loss, the sensory epithelia of the avian inner ear can regenerate new hair cells. Few molecular markers are available for the supporting-cell precursors of the hair cells that regenerate, and little is known about the signaling mechanisms underlying this regenerative response. Hybridoma methodology was used to obtain a monoclonal antibody (mAb) that stains the apical surface of supporting cells in the sensory epithelia of the inner ear. The mAb recognizes the supporting-cell antigen (SCA), a protein that is also found on the apical surfaces of retinal Müller cells, renal tubule cells, and intestinal brush border cells. Expression screening and molecular cloning reveal that the SCA is a novel receptor-like protein tyrosine phosphatase (RPTP), sharing similarity with human density-enhanced phosphatase, an RPTP thought to have a role in the density-dependent arrest of cell growth. In response to hair-cell damage induced by noise in vivo or hair-cell loss caused by ototoxic drug treatment in vitro, some supporting cells show a dramatic decrease in SCA expression levels on their apical surface. This decrease occurs before supporting cells are known to first enter S-phase after trauma, indicating that it may be a primary rather than a secondary response to injury. These results indicate that the SCA is a signaling molecule that may influence the potential of nonsensory supporting cells to either proliferate or differentiate into hair cells.
The sensory epithelia of the inner ear contain mechanosensitive hair cells that are surrounded and isolated from each other by nonsensory supporting cells. In the avian basilar papilla, these two cell types derive from a common embryonic lineage (Fekete et al., 1998), and it is thought that the decision to become either a hair cell or a supporting cell is made after the progenitors have left the cell cycle. In the mature bird, the hair cells are postmitotic, and the supporting cells are essentially mitotically quiescent (Oesterle and Rubel, 1993). After noise- or drug-induced hair-cell loss, some of the supporting cells reenter the cell cycle and undergo one or more rounds of cell division, with the progeny then differentiating as either new hair cells or new supporting cells (Corwin and Cotanche, 1988; Ryals and Rubel, 1988; Raphael, 1992,1993; Stone and Cotanche, 1994). Supporting cells in the basilar papilla may also be able to convert directly into hair cells without reentering the cell cycle after hair-cell loss (Adler and Raphael, 1996; Roberson et al., 1996), suggesting there could be two different mechanisms whereby hair cells can be regenerated in the avian inner ear. However, in both cases, the nonsensory supporting cells are considered to be the progenitors for the new hair cells.
Hair-cell damage or loss may be the primary stimulus for the onset of hair-cell regeneration, but little is known about the molecular mechanisms and signaling pathways that underlie this response. Several different growth factors have been shown to stimulate supporting-cell proliferation in cultures of both the avian and mammalian vestibular epithelia (Yamashita and Oesterle, 1995: Oesterle et al., 1997; Zheng et al., 1997), and immunohistochemical studies have indicated that fibroblast growth factor (FGF) receptors rapidly appear on the apical surfaces of supporting cells in the basilar papilla in response to noise trauma in vivo (Lee and Cotanche, 1996). In vitro studies have also shown that activation of a cyclic AMP (cAMP)-dependent protein kinase A-mediated signaling pathway can stimulate a proliferative response in the avian basilar papilla and that protein kinase A inhibitors can block drug damage-induced cell proliferation (Navaratnam et al., 1996). Thus there is evidence that both cAMP and growth factor-mediated pathways can control supporting-cell proliferation, but knowledge of the signaling pathways leading to hair-cell regeneration in vivo is both limited and fragmentary.
We have recently identified a monoclonal antibody (mAb) that selectively stains the apical surface of supporting cells within the sensory epithelia of the inner ear. The antigen recognized by this mAb is referred to as the supporting-cell antigen (SCA), and cDNA cloning reveals that it is a novel receptor-like protein tyrosine phosphatase (RPTP) [for recent reviews on RPTPs, see Neel and Tonks (1997) andStoker and Dutta (1998)]. The potential signaling ability of the SCA and its rapid loss in response to hair-cell damage suggest that it may influence supporting-cell proliferation or hair-cell differentiation in the sensory epithelia of the inner ear.
