1 Gonda Department of Cell and Molecular Biology, House Ear Institute, Los Angeles, CA 90057, USA
2 Center for Basic Neuroscience, University of Texas Southwestern Medical Center, 5323 Harry Hines Blvd, Dallas, TX 75390, USA
3 Department of Molecular and Human Genetics, Howard Hughes Medical Institute, Baylor College of Medicine, Houston, TX 77030, USA
4 Department of Cell and Neurobiology, University of Southern California Medical School, Los Angeles, CA 90033, USA
*Authors for correspondence (e-mail: pchen{at}hei.org and nsegil{at}hei.org)
Accepted 5 March 2002
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SUMMARY |
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Key words: Inner ear development, Organ of Corti, Hair cell, Prosensory domain, Math1, p27Kip1, Mouse
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INTRODUCTION |
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Proneural genes in Drosophila function in at least two steps in the development of the sensory elements of the Drosophila nervous system. First, they specify a cluster of cells in the naïve ectoderm of the embryo, endowing these cells with the competence to become neural/sensory precursors (reviewed by Jarman and Ahmed, 1998; Lewis, 1996
). Proneural genes function a second time during the selection of a specific cell within the proneural field, the sensory organ precursor (SOP), which will go on to divide through a fixed lineage and differentiate into supporting cells and neurons of the Drosophila sensory organ. Once selected, under the influence of the relevant proneural gene, the SOP actively inhibits the differentiation of other cells in the prosensory domain through Notch-dependent lateral inhibition. Loss of the proneural gene leads to the loss of the entire lineage associated with the sensory structure in question (Jarman and Ahmed, 1998
).
Similar to the development of sensory arrays in Drosophila, development of the organ of Corti appears to be separated into a proneural-like phase, during which a field of cells are specified within the cochlear epithelium to give rise to sensory structures, followed by a neurogenic-like phase, during which this field is patterned into sensory hair cells and supporting cells. The presence of proneural and neurogenic phases is supported by the observation that mutations in the elements of the Notch-DSL (Delta/Serrate/Lag-2) pathway have been shown to lead to perturbations in cellular patterning of the mouse cochlear epithelium, causing defects in the characteristic rows of inner and outer hair cells (Lanford et al., 1999; Zhang et al., 2000
; Zheng et al., 2000
; Zine et al., 2000
). Further support comes from the observation that Math1 (Atoh1 Mouse Genome Informatics), a member of the bHLH family of transcription factors and a close homolog of the Drosophila proneural gene atonal, has been found to be required for the differentiation of sensory hair cells within the developing cochlea (Bermingham et al., 1999
; Ben-Arie et al., 2000
).
In spite of the fact that Math1 can complement the proneural function of atonal in Drosophila (Ben-Arie et al., 2000), the proneural nature of the role of Math1 in mammalian development is unclear. In addition to its role in inner ear development, Math1 is required for the formation of several neuronal cell types, including the granule cells of the cerebellum (Ben-Arie et al., 1997
; Helms and Johnson, 1998
), pontine nuclei (Ben-Arie et al., 2000
), proprioceptive interneurons whose axons form the spino- and cuneo-cerebellar tracts (Bermingham et al., 2001
; Gowan et al., 2001
) and secretory cells in the small intestinal epithelium (Yang et al., 2001
). In the absence of Math1, development of all these cell types is compromised. Nonetheless, in the cerebellum, for example, it remains unknown whether the lack of granule cell development results from a lack of progenitors specified by Math1, or from a defect in proliferation or differentiation of these precursors (Ben-Arie et al., 1997
; Helms et al., 2000
). Similarly, in the developing inner ear of Math1-mutant mice, supporting cells, which (based on work in birds and fish) are believed to share a common precursor with the sensory hair cells (Fekete et al., 1998
; Haddon et al., 1998
; Haddon et al., 1999
; Jones and Corwin, 1996
; Riley et al., 1999
; Stone et al., 1999
), appear to be able to differentiate and survive even though hair cells fail to differentiate (Bermingham et al., 1999
). This result suggests that the specification of the common precursor of hair cells and supporting cells may not be strictly dependent on the presence of Math1, and thus Math1 may not be functioning in the same manner as proneural genes in Drosophila.
