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First published online 16 August 2006
doi: 10.1242/dev.02536
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Huffington Center on Aging, Department of Otolaryngology - Head and Neck Surgery, Department of Molecular and Cellular Biology, Program in Cell and Molecular Biology, Baylor College of Medicine, Houston, TX 77030, USA.
Author for correspondence (e-mail:
fpereira{at}bcm.edu)
Accepted 17 July 2006
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SUMMARY |
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 TOP SUMMARY INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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-secretase inhibitor in an in
vitro organ culture system of wild-type cochleae resulted in a reduction in
expression of the Notch target gene Hes5 and an increase in hair cell
differentiation. Importantly, inhibition of Notch activity resulted in a
greater increase in hair cell differentiation in
COUP-TFI-/- cochlear cultures than in wild-type cultures,
suggesting a hypersensitivity to Notch inactivation in
COUP-TFI-/- cochlea, particularly at the apical turn.
Thus, we present evidence that reduced Notch signaling contributes to
increases in hair cell and support cell differentiation in
COUP-TFI-/- mice, and suggest that COUP-TFI is required
for Notch regulation of hair cell and support cell differentiation.
Key words: COUP-TFI, Cochlea, Hair cell, Deiter's cell, Cell proliferation, Differentiation, Migration, Notch, Jag1, Hes5, Lfng, Organ culture, -secretase, DAPT, Myosin VIIa
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INTRODUCTION |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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; Pereira et al.,
2000). COUP-TFI (chicken ovalbumin upstream promoter transcription
factor I; also known as NR2F1) is an ONR proposed to function as a
ligand-regulated transcription factor
(Cooney et al., 1992;
Wang et al., 1989). In the
absence of a specific ligand or of binding to an antagonist, ONRs repress the
expression of target genes through interaction with co-repressor proteins
(Shibata et al., 1997). Upon
binding to a ligand or agonist, ONRs undergo conformational changes that
displace co-repressors with co-activators, leading to the expression of target
genes (McKenna and O'Malley,
2002). COUP-TFI has been shown to play important roles in the
central and peripheral nervous systems
(Pereira et al., 2000). Mice
deficient in COUP-TFI exhibit reduced axon arborization
(Qiu et al., 1997),
thalamocortical projections (Zhou et al.,
1999), disrupted regionalization of the forebrain neocortex
(Zhou et al., 2001), a delay
in axon myelination (Yamaguchi et al.,
2004), and defects in tangential cell migration in the basal
forebrain (Tripodi et al.,
2004). Most recently, the paralog COUP-TFII (Nr2f2) was implicated
in epithelial-mesenchymal interactions for radial and anteroposterior
patterning of the stomach (Takamoto et
al., 2005), and in the specification of arteries through
regulation of the Notch pathway (You et
al., 2005).
The Notch gene family encodes transmembrane receptors and ligands that are
crucial for cell fate decisions during development in metazoans
(Heitzler and Simpson, 1991;
Swiatek et al., 1994). Notch
signaling governs the choice of cell fate by lateral inhibition, in which one
cell inhibits a group of adjacent cells from taking a specific fate, and by
lineage decisions, in which one daughter cell adopts a fate different from its
sibling (Artavanis-Tsakonas et al.,
1995). The restricted expression of Notch signaling components
mediates the regulation of Notch activity
(Robey, 1997). Notch receptors
and their ligands are initially expressed in the same cells, and modulation of
expression of a specific ligand affects the activity in the adjacent cell
expressing the receptors (Heitzler and
Simpson, 1991). Ligand binding induces a proteolytic cascade,
culminating in the release and activation of the Notch intracellular domain
(NICD). A presenilin-dependent -secretase complex mediates the
activating cleavage of the NICD (De
Strooper et al., 1999). The NICD then translocates to the nucleus
and switches a DNA-bound factor associated with co-repressors into a complex
associated with co-activators that stimulate the transcription of Notch target
genes, such as the hairy/enhancer of split (Hes) genes
(Barrick and Kopan, 2006;
Jarriault et al., 1995;
Kao et al., 1998;
Kopan and Turner, 1996;
Struhl and Adachi, 1998).