MATERIALS AND METHODS
Preparation of monoclonal antibody. Lagenar maculae were dissected from the inner ears of 1- to 3-d-old posthatch chicks in PBS (150 mm NaCl, 10 mm sodium phosphate, pH 7.2) containing 2 mm benzamidine, 10 μmpepstatin, 1 μg/ml leupeptin, and 0.1 mmphenylmethylsulfonylfluoride, stored under liquid N2 until required, and used to prepare a crude membrane fraction by differential centrifugation. The membrane fraction was suspended in PBS and used to immunize a BALB/c mouse. The mouse was injected three times at 1 month intervals using the material from ∼250 lagenar maculae for each injection. The mouse was then rested for a period of 5 months, boosted with a membrane fraction prepared from ∼350 lagenar maculae, and 7 d later the spleen was used for the preparation of hybridoma cells using standard techniques (Kohler and Milstein, 1975). Animal procedures were performed in accordance with UK Home Office guidelines. Sp2/O-Ag14 cells were used as the myeloma cell fusion partner, and cells were plated in Costar 24-well plates and selected with hypoxanthine-aminopterin-thymidine growth medium containing 10% Doma Drive (Immune Systems Ltd., Paignton, UK). Culture supernatants were screened by immunofluorescence microscopy on cryosections of formaldehyde-fixed chick inner ear tissues (see below). Clone D37, secreting monoclonal antibodies that recognize the apical surface of supporting cells, was cloned by limiting dilution on three separate successive occasions to yield monoclonal hybridoma cell line D37.19.1.1 secreting mAb D37. Antibody isotype was determined using a mouse mAb isotyping kit (Life Technologies Ltd., Paisley, UK). mAb D37 is an IgG2b class antibody with κ light chains. Concentrations of IgG in tissue culture supernatants were determined by quantitative immunoblotting using mouse IgG2b purified from the ascites fluid of mice carrying plasmocytoma line MOPC 141 (Sigma, Poole, UK) as a standard.
Immunofluorescence microscopy. To prepare cryostat sections for screening hybridoma supernatants, tissues were immersion-fixed in 3.7% formaldehyde in 0.1 m sodium phosphate buffer, pH 7.4, for 1 hr at room temperature, washed three times with PBS, cryoprotected by overnight incubation in PBS containing 30% sucrose at 4°C, and mounted in 1% low melting point agar in PBS containing 18% sucrose. The agar blocks containing the tissue pieces were mounted onto microtome chucks with TissueTek, frozen with Cryospray 134 (Bright Instrument Co. Ltd., Huntingdon, UK), and sections 10 μm in thickness were cut at a temperature of −30°C. The tissue sections were mounted on gelatin-coated Multitest slides (ICN Biomedicals Ltd., Thame, UK) and stored at −20°C until use. Hybridoma supernatants were applied directly to the sections, and the slides were incubated in a humid chamber overnight. The slides were washed three times in Tris-buffered saline (TBS) (150 mm NaCl, 10 mm Tris-HCl, pH 7.4), and bound antibodies were detected by staining sequentially with two layers of FITC-conjugated secondary antibodies, FITC-conjugated rabbit anti-mouse Ig followed by FITC-conjugated swine anti-rabbit Ig (Dako, High Wycombe, UK), both diluted 1:100 in TBS containing 10% horse serum (TBS/HS).
Cryosections for detailed morphological analysis were prepared in the same manner except that 0.025% glutaraldehyde was added to the fixative to enhance tissue preservation, and the sections were preblocked by incubating them in TBS/HS for 1 hr before the addition of the primary antibody. Whole-mount preparations were fixed in 3.7% formaldehyde in 0.1 m sodium phosphate for 1 hr at room temperature, washed in PBS, and then preblocked and permeabilized in TBS/HS containing 0.1% Triton X-100 for 1 hr before use. Polyclonal rabbit antibodies to the tight junction-associated protein cingulin were a kind gift from Dr. Sandra Citi (Universita’ di Padova, Italy) (Citi et al., 1988). These antibodies stain the tight junctions around the apex of the cells and were used to clearly define the boundaries between adjacent cells. Monoclonal IgG1 antibody to the 275 kDa hair-cell antigen (HCA) has been described previously (Richardson et al., 1990). For double labels with monoclonal anti-HCA and mAb D37, after labeling with a mixture of the two hybridoma supernatants both diluted 1:10 in TBS/HS, samples were incubated sequentially in (1) a mixture of FITC-conjugated sheep anti-mouse IgG2b (Serotec, Kidlington, UK) and unlabeled rabbit anti-mouse IgG1 (Zymed, Cambridge, UK), (2) FITC-conjugated donkey anti-sheep Ig (Sigma), and (3) rhodamine-conjugated swine anti-rabbit Ig. For double labels with mAb D37 and rabbit anti-cingulin, after labeling with mAb D37 supernatant (1:10 dilution) containing rabbit anti-cingulin at a dilution of 1:1000, the samples were incubated sequentially in (1) rhodamine-conjugated swine anti-rabbit Ig, (2) FITC-conjugated sheep anti-mouse IgG2b, and (3) FITC-conjugated donkey anti-sheep Ig. To triple-label with mAb D37, monoclonal anti-HCA, and rabbit anti-cingulin, after labeling with a mixture of the two monoclonal supernatants (both at 1:10 dilution) containing rabbit anti-cingulin at a dilution of 1:1000, the samples were incubated sequentially in (1) a mixture of FITC-conjugated sheep anti-mouse IgG2b and unconjugated rabbit anti-mouse IgG1, (2) FITC-conjugated donkey anti-sheep Ig, and (3) rhodamine-conjugated swine anti-rabbit Ig. This procedure enabled the HCA and cingulin to be observed simultaneously through the rhodamine channel and the SCA to be observed through the FITC channel. All secondary antibodies were used at a dilution of 1:100 in TBS/HS. To visualize F-actin, tetramethyl rhodamine isothiocyanate–phalloidin was added to the secondary antibodies at a concentration of 20 ng/ml. To improve permeability of the anti-cingulin and secondary antibodies in whole mounts, all solutions additionally contained 0.1% Triton X-100. As a control for the immunofluorescence procedure with mAb D37, samples were stained with an irrelevant mouse IgG2b (MOPC 141) at a concentration of 5 μg/ml, a concentration 2.5-fold higher than that present in the diluted mAb D37 tissue culture supernatant.