Formation of the cochlear epithelium (Fig. 1A-D), within which the organ of Corti will differentiate, begins as an out-pocketing of the ventromedial otocyst prior to E12 (Fig. 1A) (Morsli et al., 1998). Growth of this cochlear out-pocketing will continue until the cochlea has reached its mature length at approximately E18 (Fig. 1D). Between E12 and E14, cells in a region of cochlear epithelium representing the primordial organ of Corti exit the cell cycle (Ruben, 1967
). This region is marked by the expression of p27Kip1 (Cdkn1b Mouse Genome Informatics), a cyclin-dependent kinase inhibitor involved in timing cell cycle exit in the sensory epithelium (Chen and Segil, 1999
).
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We have examined the role of Math1 in the formation of the sensory primordium and subsequent differentiation of sensory cells both along and across the developing organ of Corti. We report three pieces of evidence indicating that Math1 is not involved in the specification of the sensory primordium within the cochlea. First, Math1 is expressed only in cells after they have exited the cell cycle to form a zone of non-proliferating cells (ZNPC) along the length of the cochlear duct at the site of the developing organ of Corti. The expression of Math1 within the ZNPC is limited to a subpopulation of cells that appear to differentiate exclusively into hair cells as the sensory epithelium matures and elongates through a process that probably involves radial intercalation of cells. Second, in Math1-null mutants, development of the prosensory domain, as assayed by the appearance of the ZNPC and expression of p27Kip1, occurs normally, even though hair cells fail to differentiate. Finally, we observe that in Math1-null animals, a population of cells within the sensory epithelium dies by apoptosis in a basal-to-apical gradient, similar in timing to that normally observed for hair cell differentiation. Together, these results show that although Math1 is required for the selection and/or differentiation of hair cells, it is not required for the establishment of the ZNPC, the operationally defined prosensory domain within the developing cochlear anlage. Thus, Math1 does not play a role in the specification of the common hair cell and supporting cell lineage in the organ of Corti, and appears to play a more restricted prosensory role than its Drosophila homolog atonal.
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MATERIALS AND METHODS |
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The Math1-null mice used in this study (Ben-Arie et al., 1997) were outcrossed to CD1 wild-type mice. Genotyping was carried out by PCR using oligos 5' TCT GCT GCA TTC TCC CGA GC 3' and 5' GCA CCG AGT AAC CCC CAG AG 3' for the wild-type Math1 allele, and oligos 5' GAA CCC AAA GAC CTT TTG CAC 3' and 5' CAC GAG ACT AGT GAG ACG TG 3' for the Math1-null allele, and confirmed by immunohistochemistry for Math1 protein.
BrdU injections
BrdU was dissolved at 5 mg/ml in 7 mM NaOH in PBS and injected at 50 µg BrdU per gram of body weight. Mice were injected intraperitoneally at 2 hour intervals and sacrificed at times specified in the text. Cochlear tissues were dissected and fixed in 4% paraformaldehyde for 1-4 hours and then sectioned for immunodetection of incorporated BrdU.
Cochlear wholemounts
To visualize the expression of Math1/EGFP in the developing cochlea (Fig. 1), unfixed bulla from embryos aged E12.5, E13.5 and E14.5 were dissected in Dulbeccos phosphate-buffered saline (PBS) (GibcoBRL), then incubated in Dulbeccos PBS containing 1 mg/ml of collagenase (Worthington Biochemical Corporation) and 1 mg/ml of dispase (GibcoBRL) for 10-15 minutes. The enzyme solution was replaced with fresh Dulbeccos PBS and surrounding non-epithelial tissues were removed to expose the inner ear epithelium. The cochlear ducts from embryos older than E15 were dissected without enzyme treatment. The cochleae from Math1/EGFP transgenic animals were photographed under low magnification on a Zeiss inverted compound microscope and photographed digitally with a Spot camera (Diagnostic Instruments).