In humans, deregulated Notch signaling causes several developmental
abnormalities and diseases. Mutation of JAG1 causes Alagille
syndrome, an autosomal dominant disorder characterized by deafness and
developmental abnormalities of various organs
(Li et al., 1997;
Oda et al., 1997). Mutation in
NOTCH3 leads to CADASIL (cerebral autosomal dominant arteriopathy
with subcortical infarcts and leukoencephalopathy), an inherited vascular
dementia syndrome (Joutel et al.,
1996; Kalaria et al.,
2004) with characteristics that include sensorineural hearing loss
(Baudrimont et al., 1993;
Phillips et al., 2005). The
formation of cellular diversity in the sensory epithelium is a highly
regulated developmental event involving proliferation, cell fate decisions,
pattern formation, and differentiation and Notch signaling. Notch signaling
cascade proteins, including Notch1, Dll1, Jag1, Jag2, Hes1 and Hes5 are
expressed in hair cells, supporting Deiter's cells or their precursors
(Lanford et al., 1999;
Lanford et al., 2000;
Morrison et al., 1999;
Zheng et al., 2000;
Zine et al., 2001). Mutations
of Notch and its signaling components in mice result in extra rows of either
inner or outer hair cells, Notch1
(Zhang et al., 2000),
Jag1 (Kiernan et al.,
2001), Jag2 (Lanford
et al., 1999; Zhang et al.,
2000), Hes1 (Zheng et
al., 2000; Zine,
2003) and Hes5 (Zine,
2003), consistent with the notion that lateral inhibitory
mechanisms were disrupted. Additionally, antisense Notch1 and
Jag1 oligonucleotides (Zine et
al., 2000), or use of -secretase inhibitors
(Yamamoto et al., 2006) that
block Notch signaling, in cochlear organ cultures produce supernumerary hair
cells. These and other studies have led to the conclusion that Notch signaling
is essential for the differentiation of hair cells in vertebrates
(Daudet and Lewis, 2005;
Haddon et al., 1998;
Kiernan et al., 2001;
Kiernan et al., 2005;
Kiernan et al., 2006;
Lanford et al., 1999;
Weir et al., 2000;
Woods et al., 2004;
Yamamoto et al., 2006;
Zhang et al., 2000;
Zheng et al., 2000;
Zine et al., 2000).
We have recently described a detailed expression profile of COUP-TFI and
COUP-TFII in the developing and mature mouse cochlea
(Tang et al., 2005). We showed
that COUP-TFI is expressed in the otocyst and developing sensory epithelium
prior to and during hair cell and support cell differentiation. Here, we
report for the first time that COUP-TFI deficiency causes altered
sensory epithelial development, resulting in supernumerary hair cells and
support cells in the apical turn: there are frequent inner hair cell (IHC)
duplications, four rows of outer hair cells (OHC) in the middle turn and up to
six to seven rows of OHCs at the apex, all with an equal number of underlying
Deiter's support cells. Because the phenotype was strikingly similar to that
caused by inhibition of Notch signaling
(Zine et al., 2000;
Kiernan et al., 2005;
Kiernan et al., 2006;
Brooker et al., 2006), we
investigated the expression of Notch signaling genes in the developing sensory
epithelium of COUP-TFI-/- mice by in situ hybridization
and by quantitative RT-PCR (qRT-PCR) in an in vitro cochlea organ culture
system. These studies showed qualitative and quantitative changes in several
Notch signaling components, which indicated that Notch signaling was
attenuated in COUP-TFI-/- cochleae. We show that a
-secretase inhibitor (DAPT) suppressed Notch signaling in a
dose-dependent fashion and induced hair cell differentiation in both wild type
and in COUP-TFI-/- cochleae in organ cultures. DAPT
suppressed Notch signaling to a greater extent in
COUP-TFI-/- cochleae, suggesting a hypersensitivity to
inhibition of Notch signaling in COUP-TFI-/-, particularly
at the apical turn. These results are consistent with a function for COUP-TFI
in modulating Notch regulation of differentiation and patterning of hair cells
and support cells.
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MATERIALS AND METHODS |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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) and is in
accordance with the Guide for the Care and Use of Laboratory Animals, and the
Animal Welfare Act approved by the Institutional Animal Care and Use Committee
of the Baylor College of Medicine. The onset of gestation was identified by
the appearance of a vaginal plug the morning after mating and was designated
as embryonic day (E) 0.5, with the day of birth set as P0.