Immunoelectron microscopy. Inner ear and eye tissues were dissected in PBS and immersion-fixed in 3.7% formaldehyde/0.025% glutaraldehyde in 0.1 m sodium phosphate buffer for 1 hr at room temperature. Tissue samples were then washed three times with PBS, preblocked with TBS/HS for 1 hr, and incubated in mAb D37 tissue culture supernatant (1:10 dilution) overnight at 4°C. Samples were then washed extensively with TBS/0.05% Tween, incubated in rabbit anti-mouse IgG2b diluted 1:100 in TBS/HS/0.05% Tween overnight at 4°C, washed again with TBS/0.05% Tween, and incubated in 10 nm gold-conjugated rabbit anti-mouse Ig (British BioCell International Ltd., Cardiff, UK) overnight at 4°C. After gold labeling, samples were washed five times with TBS/0.5% Tween, five times with PBS, fixed with 2.5% glutaraldehyde in 0.1 msodium cacodylate buffer, pH 7.4 for 1 hr, washed with cacodylate buffer, and post-fixed with 1% OsO4 in 0.1 msodium cacodylate buffer for 1 hr. Samples were then washed briefly in H2O, dehydrated through a series of ascending concentrations of ethanol, equilibrated with propylene oxide, and embedded in Epon 812 resin. Blocks were cured for 2 d at 60°C and sectioned at a thickness of 90 nm. Sections were counterstained with uranyl acetate and lead citrate and viewed in a Hitachi transmission electron microscope. Samples incubated either in hybridoma medium that had not been used for cell growth or irrelevant monoclonal supernatant (mAb E40) (Goodyear and Richardson, 1999) diluted 1:10 were used as controls for the immunogold-labeling procedure.
Western blotting. Frozen tissue samples were thawed on ice, homogenized, and sequentially extracted in 1 ml vol of ice-cold TBS, high-salt buffer (1.0 m NaCl, 10 mm Tris-HCl, pH 7.4), low-salt buffer (10 mm Tris-HCl, pH 7.4), and Triton X-100 (1% Triton X-100 in 10 mm Tris-HCl, pH 7.4). All buffers contained a mixture of protease inhibitors (2 mm benzamidine, 10 μm pepstatin, 1 μg/ml leupeptin, 1 mm phenylmethylsulfonylfluoride, and 2 mmN-ethyl maleimide). The homogenates were centrifuged for 15 min at 100,000 rpm in a TLA100 rotor using a Beckman TLS benchtop ultracentrifuge to produce soluble, high-salt-soluble, low-salt-soluble, Triton X-100-soluble, and insoluble fractions. The soluble, high-salt-soluble, and low-salt-soluble fractions were precipitated by adding TCA to a final concentration of 20% and leaving them on ice for 30 min. The Triton X-100-soluble fraction was precipitated by adding 9 vol of cold acetone and holding it at −20°C for 30 min. Precipitated proteins were collected by centrifugation, solubilized in reducing SDS-PAGE sample buffer, boiled for 4 min, and run on 7.5% acrylamide gels. To visualize proteins the gels were stained with Coomassie brilliant blue. For immunoblotting, the separated proteins were transferred to nitrocellulose by semi-dry electrophoresis. The nitrocellulose blots were preblocked with 3% Marvel in TBS containing 0.05% Tween for 1 hr, incubated overnight with rabbit antibodies (1:100 dilution in preblock solution) or mAb D37 supernatant, washed with TBS/0.05% Tween, and then incubated in alkaline phosphatase-conjugated rabbit anti-mouse Ig or alkaline phosphatase-conjugated goat anti-rabbit Ig for 2 hr. After washes with TBS/0.05% Tween, blots were rinsed briefly with alkaline phosphatase buffer (0.1 m NaCl, 0.05 mMgCl2, 0.1 m Tris-HCl, pH 9.5) and reacted with alkaline phosphatase buffer containing 0.34 mg/ml nitroblue tetrazolium and 0.175 mg/ml 5-bromo-4-chloro-3-indolyl phosphate. Tissue culture supernatants containing irrelevant monoclonal antibody (mAb E40) (Goodyear and Richardson, 1999) or rabbit preimmune serum diluted 1:100 were used as controls for the immunoblotting procedures.
Preparation of a chick intestine cDNA library.Poly(A)+ RNA was prepared from the small intestine of 2-d-old posthatch chicks using a Quick-Prep micro kit (Pharmacia, Milton Keynes, UK). First-strand cDNA synthesis was primed with a mixture of random hexamers (Promega, Southampton, UK). The resultant single-strand cDNA was rendered double-stranded and, after the addition of EcoRI adaptors, ligated into the EcoRI site of the λ Zap II vector (Stratagene, Cambridge, UK). The cDNA library was amplified before screening.