Immunohistochemistry
Cochleae were dissected in Hanks balanced saline solution (GibcoBRL) and fixed in 4% paraformaldehyde in PBS. Immunohistochemistry was as previously described (Chen and Segil, 1999). The following antibodies were used in these studies: anti-p27Kip1 (NeoMarker, mouse monoclonal, dilution 1:100); anti-Jagged1 (Santa Cruz, goat polyclonal, dilution 1:50- 1:100); anti-BrdU (Chemicon, mouse monoclonal, dilution 1:100); anti-activated Caspase 3 (R&D Systems, rabbit polyclonal, dilution1:200); anti-EGFP (Molecular Probes, rabbit polyclonal, dilution 1:1000); anti-Math1 (rabbit polyclonal, dilution 1:100)) (Helms and Johnson, 1998
); anti-MyosinVIIa (rabbit polyclonal, courtesy of Christine Petit, Pasteur Institute, dilution 1:1500). Sections stained with anti-p27Kip1 were first treated in a microwave oven for 10 minutes in 10 mM citric acid buffer, pH 6.0. For BrdU staining, sections were incubated in 50% formamide/2xSSC at 65°C for 2 hours and then washed with 2xSSC/2N HCl at 37°C for 30 minutes. After neutralization with 0.1 M boric acid (pH 8.5) for 10 minutes, the sections were stained with an antibody against BrdU.
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RESULTS |
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Timed-mated pregnant female mice were injected with BrdU on either E12.5, E13.5 or E14.5 (three injections, 2 hours apart) and the animals were killed 8 hours after the first injection. The pattern of BrdU incorporation into the nuclei of replicating cells within the entire cochlear duct was compared with the onset of p27Kip1 expression by immunohistochemistry (Fig. 2). Adjacent sections through the basal region of the cochlea are shown. After administration of an 8 hour pulse of BrdU at E12.5, cells throughout the cochlear epithelium have incorporated BrdU, indicating that they are still in the cell cycle (Fig. 2A). This includes the site of the future organ of Corti, as ascertained by the presence of spiral ganglion neurons that were stained with antibody against neurofilament and neuronal ß-tubulin (data not shown, see arrow in Fig. 2A). p27Kip1 is not yet expressed in the cochlea at this stage (Fig. 2B). By contrast, following BrdU administration on E13.5, a distinct ZNPC is formed, as seen by the lack of BrdU incorporation in this region (Fig. 2C, bracket). The establishment of this ZNPC between E12.5 and E13.5 correlates with the onset of p27Kip1 expression both temporally and spatially (Fig. 2C,D). At E13.5, the ZNPC runs the apical to basal extent of the cochlear anlage (Fig. 3C), and is indicative of a population wide cell cycle exit that occurs within a narrow band of cells, delimited by p27Kip1 expression. p27Kip1 protein continues to be expressed on E14.5 (Fig. 2F), prior to the onset of hair cell and supporting cell differentiation, as cells in the regions on either side of the nascent organ of Corti continue to divide and incorporate BrdU (Fig. 2E, bracket). In summary, a zone of non-proliferating cells (ZNPC) is formed at the site of the future organ of Corti by E13.5, coinciding temporally and spatially with the expression domain of p27Kip1.
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To compare more easily the temporal and spatial pattern of Math1 expression with that of p27Kip1 and the establishment of the ZNPC, we made use of a transgenic mouse harboring a cDNA coding for EGFP under the direct control of a Math1 enhancer (Helms et al., 2000). The expression of the transgene, Math1/EGFP, in the developing inner ear is illustrated in Fig. 1. Comparison between the pattern of Math1/EGFP expression and that of endogenous Math1 protein detected by immunohistochemistry, indicates that the onset of Math1/EGFP transgene expression matches the expression of the endogenous Math1 (compare Fig. 3B with 3C; compare 3D with 3E; data not shown). A previous report has indicated that Math1 is expressed as early as E12 in the inner ear (Bermingham et al., 1999
). However, at this time both Math1 immunoreactivity (Fig. 3A) and Math1/EGFP expression (Fig. 1A) are limited to the sensory regions of the vestibular portion of the inner ear, consistent with the earlier onset of differentiation observed in this part of the inner ear (Ruben, 1967
). The expression of Math1 is not observed in the cochlear duct on either E12.5 (Fig. 3A, arrow; Fig. 1A) or E13.5 (Fig. 3B; Fig. 1B), at which time the ZNPC has already been established. The presence of the ZNPC in the absence of Math1/EGFP expression is dramatically demonstrated in a horizontal section through the developing cochlear duct of an E13.5 Math1/EGFP transgenic embryo injected with BrdU (Fig. 3C, ZNPC in brackets).