Counts of phalloidin-stained hair cells
P10 cochleae were dissected to open the cochlear capsule and fixed in 2%
paraformaldehyde and 0.1% Triton X-100 in PBS for 10 minutes. After PBS washes
and incubation in Alexa 488-conjugated phalloidin (Molecule Probes, Eugene,
OR; 1:200, diluted in PBS) for an hour at room temperature, the stria
vascularis and tectorial membrane were removed to expose the organ of Corti.
Cochleae were then flat-mounted with Vectashield DAPI medium (Vector
Laboratories, Burlingame, CA) on glass slides and examined under
epi-fluorescence (Carl Zeiss, Gottingen, Germany). Eight samples from each
genotype were studied. Hair cell counts were estimated from three equal
portions (basal, middle and apical) of the cochlear duct, and counted in at
least four random microscopic fields (400x) from three cochleae of each
genotype. Numbers are means±s.e.m., with statistical significance at
P<0.05.
Paint-filling of cochlear ducts
Inner ears at E13, E15 and E17 were isolated from wild-type and null
embryos, fixed in Bodian's fixative, dehydrated in an ethanol series, and
cleared in methyl salicylate. Latex paint was injected to visualize the
membranous labyrinths as previously described
(Morsli et al., 1998). At
least four pairs of inner ears were injected for each stage studied.
Histology
Embryonic heads of E14.5 to E16.5 mice, or isolated cochleae at P10, were
fixed in neutral-buffered formalin, dehydrated and embedded in paraffin. Sets
of 7-10 µm serial sections through the cochlear duct were collected and
processed for Hematoxylin and eosin staining, immunofluorescence analyses or
in situ hybridization.
Immunofluorescence and proliferating cell counts
Immunofluorescence was performed with anti-p27 (1:200, NeoMarkers, Fremont,
CA), Ki67 (1:200, BD Biosciences, San Diego, CA), anti-BrdU (DAKO,
Carpinteria, CA), anti-myosin VIIa (Tama Hasson, Department of Biological
Sciences, University of California at San Diego, San Diego, CA; or Proteus
Biosciences, 25-6790), Griffonia simplicifolia lectin I (Vector
Laboratories, Burlingame, CA), anti-ß-tubulin (Sigma, St Louis, MO) and
anti-COUP-TFI (Tang et al.,
2005) antibodies, as published previously
(Zhou et al., 1999), except
the secondary antibodies were conjugated to Alexa Fluors (594 red or 488
green, and used at 1:1000; Molecular Probes, Eugene, OR). Nuclei were
counterstained with DAPI (Vector Laboratories, Burlingame, CA). For BrdU
labeling, pregnant mice were injected with 100 µg/g BrdU (Amersham,
Piscataway, NJ) 3 hours prior to euthanasia. At least six cochleae from each
group were analyzed. The number of BrdU-positive and Ki67-positive cells in
the outer sulcus region of wild-type and COUP-TFI-/-
cochlea were counted from at least 12 sections from each of three
cochleae/genotype.
In situ hybridization
In situ hybridization was performed on E14.5 to E16.5 sections essentially
as published (Tang et al.,
2005). Non-radioactive antisense digoxigenin (DIG)-11-UTP (Roche,
Indianapolis, IN) riboprobes were synthesized from linearized plasmids, 1800
bp (mouse Jag1), 750 bp (mouse Lfng provided by Dr Sean
Egan, University of Toronto, Canada) and 1400 bp (mouse Hes5) cDNA
(kindly provided by Dr Tim Mitsiadis, Kings College, London, UK). At least
eighht samples were analyzed at each stage.
Quantitative real-time PCR
Total RNA was purified using RNeasy spin columns (Qiagen, Valencia, CA) and
treated with RNase-free DNase (Ambion, Austin, TX), before reverse
transcription into cDNA with oligo(dT) using MMLV-reverse transcriptase
(Ambion, Austin, TX), in accordance with manufacturers' protocols. A control
reaction lacking reverse transcriptase ensured fidelity of the amplified
products. Primers (Table 1)
were designed using Primer Express (Applied Biosystems, Foster City, CA).