Isolation of cDNA clones. A total of 1.5 × 106 clones was immunoscreened with mAb D37 using alkaline phosphatase-conjugated goat anti-mouse IgG to detect immunopositive plaques. A single phage clone was isolated through three successive rounds of immunoscreening and converted to a plasmid (pBluescript SK+) by helper phage rescue. Additional clones encoding the entire open reading frame were isolated by high-stringency screening with 32P-labeled DNA probes (see below) derived from the initial immunopositive clone by PCR amplification with sequence-specific primers.
Preparation of 32P-labeled probes. PCR products were generated from cDNA clones, separated by gel electrophoresis, purified from the gel using GeneClean (Stratatech Scientific, Luton, UK) and random primer-labeled (Feinberg and Vogelstein, 1984) with α32P-dCTP using a MegaPrime labeling kit (Amersham International, Little Chalfont, UK). Unincorporated label was removed using Sephadex G50 columns (Pharmacia), and the probes were denatured before they were added to the hybridization mix.
DNA sequencing and analysis. Double-stranded plasmid DNA was prepared using Wizard Plus minipreps (Promega) and sequenced with T7 DNA polymerase by the dideoxy-chain termination method of Sanger et al. (1977) using T3, T7, and specific oligonucleotide primers. Some plasmid DNA samples were also sequenced on an ABI 370A automatic sequencer. Sequence analysis was performed using the DNA Star package (DNA Star, London, UK). Protein and DNA sequence database searches were performed using the BLAST network service at the National Center for Biotechnology Information (Altschul et al., 1997).
Preparation of antibodies to an extracellular domain bacterial fusion protein. Primers with an internal XhoI restriction site (forward F1: CGTACAGGCTCGAGGTTAGGAATGCTACT; reverse R1: CTCCCCTCGAGTTGACTCTGTTGCTT) were used to amplify a 1635 bp fragment from cDNA clone A corresponding to amino acids 294–838 in the extracellular domain of the SCA. The PCR product was separated by gel electrophoresis in a Tris borate-EDTA–agarose gel, recovered from the gel using GeneClean, digested with XhoI, extracted with phenol/chloroform, and precipitated with ethanol. The PCR product was ligated into a XhoI cut, dephosphorylated pET15b vector (Novagen, Abingdon, UK) using T4 DNA ligase, and transformed intoEscherichia coli XL1-blue cells. A plasmid containing the cDNA insert in the correct orientation was transformed into E. coli BL21 cells, and expression of the His-tagged fusion protein was induced with iso-propyl β-d-thiogalactopyranoside. The fusion protein was purified from bacterial lysates using His-bind resin (Novagen), dialyzed against H2O, lyophilized, and resuspended in PBS. A rabbit was immunized with ∼0.5 mg of the fusion protein on four separate occasions at 1 month intervals, using Freund’s complete adjuvant for the first immunization and Freund’s incomplete adjuvant for the later boosts. Antibodies were affinity-purified on a column of the fusion protein coupled to Sepharose 4B (Sigma).
Immunoprecipitation. Triton X-100-soluble fractions were prepared from frozen samples of small intestine, kidney, retina, and utricular maculae as described above for Western blotting using EDTA (2 mm) as an additional protease inhibitor and sodium phosphate (20 mm, pH 7.4) in place of Tris-HCl to buffer the solutions. Protein content of the extracts was determined using the bicinchoninic acid protein assay reagent (Pierce, Chester, UK). Rabbit immune serum to the extracellular domain fusion protein or preimmune serum (4 μl) was added to 400 μl aliquots of the extracts, each containing 72 μg of protein, and the samples were incubated overnight at 4°C. Immune complexes were collected by adding a 20 μl vol of protein A-agarose beads [prepared as a 1:1 (v/v) suspension in the Triton X-100 extraction buffer] and incubating the samples for 1 hr at 4°C on a rotator. The beads were then washed three times with cold PBS containing 1% Triton X-100 and one time with cold PBS and then boiled in a 15 μl vol of reducing SDS-PAGE sample buffer. Aliquots of the eluted samples (10 μl) were run on 7.5% polyacrylamide gels, transferred to nitrocellulose membranes, and immunoblotted with the mAb D37 supernatant as described above.