The first cells to express Math1 in the cochlea appear between E13.5 and E14.5 as a discrete column of cells that spans the entire depth of the sensory epithelium near the base of the cochlear duct, as assayed both by immunohistochemistry (Fig. 3D) and by Math1/EGFP (Fig. 3E,F). These cells appear near the medial border of the ZNPC within the domain of p27Kip1 expression (Fig. 3E,F). At this time, Math1 has not yet appeared in the middle, apical or the hook regions of the still elongating cochlea (Fig. 1C).
The observation that the onset of Math1 expression takes place within the boundaries of the ZNPC suggests that Math1 is expressed only in cells that have exited the cell cycle. To determine whether the appearance of Math1 in the nascent organ of Corti is strictly tied to the postmitotic state, timed-mated pregnant mice were injected with BrdU at E12.5 (Fig. 4A) and E13.5 (Fig. 4B), and allowed to survive until E14.5, when Math1+ cells first appear in the base of the cochlea (Fig. 3D). Math1/EGFP transgenic mice were used to identify the Math1-expressing cells. The presence of BrdU and Math1/EGFP double-labeled cells is indicative of the time of cessation of cell division of the Math1/EGFP+ cells. In mice injected at E12.5 and sacrificed on E14.5, numerous double-positive (yellow) cells were observed (Fig. 4A, sacrificed 48-54 hours after the initial BrdU injection), indicating that at the time of injection of BrdU, these cells were still in the cell cycle. However, BrdU injection 1 day later (on E13.5) yielded no double-positive cells when sacrificed at E14.5 and the ZNPC is clearly visible (Fig. 4B, bracket). Together, these data indicate that sensory epithelial cells in the primordial organ of Corti become postmitotic between E12.5 and E13.5, prior to the expression of Math1, and that Math1 expression initiates at the medial border of the ZNPC where inner hair cells first begin to appear.
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By E15.5, the sensory epithelium in the base of the cochlea has matured into a bilayered structure (Fig. 5D,F,H) and a single row of inner hair cells and three rows of outer hair cells are visible with Math1 labeling (Fig. 5D). In an adjacent section stained for MyosinVIIa (Fig. 5F), only the inner hair cell (Fig. 5F, arrowhead) and the innermost outer hair cell (Fig. 5F, the outer hair cell region is indicated by a bracket) are labeled by MyosinVIIa. The lack of staining in the two outermost rows of outer hair cells (Fig. 5F, bracket) is indicative of an inner to outer (medial to lateral) gradient of differentiation. The location of the developing organ of Corti is shown in an adjacent section by double-labeling for p27Kip1 and MyosinVIIa (Fig. 5H). Math1 expression clearly precedes MyosinVIIa expression and p27Kip1 downregulation in nascent hair cells in this medial to lateral gradient (compare Fig. 5D with 5F,H).
Math1 expression also precedes MyosinVIIa expression in the basal-to-apical gradient (compare Fig. 5C with 5E and 5G). At the apical end of the gradient on E15.5, the same columnar pattern of Math1+ cells (Fig. 5C) that were seen a day earlier in the base (Fig. 5B), are now visible (compare Fig. 5B with 5C), and the sensory epithelium has not begun to thin to the mature state. MyosinVIIa expression has not begun at this apical level (Fig. 5E), nor has downregulation of p27Kip1 occurred (Fig. 5G).
Math1 is not required for the establishment of the ZNPC
We have shown that the onset of Math1 expression occurs in a limited subset of cells confined to the previously established ZNPC (Fig. 3), suggesting that the sensory primordium is established without the help of Math1. However, because these determinations rely on the early detection of Math1 immunoreactivity or transgene expression, it is possible that the Math1 gene functions prior to our ability to detect its presence. As a functional test of the expression data presented so far, we have compared the development of the sensory primordium in wild-type and Math1-null embryos.