SYBR-green quantitative PCR was performed using the ABI Prism 7000 Sequence
Detection System (Applied Biosystems, Foster City, CA). Reactions contained
12.5 ng template DNA, 12.5 µl 2xSYBR-green PCR Master Mix (Sigma, St
Louis, MO) and 50 nM primers, in a final volume of 25 µl. Cycling
conditions were: 95°C for 10 minutes to activate the Taq and then 40
cycles of sequential denaturation (95°C for 15 seconds) and
annealing/extension (72°C for 60 seconds). A housekeeping gene, Gapdh, was
also analyzed to normalize and correct for variations in RNA and/or cDNA
quality and quantity. Data analysis was performed using the ABI Prism 7000 SDS
Software (Applied Biosystems, Foster City, CA). Four cochleae from each group
were pooled together as one biological sample. At least three biological
replicates (each with three technical replicates) for each group were
analyzed. The Ct value, which represents the cycle number at which a
fluorescent signal rises statistically above background, was determined for
each transcript. After normalization with Gapdh, the change (
) in Ct
values was presented. In these analyses, the Ct value for each biological
replicate represented the average of the three technical replicates. The data
are presented as average Ct±s.d. Statistical significance (when
P<0.05) was determined by two-tailed t-test, with respect
to the corresponding dimethyl sulfoxide (DMSO group).
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), with some modifications. Briefly, cochleae were dissected
from E16.5 embryos in cold HBSS and cultured in DMEM, 10% fetal bovine serum
and N-2 supplement with antibiotics (all from Invitrogen, Carlsbad, CA). To
modulate Notch signaling, the -secretase inhibitor
N-[N-(3,5-difluorophenacetyl)-L-alanyl]-S-phenylglycine t-butyl ester (DAPT,
Calbiochem, San Diego, CA) at concentrations from 0.5 to 5 µM was used.
DMSO solvent was used as control. Explants were cultured for 5 days with daily
media changes. The numbers of outer and inner hair cell rows in the explants
were counted (at 400x magnification) in every fourth 7-µm thick
section previously labeled with myosin VIIa antibodies. An average of 12
sections from each explant and at least six explants from each group were
counted. Data are presented as mean±s.e.m. and statistical significance
(P<0.05) was determined by a paired t-test.
Western analysis
Myosin VIIa (Myo7a) expression in cochlear explants were determined by
western blot analyses. Cochleae lysates (30 µg) were fractionated by 7.5%
sodium dodecyl sulfate polyacrylamide gel electrophoresis
(Tang et al., 2005).
-Tubulin served as an internal control for protein loading. Four
cochleae from each group were pooled together as one biological sample. At
least three biological replicates for each group were analyzed.
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RESULTS |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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Paint-filling of the membranous labyrinths demonstrated that COUP-TFI-/- have a shorter cochlear duct (arrows in Fig. 1B, parts b,d,f) than wild-type controls (Fig. 1B, parts a,c,e). The cochlear duct lengths were similar at E13; however, the wild-type duct was longer than that of COUP-TFI-/- embryos by E15 and E17. We next determined the number of hair cells (IHC and OHC) at different regions of the flat-mounted, phalloidin-stained cochlear ducts. We found more hair cells per unit area in COUP-TFI-/- than in the wild type at the middle and apical regions, but because of the shorter duct, there was a reduction in total hair cells in the base and middle turns of COUP-TFI-/- cochlear ducts. In addition, despite having a shorter duct, the total number of hair cells in COUP-TFI-/- was similar to in wild type (Fig. 1C).
The COUP-TFI-/- organ of Corti exhibits continued
proliferation and ectopic hair cell differentiation Because there were
extra hair cells per unit area in the middle and apical turns of
COUP-TFI-/- organ of Corti, we analyzed the expression
domain of the cyclin-dependent kinase inhibitor p27, which demarcates a zone
of non-proliferation (ZNP) in the developing organ of Corti where hair cells
and support cells differentiate (Chen et
al., 2002). The ZNP was similar at the basal and middle turns, and
hair cells differentiated appropriately near the junction between the ZNP and
the inner sulcus region of proliferating cells in the wild-type and
COUP-TFI-/- sensory epithelia (arrowheads in
Fig. 2A-D, see also
Fig. 2I-L). However, at the
apical turn, the ZNP domain was consistently widened and encompassed the extra
hair cells in COUP-TFI-/- mice
(Fig. 2, compare double arrows
in 2F,H with 2E,G).
We next determined whether there were changes in proliferation. No
differences were found in BrdU labeling at time-points before E16.5 (data not
shown), after which there were extra BrdU-positive cells in the outer sulcus
region at the apical turns in the COUP-TFI-/- organ of
Corti (Fig. 2J, arrows).