RT-PCR. Poly(A)+ mRNA was isolated from chick small intestine, kidney, retina, and utricular macula as described above and used to synthesize randomly primed first-strand cDNA using avian myeloblastosis virus reverse transcriptase (Promega). The resultant cDNA was used in RT-PCR reactions with oligonucleotide primer pairs designed to amplify bases 2887–4310 of the cDNA sequence (forward F2: CATATGCTCGAGATGACAGCCACCTATGTGAC; reverse R2: GGATCCTCGAGCTTTCTCATGCACAGACAAC). The 50 μl reactions contained 50 pmol each primer and were hot-started with 4 U of TaqExpress (Genpak Ltd., Brighton, UK) followed by 35 cycles of 94°C for 15 sec, 57°C for 15 sec, and 68°C for 90 sec. The reactions were terminated with a 5 min incubation at 68°C. PCR reactions were analyzed by agarose gel electrophoresis followed by transfer to Hybond-N membrane (Amersham International) and UV cross-linking. Membranes were then hybridized with a 32P-labeled DNA probe derived by PCR of cDNA clone C with primers lying internal to those used for the RT-PCR reactions (forward F3: ACACAATGGAGAGCCACACA; reverse R3: TCCATGACACACTGGTTTAG). Hybridization of the membranes and washing to high stringency were performed as described by the manufacturer (Amersham International). In addition the 1.4 kbp product was purified using GeneClean and directly sequenced on an ABI 370A automatic sequencer to confirm its identity in all four tissues.
Preparation of noise- and drug-damaged auditory papillae.One-week-old chicks were exposed to 120 dB sound pressure level (SPL) octave band noise centered around a frequency of 2.0 kHz for 14 hr and killed 1 hr after the end of the exposure period [see Raphael (1993)for a description of the noise exposure setup]. Also, 2-week-old chicks were exposed to a 900 Hz tone at 120 dB SPL for 12 hr and killed 4 hr after the end of the exposure period [for details, see Cotanche et al. (1995)]. Pieces of skull containing the labyrinth were immersion-fixed as described above, basilar papillae were dissected, and whole-mount preparations were double-labeled with monoclonal anti-HCA and mAb D37, or triple-labeled with monoclonal anti-HCA, mAb D37, and cingulin, as described earlier. Papillae from a total of eight noise-damaged animals and three age-matched controls were examined. The noise exposure procedures and animal handling were approved by the University of Michigan’s Committee on the Use and Care of Animals (UCUCA, approval 6981A) and the Institutional Animal Care and Use Committee at The Children’s Hospital (Boston, MA) and were performed in a manner consistent with the National Institutes of Health Guide for Care and Use of Laboratory Animals.
Basilar papillae from 14-d-old posthatch chicks were dissected in Medium 199 with HBSS and additional HEPES buffer and placed in MatTek culture wells in Medium 199 with Earle’s salts supplemented with 10% fetal bovine serum. To induce hair-cell loss, neomycin was added to a final concentration of either 0.2 or 1.0 mm. Cultures were maintained for 24 hr in vitro at 37°C in an atmosphere of 95% air/5% CO2, washed with serum-free medium, and fixed in 4% paraformaldehyde buffered with 0.1m sodium phosphate, pH 7.2, for 30 min. Cultures were then washed in PBS and prepared for cryosectioning as described above, and 20-μm-thick sections were cut in a plane parallel to the apical surface of the papilla. Sections were triple-labeled for the HCA, SCA, and cingulin as described above. A total of eight papillae exposed to 1.0 mm neomycin, three exposed to 0.2 mmneomycin, and eight unexposed controls were examined.
RESULTS
mAb D37 recognizes a Triton X-100-soluble protein of ∼220 kDa present on the apical surface of supporting cells
Whole mounts of the posthatch basilar papilla double-labeled with mAb D37 and monoclonal anti-HCA reveal that mAb D37 specifically stains the narrow, compacted apical surfaces of the supporting cells that surround each hair cell but not the apical surfaces of the hair cells (Fig. 1a,a′). Cryosections of the cochlear duct that have been double-labeled with mAb D37 and rhodamine– phalloidin show that the apical surface of the basilar papilla is intensely stained by the antibody (Fig.1b,b′). Labeling is also observed on the apical surfaces of the homogene cells and, to a much lower extent, on the lumenal surface of the cells in the tegmentum vasculosum (Fig. 1b). Cryosections also indicate that mAb D37 labeling is restricted to the apical surface of cells in the cochlear duct; staining is not observed on the basolateral membranes of cells in these epithelia. mAb D37 also reacts with the apical surfaces of supporting cells in the vestibular epithelia of the inner ear, where the supporting-cell surfaces are larger and less regular in shape and size than they are in the basilar papilla (Fig. 1c,c′).
The mAb D37 reacts with a protein band of 220 kDa (Fig.2) on immunoblots of protein fractions prepared from the lagenar macula, a vestibular organ found at the end of the cochlear duct. Immunoreactivity is not detected in either the soluble or low-salt-soluble fractions. Traces of immunoreactive protein can be detected in the high-salt-soluble fraction, and a large proportion of the 220 kDa protein is soluble in the nonionic detergent Triton X-100. However, significant amounts of the protein are found in the insoluble fraction that remains after extraction with Triton X-100 (Fig. 2). Because the 220 kDa protein recognized by mAb D37 is localized on the apical surfaces of supporting cells within the sensory epithelia of the inner ear, it is referred to as the SCA.