Timed-mated pregnant mice were given an 8 hour pulse of BrdU starting on E14.5 (three injections, one every 2 hours and then sacrificed 2 hours after the last injection). The pattern of BrdU incorporation indicated that the ZNPC had formed prior to this time in both wild-type and Math1/ littermates (Fig. 6A,B, brackets). Likewise, the pattern of p27Kip1 expression is the same in wild-type and Math1/ littermates (Fig. 6C,D, brackets). Thus, according to these criteria, Math1 activity is not needed for the establishment of the sensory primordium.
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A gradient of apoptosis in the Math1/ organ of Corti parallels the basal-to-apical gradient of hair cell differentiation in the wild-type organ of Corti
Hair cells in the Math1-null organ of Corti fail to differentiate (Bermingham et al., 1999). Both the organ of Corti and the vestibular system from these animals appear as a single layer of cells, which (according to morphological criteria) appear to be entirely supporting cells (Bermingham et al., 1999
). To analyze the failure of hair cell differentiation and the reduction in the thickness of the sensory epithelium that accompanies the maturation of the organ of Corti, we compared wild-type and Math1/ embryos for the presence of apoptotic cells.
Adjacent sections through the organ of Corti of wild-type and mutant embryos from E15.5-E17.5 were stained with anti-p27Kip1 to reveal the location of the developing sensory epithelium. These same sections were then double-labeled either with antibody against Activated Caspase 3 (ActCasp3), a marker of apoptotic cells, or against MyosinVIIa, in order to compare the state of hair cell differentiation in the organ of Corti in the presence and absence of Math1 (Fig. 7).
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By contrast, in Math1-null embryos, a gradient of apoptosis is observed (Fig. 7G,H,J,K), and, as previously reported (Bermingham et al., 1999), hair cells fail to differentiate, as indicated by the lack of MyosinVIIa staining (Fig. 7I,L). The gradient of apoptosis parallels the normal base-to-apex pattern of maturation, with apoptotic cells first appearing in the base of the cochlear duct on E15.5 (Fig. 7H), while no apoptotic cells are seen in the apex in the mutant organ of Corti at this time (Fig. 7G). Only later, at E17.5, do apoptotic cells appear in the apex (Fig. 7J), just at the time when the wave of hair cell differentiation would normally arrive (Fig. 7D). Prior to the onset of hair cell differentiation, the sensory epithelium of the mutant organ of Corti appears normal (four to five cells deep) (compare Fig. 7A with 7G). At E17, in the base of the cochlea of wild-type animals, the organ of Corti has differentiated into three rows of outer hair cells and one row of inner hair cells (Fig. 7F), while comparable sections from the mutant embryo indicate that apoptosis, present at E15, is no longer ongoing (Fig. 7K), but that the sensory epithelium has thinned to one layer of p27Kip1-positive cells (Fig. 7L). Despite their reported morphological resemblance to supporting cells (Bermingham et al., 1999
), it is noteworthy that we failed to detect a marker of supporting cells, Jagged1 (Morrison et al., 1999
), in the surviving cells of the Math1/ organ of Corti (data not shown).
Aberrant apoptotic activity is also observed in the sensory epithelia of the vestibular system in the absence of Math1, and the sensory epithelia of the vestibular system thins to a single layer of cells (data not shown). Together, these observations indicate that a population of cells in the developing sensory epithelium of the inner ear die in the absence of hair cell differentiation that is normally activated by Math1.
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DISCUSSION |
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The establishment of the ZNPC
Cells in the developing cochlea that are destined to form the organ of Corti have previously been reported to exit the cell cycle in a relatively synchronous wave between E12 and E14 (Ruben, 1967). We have used both the cell cycle exit and the expression of p27Kip1 as markers with which to assay the establishment of the ZNPC. Our previous observations on the function of p27Kip1 during organ of Corti development emphasized the importance of coordinating cell cycle control with cellular differentiation (Chen and Segil, 1999
). We have extended these earlier observations by narrowing the developmental window during which the signal for cell cycle withdrawal occurs, to between E12.5 and E13.5, and by identifying an additional marker, Jagged1, whose pattern of expression suggests a role in the establishment of the medial border of the ZNPC (Fig. 6E). However, the mechanism coordinating cell cycle exit and differentiation remains obscure. Although Math1 does not regulate cell cycle exit within the sensory primordium, the possibility remains that another, yet to be discovered, proneural gene is responsible for the specification of the sensory primordium and the timing of cell cycle exit.