Compared with the ZNP region in adjacent serial sections, the extra
BrdU-positive proliferating cells were found outside the ZNP in the lateral
region where Hensen's cells would differentiate in
COUP-TFI-/- epithelia (compare
Fig. 2J with 2L). The presence
of ectopic proliferating cells was corroborated by Ki67 staining, another cell
proliferation marker (Fig.
2M,N), and quantification was performed at this stage
(Fig. 2Q). At older stages
(P0), when the wild-type organ of Corti was postmitotic
(Ruben, 1967), some
Ki67-positive cells were still found at the apical turn in the
COUP-TFI-/- mutants
(Fig. 2O,P), suggesting that
proliferation in the COUP-TFI-/- sensory epithelium was
deregulated. Routine myosin VIIa immunolabeling to mark hair cells
unexpectedly revealed its ectopic expression in the supporting cell region in
both the basal and apical turns of COUP-TFI-/- epithelia
(asterisk in Fig. 2R-T). The
cells may represent displaced hair cells, as has been found in the pRB mutants
(Mantela et al., 2005).
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), and
loss-of-function mouse mutants of the Notch signaling pathway have alterations
in the number and rows of hair cells
(Brooker et al., 2006;
Kiernan et al., 2001;
Lanford et al., 1999;
Zhang et al., 2000;
Zheng et al., 2000;
Zine, 2003), we analyzed the
expression of crucial components in the Notch signaling pathway. We used in
situ hybridization to examine the expression of the Notch receptors:
Notch1, Notch 2 and Notch3; Notch ligands, Jag1, Jag2,
Delta-like1 and Delta3; Notch downstream target genes,
Hes1 and Hes5; and a modulator of Notch intracellular domain
cleavage, Lfng. Among these transcripts, Jag1, Hes5 and
Lfng showed altered expression in COUP-TFI-/-
cochleae (Fig. 3), and no
significant changes in the expression of other genes were seen (data not
shown). Jag1 was expressed in a broad domain in the sensory epithelium encompassing the presumptive hair and support cell precursor region (Fig. 3B) from the apex to the base in the wild-type E15.5 cochlea. As the sensory epithelium progressed in development in the apical to basal direction (Fig. 3B-D), the signal intensity within the center of this domain decreased and hair cells are seen to differentiate (Fig. 3B, arrow points to hair cells with large nuclei devoid of in situ signal). By contrast, there was a consistent reduction of Jag1 expression levels throughout the COUP-TFI-/- cochlear duct, and no significant changes in signal intensity were seen from apex to base (Fig. 3F-H).
At E16.5, the expression of Hes5 in the wild-type organ of Corti
was restricted to the hair cells and support cells, with the highest level in
the Deiter's supporting cells below OHCs
(Fig. 3I-L). In the
COUP-TFI-/- organ of Corti, Hes5 expression was
seen in a much more restricted domain, and consistently at a lower intensity
in the middle turn at E16.5 (Fig.
3M-P). By contrast, the expression domain of Lfng at
E14.5 was confined to a narrow region of the sensory epithelium in the
wild-type cochlear duct (Fig.
3R, circle), whereas in COUP-TFI-/- ducts, the
expression domain was significantly expanded
(Fig. 3U, circle). The COUP-TFI
expression domain in wild type (Fig.
3S) encompassed the expanded Lfng expression domain
within the sensory epithelium (compare arrowheads in
Fig. 3R,U with 3S). By E15.5,
Lfng expression was primarily confined to the morphologically defined
greater epithelial ridge (GER) (Sher,
1971) in the wild-type organ
(Fig. 3W-Y, arrows), whereas,
in the COUP-TFI-/- duct, Lfng exhibited a reduced
level and was detected in a widened domain encompassing the GER and lesser
epithelial ridges (LER) along the length of the duct
(Fig. 3A'-C',
arrows; compare expression in the middle to apical turns in 3B' to 3X,
and 3C' to 3Y). These changes in expression levels were confirmed by
quantitative real-time RT-PCR (data not shown).