mAb D37 also recognizes the apical membranes of epithelial cells in kidney, gut, and retina
Cryosections of brain, gizzard, heart, intestine, kidney, liver, lung, skeletal muscle, and retina were screened for immunoreactivity with mAb D37. Staining was not detected in brain, gizzard, heart, liver, lung, or muscle. In the intestine, kidney, and retina strong immunoreactivity was observed (Fig.3b–d). As in the basilar papilla (Fig. 3a), the staining seen in these tissues with mAb D37 is associated with the apical surfaces of the epithelia (Fig.3b–d). In the kidney and intestine, mAb D37 stains the brush borders (Fig. 3b,c), and in the retina it stains the external limiting membrane (Fig. 3d). Specific immunostaining was not observed when cryosections of basilar papilla, kidney, intestine, and retina were stained with an irrelevant mouse IgG2b monoclonal antibody at a concentration 2.5-fold higher than that estimated to be present in the diluted mAb D37 supernatants (Fig. 3e–h).
Immunoelectron microscopy reveals that the epitope recognized by mAb D37 is located on the external surface of the plasma membrane (Fig.4). In the ear, the antigen is associated with the microvillar and nonmicrovillar membrane of the supporting-cell surface (Fig. 4a). The SCA is not present on the kinocilia of the supporting cells (Fig. 4a). In the retina, the SCA is distributed along the microvilli of the Müller cells that surround the photoreceptors to form the external limiting membrane (Fig. 4b). Gold labeling of supporting cell surfaces and Müller cell microvilli was not observed when the primary antibody was omitted or irrelevant mAb supernatant was used in place of mAb D37.
Immunoblots of Triton X-100-soluble fractions prepared from the lagenar macula, kidney, intestine, and retina reveal that mAb D37 recognizes bands of similar but not identical apparent molecular mass in all four tissues (Fig. 5a). The size of the band varies from 205 kDa in the retina to 270 kDa in the intestine, as determined by back-extrapolating from the highest molecular size marker used (myosin, 205 kDa). Single bands are consistently observed in fractions prepared from maculae (220 kDa), retina (205 kDa), and kidney (230 kDa), and up to three bands can be detected in the intestinal fraction (270, 240, 220 kDa). These differences in the apparent molecular mass of the antigen found in the different tissue types are observed consistently from one preparation to another and may result from variations in post-translational modification in the different tissues or from the presence of alternative splice variants.
The supporting-cell antigen is a receptor-like protein tyrosine phosphatase
An immunoscreen of a randomly primed chick intestine cDNA library with mAb D37 resulted in the isolation of a single immunopositive clone, clone A, which is 2.3 kbp in size and contains an uninterrupted open reading frame. A 1635 bp 5′ fragment of this clone was used to generate a bacterial fusion protein of 545 amino acids for the preparation of polyclonal antibodies. The rabbit immune serum directed against this fusion protein stained bands of 205–270 kDa with electrophoretic mobilities the same as those recognized by mAb D37 in Triton X-100-soluble fractions prepared from the lagenar macula, retina, kidney, and intestine (Fig. 5a,b). This rabbit antiserum also stained cryosections of the inner ear, retina, kidney, and intestine in a manner identical to mAb D37 (Fig.5c–f). Although mAb D37 did not react with this fusion protein in immunoblotting (data not shown), the proteins immunoprecipitated from Triton X-100-soluble fractions of lagenar macula, retina, kidney, and small intestine by the polyclonal rabbit serum directed against the fusion protein all reacted with mAb D37 in immunoblots (Fig. 5g). These results provide good evidence that clone A, isolated with mAb D37, encodes the SCA.
Clones encoding the entire open reading frame of the SCA were isolated by screening the library with DNA probes generated by PCR from the 5′ and 3′ ends of clone A. Two additional clones, clones AA and C, were obtained. The three clones provide a composite cDNA sequence of 5515 bp, with an open reading frame of 4218 bp (Fig.6a). The open reading frame encodes a protein of 1406 amino acids (Fig. 6b) with a calculated molecular mass of 154.2 kDa. Database searches show that the SCA is a member of the RPTP family, sharing 49.8% maximal identity with murine Byp (Kuramochi et al., 1996), 48.7% with rat vascular density-enhanced phosphatase-1 (rDEP-1) (Borges et al., 1996), 45.7% with human density-enhanced phosphatase (DEP-1) (Östman et al., 1994), and 35.3% with human PTPβ (HPTPβ) (Krueger et al., 1990). Other RPTPs have considerably less similarity to the SCA. The derived amino acid sequence of the SCA begins with a hydrophobic signal sequence and a region of 58 amino acids that shows no significant similarity to other known proteins. This region is followed by eight highly similar fibronectin type III (FN-III) repeats (Figs. 6b,7), a membrane proximal region, a hydrophobic transmembrane domain, and a cytoplasmic domain containing the 11 amino acid consensus sequence [(I/V)HCXAGXXR(S/T)G] for tyrosine phosphatase activity (Fig. 6b,c). This catalytic site is highly conserved and shares 100% identity with the catalytic sites of human DEP-1 and mouse Byp.