The relatively synchronous cell cycle exit within the ZNPC differentiates these cells from the surrounding cochlear epithelium, which continues to divide after E13.5 (Fig. 2). In p27Kip1-knockout embryos, the synchronicity of cell cycle exit is disturbed and the ZNPC cannot be recognized as a discrete entity (data not shown). Nonetheless, Math1 is expressed only after cells within the p27Kip1-mutant sensory primordium do exit the cell cycle, as in the wild-type animal (data not shown). Among the tissues where Math1 plays a role, the strict coupling of the postmitotic state to the induction of Math1 expression appears to be unique to the organ of Corti. In other systems, such as the cerebellum, the spinal cord and the gut (Ben-Arie et al., 1997; Helms et al., 2000
; Yang et al., 2001
), Math1 is expressed in the proliferating precursor cells. The common theme that connects Math1 expression in various cell types may be its expression only at the time of, or after, the selection of a particular cell fate within a group of multipotent cells, regardless of the cell cycle state. In the cochlea, the inductive signal(s) for the expression of Math1 and the selection/differentiation of hair cells within the sensory primordium appears to be postmitotic.
Uncoupling the specification of the sensory primordium from selection of hair cell fate
During the development of the CNS and PNS in Drosophila, various bHLH proteins function as proneural genes, required for the specification of a so-called equivalence group, of cells that have become competent to form neuronal precursors. Typically, the same bHLH gene that imparts competence to the equivalence group is then required in a second step, in which single cells from within this group are selected to go on and become neurons or sensory cells through a tightly regulated series of asymmetric cell divisions coupled to differentiation of specific cell types (Jarman and Ahmed, 1998). Upregulation of the proneural gene in the selected cell is not only necessary for the differentiation of that cell, but also for the subsequent downregulation of the same gene in adjacent cells through a process of lateral inhibition mediated by Notch signaling (for a review, see Lewis, 1996
).
Earlier reports, based on in situ hybridization evidence, suggest that prior to hair cell differentiation, Math1 is first expressed in a horizontal band three to four cells wide running the length of the cochlea and then, as the organ of Corti matures, expression becomes limited to hair cells (Lanford et al., 2000). This observation, together with the demonstration that Notch signaling plays an important role in patterning hair cell differentiation (Lanford et al., 1999
; Lewis et al., 1998
; Zheng et al., 2000
; Zine et al., 2000
; Zine et al., 2001
), suggested a model in which Math1 may specify an equivalence group, analogous to a Drosophila proneural cluster, which is subsequently refined by lateral inhibition via Notch signaling and results in the limited expression of Math1 in hair cells. Our observations differ, in that at the earliest times of Math1 expression in the developing cochlea, we observe discrete vertical columns of Math1+ cells spanning the four to five cell deep sensory epithelium (Fig. 3). Circumstantial evidence in the form of labeling with anti-MyosinVIIa and anti-Math1 (Fig. 5) indicates that Math1 expression is probably limited to nascent hair cells as the differentiation of the organ of Corti progresses from base to apex in the cochlea (Fig. 5). This suggests that while Math1 plays a crucial role in hair cell differentiation, it is unlikely to play a role in defining a competence domain within the cochlear epithelium and, in turn, suggests a role for Math1 that differs somewhat from that outlined above.
In our model, the ZNPC, which arises between E12 and E13 (Fig. 2), before the expression of Math1, represents an operationally defined prosensory domain by virtue of the fact that the entire complement of hair cells and supporting cells in the mature organ of Corti arise from this postmitotic cell population. Because we lack prospective markers for an earlier definition of the prosensory domain, we are not able to establish when the prosensory domain first forms or its size at the time when it first arises. At E13, however, the ZNPC probably represents an equivalence group, in that hair cell and supporting cell differentiation has not yet occurred within its borders, and competence to differentiate into hair cell appears to persist for some time even after the differentiation of hair cells is well under way (Kelley et al., 1995). However, competence to differentiate into hair cells is unlikely to be limited to the ZNPC. Several groups have demonstrated that abnormal perturbations of Notch pathway signaling may lead to hair cell differentiation outside this region in nearby cochlear epithelia (Kelley et al., 1993
; Zine et al., 2001
). In addition, ectopic expression of Math1 can lead to hair cell differentiation within the greater epithelial ridge of postnatal animals (Zheng and Gao, 2000
).