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-secretase induces myosin VIIa expression in a cochlea organ culture) to determine the role of Notch signaling in regulating hair
cell differentiation in COUP-TFI-/- cochlea. We used an
inhibitor of -secretase, DAPT, to inhibit Notch signaling
(Dovey et al., 2001;
Geling et al., 2002), as
presenilin-dependent -secretase mediates proteolytic cleavage and
activation of the Notch intracellular domain
(De Strooper et al., 1999). We
used qRT-PCR and western blotting to analyze changes in expression of myosin
VIIa levels as a marker of hair cell differentiation
(Hasson et al., 1995). Myosin
VIIa transcripts (Fig. 4A) and
protein (Fig. 4B) were
increased in a dose-dependent manner upon addition of DAPT (0.5 to 5 µM) to
organ cultures, with a statistically significant increase at 5 µM DAPT with
respect to the DMSO control group.
Expression of COUP-TFI and COUP-TFII are unchanged by DAPT treatment
We next determined whether DAPT treatment affected COUP-TFI and its homolog
COUP-TFII in the in vitro organ culture model
(Fig. 4C). Addition of DAPT in
the cochlea cultures did not alter COUP-TFI and COUP-TFII
expression, even at the highest DAPT concentration that induced hair cell
differentiation (5 µM, Fig.
4A). The expression of COUP-TFI and COUP-TFII
transcripts was unchanged by DAPT treatment, even after normalizing to the
values for myosin VIIa to exclude the possibility of changes in
COUP-TFI and COUP-TFII expression as a consequence of hair
cell number changes induced by Notch inactivation.
Dose-dependent inactivation of Notch signaling induces hair cell differentiation in cochlea organ cultures
In order to confirm that DAPT treatment of the cochlea cultures resulted in
inhibition of Notch signaling, we studied the expression of Hes5, a
direct downstream target of Notch in hair cell differentiation
(Lanford et al., 2000;
Zine et al., 2001).
Hes5 expression was reduced with increasing concentrations of DAPT,
reaching statistical significance at 2.5 and 5 µM
(Fig. 4D). This reduction was
detected in both wild-type and COUP-TFI-/- cochleae.
Interestingly, there was also a dramatic reduction in Hes5 expression
in COUP-TFI-/- cochleae when compared with the wild-type
culture with addition of 5 µM DAPT, and when compared with the levels of
both wild-type and COUP-TFI-/- cochleae at 2.5 µM DAPT.
We expected to see changes in Hes1, as Hes1-/-
cochleae had an increase of IHCs (Zine et
al., 2001); however, the changes we detected by RT-PCR were not
statistically significant. This suggests that COUP-TFI-/-
cochleae were more sensitive to Notch inactivation.
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DISCUSSION |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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Suppression of Notch signaling induces hair cell and support cell differentiation
Notch signaling is important in cell fate determination, and for hair cell
and support cell differentiation (Brooker
et al., 2006; Daudet and
Lewis, 2005; Heitzler and
Simpson, 1991; Kiernan et al.,
2001; Lanford et al.,
1999; Zhang et al.,
2000; Zine et al.,
2000). Notch signaling plays at least two roles during inner ear
development. The Notch ligand Jag1 regulates neuroepithelial patterning
(Kiernan et al., 2001;
Tsai et al., 2001) and lateral
induction of sensory progenitors (Brooker
et al., 2006; Daudet and
Lewis, 2005; Kiernan et al.,
2006; Murata et al.,
2006). Within each patch of sensory progenitors, the ligands Dll1
and Jag2 act synergistically through Notch1 to mediate lateral inhibition,
restricting the proportion of cells that differentiate as hair cells or
supporting cells (Brooker et al.,
2006; Kiernan et al.,
2005; Murata et al.,
2006).
In COUP-TFI-/- cochleae, deregulated Notch signaling
included expansion of the Lfng expression domain to encompass the LER
and GER in the early sensory epithelium before hair cells and supporting cells
differentiated. Lfng is expressed in support cells, and
Lfng-/- mice have no overt hair cell phenotype but
mutation of Lfng acts epistatically with Jag2 to suppress
the production of extra IHCs (Zhang et
al., 2000). The fringe genes modulate Notch activation
(Bruckner et al., 2000;
Moloney et al., 2000) and,
thus, the expansion of the Lfng expression domain in
COUP-TFI-/- sensory epithelium should have resulted in
reduced Notch activation. Reduced Notch signaling was detected as a decrease
in the Notch target gene Hes5, which would have relieved the
inhibitory action of Notch on Math1 (Chen
et al., 2002; Kawamoto et al.,
2003; Woods et al.,
2004; Zheng and Gao,
2000). This resulted in hair cell differentiation in a widened ZNP
in the COUP-TFI-/- cochleae (see
Fig. 6). More studies will be
needed to understand the full potential of elevated LFNG in modulating hair
cell and support cell differentiation.