RT-PCR with primers designed to amplify a 1.4 kbp region of the cDNA encoding the entire membrane proximal region and the intracellular domain of the protein indicate that the mRNA for the SCA found in the inner ear, retina, kidney, and small intestine is the product of the same gene (Fig. 8). The major PCR product amplified in each of these four tissues was of the size predicted from the intestinal cDNA sequence. These PCR products hybridized at high stringency with an internal probe derived from the intestinal cDNA clone C. Direct sequencing of these PCR products yielded identical sequences from all four tissues. RT-PCR with a primer pair designed to amplify the entire extracellular domain including the region encoding the FN-III repeats also amplified a major fragment with the size predicted from the intestinal cDNA clone, but with yields that were insufficient for direct sequencing.
Supporting cells downregulate the SCA in response to noise- and drug-induced hair-cell damage
In whole-mount preparations of noise-damaged basilar papillae that have been double-labeled with monoclonal anti-HCA and mAb D37, it can be seen that the intensity of the mAb D37 labeling on the supporting-cell surfaces decreases in areas of hair-cell damage (Fig.9). These areas could be readily identified by the disruption of the normal regular mosaic of hair and supporting cells, by supporting cells exhibiting varying degrees of expansion of their apical surface, and the presence of hair cells with small punctate spots of HCA around their perimeter (Fig. 9). Outside the noise-damaged patch, supporting-cell surfaces have characteristic, narrow, compacted surfaces that stain fairly uniformly for the SCA (Fig. 9a,a′). On the edge of and within the damaged patch, some of the supporting cells exhibit substantially lower levels of labeling than neighboring supporting cells (Fig.9b,b′,c,c′).
In control basilar papillae that have been maintained in vitro for 24 hr, the supporting-cell surfaces show a small amount of expansion relative to their in vivo counterparts but otherwise stain intensely for the SCA (Fig.10a). The hair cells retain a normal morphology (Fig. 10a′). After treatment with 1 mm neomycin for 24 hr, most hair cells are lost, and in many areas no immunoreactivity can be detected with the monoclonal anti-HCA (Fig. 10b′,c′). In these drug-damaged areas where the hair cells have been lost, although many of the supporting cells maintain high levels of SCA expression, cell surface profiles can be observed that contact one another and do not stain with either mAb D37 or the monoclonal anti-HCA (Fig. 10b–c′). Many of the other supporting cell surfaces have reduced levels of mAb D37 staining relative to those in control cultures.
DISCUSSION
The results of this study describe the identification and characterization of the SCA as an RPTP that is associated with the apical surface of supporting cells in the sensory epithelia of the inner ear. The SCA is not unique to the inner ear and can be detected by immunofluorescence microscopy in a number of other tissues including retina, intestine, and kidney, where it is also associated with the apical membranes of polarized epithelial cells. The SCA can be detected in the brain by immunoblotting (data not shown) but not by immunofluorescence microscopy, indicating either that it is widely distributed in a diffuse, nonlocalized manner or that the relevant epitope is masked in brain sections. The presence of the SCA in brain is further confirmed by the observation that a partial clone of ∼300 bp derived from brain by degenerate RT-PCR has sequence identical to the SCA (Bodden and Bixby, 1996).
The derived amino acid sequence of the SCA predicts a transmembrane protein with a large extracellular domain containing eight FN-III repeats and an intracellular domain with a single catalytic site. The SCA is therefore a class III RPTP, according to the classification system of Tonks and colleagues (Fischer et al., 1991; Brady-Kalnay and Tonks, 1995). A number of other class III RPTPs have been described that only have FN-III repeats in their extracellular domains and a single intracellular catalytic domain. These include theDrosophila RPTPs DPTP10D and DPTP4E (Shin-Shay et al., 1991;Yang et al., 1991), chick CRYP-2 (Bodden and Bixby, 1996), rabbit GLEPP1 (Thomas et al., 1994), murine Byp (Kuramochi et al., 1996), rat DEP-1 (Borges et al., 1996), and, from human, HPTPβ (Krueger et al., 1990), DEP-1 (Östman et al., 1994), HPTPη (Honda et al., 1994), PTP-U2 (Seimiya et al., 1995), and SAP-1 (Matozaki et al., 1994). HPTPη and PTP-U2 are 97–99.5% similar to DEP-1, and all three molecules may therefore be the product of a single gene. The SCA is closely related to murine Byp and to DEP-1 from both human and rat, but differs from them in that the extracellular FN-III repeats show an unusual and much higher degree of internal similarity (Fig. 7). The FN-III repeats of the SCA share 54–94% identity, whereas the FN-III repeats of human DEP-1 have only 12–28% identity. The similarity of the FN-III repeats in the SCA indicates that they are derived from a recent exon duplication event or have been highly conserved to maintain function.