Shortly after the establishment of the ZNPC, a signal(s) of unknown origin stimulates the initial expression of Math1 near the base of the cochlea. Expression initiates in a series of discrete columns of cells that span the depth of the sensory epithelium (Fig. 8). We believe these cells represent nascent hair cells, which by a process of convergent intercalation will form the inner hair cells of the organ of Corti. This pattern of Math1 induction is then propagated in the basal-to-apical direction, as well as in a medial-to-lateral direction, in order to give rise to the rows of outer hair cells (Fig. 8). The basis of this propagated patterning event is currently unknown, but is likely to depend both on positive stimuli inducing Math1 expression, and lateral inhibition that limits the expression of Math1 in the surrounding supporting cell precursors. In this model, cells within the prosensory domain would receive a positive stimulus to express Math1, which in genetically Math1-null animals leads to apoptosis in a pattern of cell death that parallels the normal process of hair cell differentiation.
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While homologs of bHLH genes are involved in the development of the nervous system in many species, including mammals (Lee, 1997), it appears that the two functions ascribed to these factors in Drosophila, equivalence group specification and SOP selection, have been uncoupled evolutionarily. Evidence for this includes the observation that mutation of other members of the family of vertebrate bHLH proteins appears to cause the loss of a single cell type in the different tissues within which they are expressed (Hassan and Bellen, 2000
), rather than the failure of the entire sensory lineage, as occurs in Drosophila mutants. Similarly, in the mouse inner ear, loss of Math1 leads to the death of only a subpopulation of cells within the prosensory domain, probably cells that are otherwise destined to become hair cells.
The molecular pathways that specify the boundaries of the ZNPC and coordinate its appearance with the cellular differentiation of the organ of Corti remain elusive. In addition to its role in the selection of hair cell versus supporting cell fate (Haddon et al., 1998; Eddison et al., 2000
; Lanford et al., 1999
), the role of the Notch signaling pathway in the formation of the boundaries for the sensory primordium remains to be tested directly. Our demonstration that Jagged1 expression appears to share a border with the prosensory domain defined by the ZNPC is suggestive of such a role.
A model of organ of Corti growth by radial extension
Radial and mediolateral intercalation of cells is the basis for the movements of convergence and extension that function in gastrulation, neurulation and formation of the vertebrate body axis (Keller et al., 2000; Zajac et al., 2000
). The morphological changes that occur in the absence of significant cell birth and cell death during maturation and elongation of the organ of Corti from E13, when the cochlear duct is three-quarters of a turn long, to E18, when the cochlear duct has achieved its mature one and a half turns (Ruben, 1967
) (Figs 1, 2, 5, 7), suggest that a similar process involving radial intercalation may be at work in the sensory epithelia of the cochlear duct. This model is derived from three observations. First, few new cells are added to the organ of Corti following E13.5, so the elongation process has to be accounted for by non-mitotic growth. Second, that the sensory epithelium thins from four to five cells deep at E13, to two cells deep in its mature state (Figs 5 and 7). Third, that staining with antibody to ActCasp3 reveals no apoptotic cells within the developing organ during this period of development (Fig. 7 and data not shown). Thus, radial intercalation of cells (movement along the y-axis in Fig. 8) leads to the thinning and the longitudinal extension (along the z-axis in Fig. 8) of the developing sensory organ during the elongation of the cochlear duct. In this process, hair cell progenitors, in the form of Math1+ cells that were aligned in the same location along the y-axis, are displaced along the z-axis as they differentiate (Fig. 8). At the same time, new columns of Math1+ cells that form lateral to this initial column (see Fig. 5B,C) recapitulate the process to form the rows of outer hair cells. A similar scenario of cellular rearrangement and elongation within the basilar papilla has been observed in the inner ear of birds (Goodyear and Richardson, 1997
), though direct proof of this hypothesis in either species awaits direct observation of the process using marked cells.
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ACKNOWLEDGMENTS |
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REFERENCES |
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