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-secretase
inhibitor modulates Notch signaling and induces hair cell differentiation.
DAPT has been shown to regulate -secretase in a dose-dependent manner,
and hence Notch signaling in mouse kidney
(Cheng et al., 2003) and thymus
cultures (Doerfler et al.,
2001; Hadland et al.,
2001), and in whole animals
(Dovey et al., 2001;
Geling et al., 2002). Although
-secretase modulates the activation of several proteins
(Kimberly and Wolfe, 2003),
inhibition of -secretase produces phenotypes similar to those of Notch
mutations in zebrafish (Geling et al.,
2002) and Drosophila
(Micchelli et al., 2003),
strongly suggesting that the disruption of Notch signaling is the dominant
effect of DAPT treatment. Using increasing concentrations of DAPT in cochleae
explants, we have discovered that Notch regulates hair cell differentiation in
a dose-dependent manner in the mouse cochlea. The concentrations of DAPT used
were not toxic and did not seem to modify levels of genes non-specifically, as
the expression levels of -tubulin, COUP-TFI and COUP-TFII were
unaltered. Pharmacological suppression of Notch activation with a different
-secretase inhibitor demonstrated a Notch-dependent regulation of
excess hair cell development, primarily in the middle to basal turns
(Yamamoto et al., 2006). It is
unclear whether this difference of where in the duct excess hair cells
differentiate is due to the different -secretase inhibitor used, the
stage of culture, or both. Importantly, high doses of DAPT further attenuated
Notch signaling to produce a greater number of hair cells in the apex in
COUP-TFI-/- than in wild-type cochleae. Consistent with
our results, genetic redundancy and gene-dose effects of Notch signaling
components have been documented for several Notch signaling mutants that
produce excess hair cells in the organ of Corti
(Kiernan et al., 2005;
Zhang et al., 2000;
Zine et al., 2000), further
indicating that Notch signaling was not completely suppressed in
COUP-TFI-/- mice in vivo.
Conditional deletion of Jag1 results in loss of hair cells, particularly
OHCs (Brooker et al., 2006;
Kiernan et al., 2006), thus
its reduction does not explain the excess hair cells in the
COUP-TFI-/- cochlea. A comparison with the Dll1
conditional-deletion cochlea reveals phenotypical similarities to
COUP-TFI-/- that include excess OHCs and an occasional
duplication of IHCs, with expansion of the ZNP/prosensory region from the
middle turn to apex and a shortened cochlear duct. In addition, deletion of a
Notch downstream effector, Foxg1, produced a large increase in hair
cells and supporting cells in the mid-apical turn, but it was unclear whether
there was an equivalent number of hair cells and support cells because the
organ of Corti was significantly disrupted
(Pauley et al., 2006). These
similarities further support our contention that COUP-TFI modulates hair cell
and support cell development by regulating Notch signaling.
It has been suggested that signals required for hair cell differentiation
are conveyed within the plane of the epithelium along the basal-to-apical axis
of the developing cochlea (Montcouquiol
and Kelley, 2003). Our data suggest that the potential for hair
cells and support cells to differentiate depends on their position in the
cochlear duct, and that those in the apical region have the greatest
susceptibility to Notch signaling. This may explain why it is not uncommon to
find more than the typical three rows of outer hair cells in the apical region
of the wild-type cochlear duct in vivo. COUP-TFI protein and mRNA expression
are highest at the apical turn during hair cell differentiation
(Tang et al., 2005), further
supporting the hypothesis that COUP-TFI function is required to regulate hair
cell and support cell differentiation in a Notch-dependent and
position-dependent manner.
Relationship of the shortened cochlear duct and excess hair cells
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
process of convergent-extension is suggested to promote outgrowth and
morphogenesis of the avian basilar papilla
(Goodyear and Richardson,
1997) and the mammalian cochlear duct
(Chen et al., 2002). The lack
of longitudinal extension of the COUP-TFI-/- duct may have
resulted in a short cochlear duct, and displacement and accumulation of
precursor cells that differentiated at an inappropriate position but still
resulted in a similar total number of the hair cells as in the wild type.