The ligand for the SCA is not known, and thus far only a few RPTP ligands have been identified. RPTPμ interacts with itself, acting as a homophilic cell–cell adhesion molecule (Brady-Kalnay et al., 1993;Gebbink et al., 1993). RPTPβ/ζ probably interacts with a complex composed of contactin, Nr CAM, and the contactin-associated protein caspr (Peles et al., 1995; Sakurai et al., 1997; Peles et al., 1997; for review, see Peles et al., 1998), and the laminin-nidogen complex can act as a ligand for the leukocyte common antigen-related receptor (O’Grady et al., 1998). The SCA cannot act as a homophilic cell–cell adhesion molecule on the apical surfaces of polarized epithelia, but the apical membranes of the supporting cells in the avian inner ear are in intimate contact with the extracellular matrices that overlie the sensory epithelia. Components of these matrices, such as chick α- and β-tectorin (Killick et al., 1995; Coutinho et al., 1999), are therefore candidate ligands. Although the tectorins are expressed only in the inner ear and cannot be ligands in the other organs where the SCA is found, other extracellular molecules may interact with the SCA in these tissues. For example, the interphotoreceptor matrix, an extracellular matrix composed of glycoproteins and proteoglycans that surrounds the outer segments of the photoreceptors (Hageman and Johnson, 1991), contacts the Müller cell microvilli in the eye, and molecules that have regions of sequence similarity with the tectorins, such as the urinary protein uromodulin and the mucins (Killick et al., 1995; Legan et al., 1997), are associated with the brush borders in the kidney and intestine.
The proliferation of normal, nontransformed cell types requires the presence of exogenous growth factors, many of which operate via receptor tyrosine kinases, and it is the balance of protein tyrosyl phosphorylation that influences the growth state of a cell. Supporting cells proliferate when explants of the sensory epithelia of the avian inner ear are grown in serum-free medium (Warchol and Corwin, 1993), even if the epithelia are completely isolated from underlying stromal tissue, indicating that they can produce growth factors that act in an autocrine manner (Warchol, 1995). Growth factors that have been shown to influence supporting-cell proliferation include TGFα, epidermal growth factor (in combination with insulin), FGF2, and IGF1 (Yamashita and Oesterle, 1995; Oesterle et al., 1997; Zheng et al., 1997), and mRNAs for the receptors of all of these factors, including the insulin receptor, are present in the chick inner ear (Lee and Cotanche, 1996). Although it is not known which growth factors are operational in the ear in vivo, there is recent evidence that RPTPs can negatively regulate both insulin receptor (Kulas et al., 1995) and FGF receptor signaling pathways (Kokel et al., 1998). Interaction of the SCA with either of these two receptor tyrosine kinase pathways could control the level of protein phosphorylation in the supporting cells of the ear. Furthermore, a number of lines of evidence from in vitro studies indicate that some of the class III RPTPs with which the SCA shares sequence identity are involved in the control of cell growth and differentiation (Östman et al., 1994; Gaits et al., 1995; Borges et al., 1996;Keane et al., 1996). For example, human DEP-1 is upregulated when fibroblast cell lines reach density-dependent arrest of cell growth (Östman et al., 1994), and expression levels of mRNA for human DEP-1 and SAP increase when breast cancer cell lines are treated with sodium butyrate, a compound that induces cell differentiation and inhibits cell growth (Keane et al., 1996). Together these data prompt the hypothesis that the SCA controls either the proliferation or differentiation of supporting cells in the sensory epithelia of the inner ear.
If the SCA does play a role in controlling supporting-cell proliferation in the inner ear, levels of either SCA mRNA or protein may be expected to correlate with the proliferative state of the supporting cell, as described above for related RPTPs in dissociated cell culture. After hair-cell loss induced by either ototoxic drug treatment in vitro or noise damage in vivo, SCA expression levels clearly decrease on the apical surfaces of some, but not all, of the supporting cells in the basilar papilla. For the noise-damaged tissue, this decrease occurs before the time at which supporting cells first enter S-phase [18 hr after the onset of noise exposure (Stone and Cotanche, 1994)] and may therefore be a primary rather than a secondary response to hair-cell injury. High levels of SCA expression may block cell proliferation but could also prevent cells from adopting the hair-cell phenotype. Whether these cells with decreased levels of SCA expression then go on to reenter the cell cycle and give rise to new hair and supporting cells, or differentiate directly into hair cells, remains to be determined and will be the focus of future studies.
Footnotes
This work was supported by grants from the Wellcome Trust, the Medical Research Council, Defeating Deafness, the National Organization for Hearing Research (D.A.C.), and National Institutes of Health/National Institute on Deafness and Other Communication Disorders Grants DC02291 (M.E.W.), DC03568 (Y.R.), and DC01689 (D.A.C.). The authors thank Cecylia Malenczak, Laura Perry, and Elizabeth Messana for excellent technical assistance, and Jonathan Gale for his helpful criticism of this manuscript.
The nucleotide sequence reported in this paper has been submitted to the EMBL Nucleotide Sequence Database with accession number AJ238216.
Correspondence should be addressed to Dr. Guy P. Richardson, School of Biological Sciences, The University of Sussex, Falmer, Brighton, BN1 9QG, UK.