Alternatively, the ectopic differentiation of support cells into hair cells in
COUP-TFI-/- apex, which may have occurred at the expense
of the support cells, was sufficiently compensated by continued proliferation
in the sensory epithelium and resulted in a relatively well-patterned organ of
Corti with corresponding numbers of hair cells and support cells. This
hypothesis is not without precedent: hair cells continued to be produced
postnatally because of an uncontrolled cell cycle and continued proliferation
in cyclin kinase inhibitor p27-/- mutants
(Chen and Segil, 1999), and
Dll1/Jag2 double mutants have supernumerary hair cells that arose
through a switch in cell fate but also have prolonged cell proliferation
(Kiernan et al., 2005). Thus,
excess hair cell differentiation may hinder the process of
convergent-extension, or defects in convergent-extension may promote excess
hair cell differentiation at the middle to apex. Nevertheless, inhibiting
lateral inhibition has similar effects, causing the production of excess hair
cells and support cells and a shortened cochlear duct; subtle differences may
occur depending on the method/target of mutation.
|
),
over- or ectopic expression (Chen et al.,
2002; Kawamoto et al.,
2003; Woods et al.,
2004; Zheng and Gao,
2000), neurogenin1 (Ma et al.,
2000; Matei et al.,
2005) and Foxg1
(Pauley et al., 2006)
mutations, Notch overexpression (Daudet
and Lewis, 2005) and underexpression
(Brooker et al., 2006;
Kiernan et al., 2005;
Kiernan et al., 2006;
Yamamoto et al., 2006;
Zine et al., 2001),
localization of cell-specific and timing of Notch activation
(Murata et al., 2006),
retinoid agonist and antagonist treatments in culture
(Kelley et al., 1993;
Raz and Kelley, 1997), cell
ablation studies (Kelley et al.,
1995), and other studies, have suggested ways by which
supernumerary hair cells and/or supporting cells may arise. Extra cells may
arise by: (1) expansion of the precursor cell pool
(Daudet and Lewis, 2005); (2)
secondary division of precursor cells
(Brooker et al., 2006;
Chen et al., 2002;
Kiernan et al., 2005;
Kiernan et al., 2006); (3)
proliferation of supporting cells that then transdifferentiate into hair cells
(Malgrange et al., 1998;
Zheng and Gao, 2000); and (4)
the recruitment and differentiation of adjacent non-sensory cells, including
cells from the GER and outer sulcus
(Brooker et al., 2006;
Goodyear and Richardson, 1997;
Woods et al., 2004;
Yamamoto et al., 2006;
Zheng and Gao, 2000).
A functional hierarchy of Notch and COUP-TFI regulation of hair cell and
support cell differentiation is presented in
Fig. 6. Our data suggest that
the expansion of Lfng expressing cells and reduced Notch signaling in
the precursor cell pool contributed to the increase in hair cell and support
cell numbers in COUP-TFI-/- cochlea. The fact that
COUP-TFI transcripts were unaffected by DAPT inhibition of Notch
signaling suggests that COUP-TFI acts in parallel or upstream of Notch to
regulate hair cell and support cell differentiation. COUP-TFI can directly
regulate cell proliferation, differentiation and migration in different
tissues. For example, the Drosophila homolog, seven-up,
controls cell proliferation in the Malpighian tubules
(Kerber et al., 1998);
overexpression of COUP-TFI in neurons blocks morphological differentiation
(Neuman et al., 1995); and
COUP-TFI regulates tangential cell migration in the developing forebrain
(Tripodi et al., 2004). As
COUP-TFI transcripts and protein co-localize with Lfng and
Jag1 in the sensory epithelium
(Tang et al., 2005), COUP-TFI
might directly modulate the transcription of these Notch component genes and,
thus, may constitute a regulatory mechanism to control hair cell and support
cell numbers.
In summary, the orphan nuclear receptor COUP-TFI plays a crucial role in regulating cochlear hair and support cell differentiation. Inactivation of the COUP-TFI gene results in supernumerary hair cells and support cells, especially at the apical turn, which is also the region most susceptible to Notch inactivation. We conclude that COUP-TFI plays an important role in modulating Notch-mediated hair cell differentiation.
|
ACKNOWLEDGMENTS |
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Footnotes |
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REFERENCES |
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-COUP-TFI) in wild-type sensory epithelium at E14.5 (arrowhead marks a
hair cell). Scale bar: in A,E,I,M,Q,T,V,Z, 200 µm; in
B-D,F-H,J-L,N-P,R,S,U,W-Y,A'-C', 50 µm.
