susan hayes, branden r. nelson, brian buckingham and thomas a. reh- notch signaling regulates...
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Notch signaling regulates regeneration in the avian retina
Susan Hayesa, Branden R. Nelsona, Brian Buckinghamb, and Thomas A. Reha
aDepartment of Biological Structure, 357420 Health Science Center, University of Washington, School of
Medicine, Seattle, WA 98195, USA, Phone: (206) 543-8043, Fax: (206) 543-1524, e-mail:
bMedical Student Training Program, Box 357470, University of Washington, School of Medicine, Seattle,
WA 98195, USA
Abstract
The chicken retina is capable of limited regeneration. In response to injury, some Mller glia
proliferate and de-differentiate into progenitor cells. However most of these progenitors fail to
differentiate into neurons. The Notch pathway is upregulated during retinal regeneration in both fish
and amphibians. Since the Notch signaling pathway maintains cells in a progenitor state duringdevelopment, we hypothesized that a persistently active Notch pathway might prevent a more
successful regeneration in the chick retina. We found Notch signaling components are upregulated
in the proliferating progenitors. We also found that blocking the Notch pathway while Mller glia
are de-differentiating into progenitor cells, prohibits regeneration; conversely, blocking the Notch
pathway after the progenitors have been generated from the Mller glia, caused a significant increase
in the percentage new neurons. Thus, Notch signaling appears to play two distinct roles during retinal
regeneration. Initially, Notch activity is necessary for the de-differentiation/proliferation of Mller
glia, while later it inhibits the differentiation of the newly generated progenitor cells.
Keywords
retina; regeneration; Notch; Mller glia
INTRODUCTION
In response to damage, Mller glia in the chick and fish retina can re-enter the cell cycle,
express progenitor genes and regenerate neurons (Fischer, 2005; Fischer et al., 2002; Fischer
and Reh, 2001; Fischer and Reh, 2002; Fischer and Reh, 2003; Raymond et al., 2006; Yurco
and Cameron, 2005). In the fish retina, the Mller glial derived progenitors go on to
successfully regenerate nearly all the damaged retina (Raymond et al., 2006; Yurco and
Cameron, 2005). However, regeneration in the bird is much less successful, and the majority
of the progenitor cells derived from Mller glial cell divisions remain undifferentiated (Fischer
and Reh, 2001), expressing the markers of progenitor cells, rather than differentiating as either
Mller glia or neurons.
The failure of the majority of progenitors to differentiate into neurons in the regenerating chick
retina suggests that some factors expressed in the regenerating retina may limit neuronal
differentiation in these cells. A potential candidate for this block in differentiation is the Notch
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NIH Public AccessAuthor ManuscriptDev Biol. Author manuscript; available in PMC 2008 June 1.
Published in final edited form as:
Dev Biol. 2007 December 1; 312(1): 300311.
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pathway. During retinal development, the Notch signaling pathway maintains progenitor cells
in an undifferentiated state; constitutive activation of the Notch pathway prevents cells from
differentiating as neurons, and instead they either differentiate into Mller glia, or remain in a
progenitor state (Bao and Cepko, 1997; Dorsky et al., 1997; Henrique et al., 1997; Jadhav et
al., 2006). The Notch receptor is activated by the ligands, Delta (Dll1-4) or Serrate 1,2 (known
as Jagged 1,2 in mammals). Binding of the Notch receptor to its ligand induces two proteolytic
cleavages of Notch. The second cleavage, mediated by a -secretase, cleaves the intracellular
domain (ICD), allowing it to translocate to the nucleus where it can activate one or moredownstream target genes of the hairy/enhancer of split family (Hes) (Bray, 2006). Hes genes
inhibit expression of proneural genes (Chen et al., 1997; Sriuranpong et al., 2002), preventing
neuronal differentiation. Inhibition of Notch signaling by a dominant-negative Dll1 or the -
secretase inhibitor, DAPT, in developing retina promotes neuronal differentiation (Henrique
et al., 1997; Nelson et al., 2006; Nelson et al., 2007).
Recent studies have implicated the Notch signaling pathway in retinal regeneration. A study
in fish retina has shown that after injury, Notch and some of the associated pathway components
are expressed in the Mller glia, which are proliferating and de-differentiating into progenitor
cells (Raymond et al., 2006; Sullivan et al., 1997). Since the Notch signaling pathway is known
to maintain the progenitor state in developing retina, we hypothesized that the Notch pathway
might be persistently active during regeneration in the chick retina and thus prevent more
successful regeneration. To explore this possibility, we analyzed Notch pathway componentsfollowing neurotoxic damage and used a small molecule inhibitor of the Notch pathway,
DAPT, to test for a requirement for Notch at various times during the regeneration process.
In this study, we find that Notch activity has two distinct roles in retinal regeneration. After
neurotoxic damage, Notch signaling components are upregulated in the proliferating Mller
glia. Activation of the Notch pathway is necessary for the de-differentiation process; inhibiting
the Notch pathway soon after neurotoxic damage reduces the percent of Mller glia that re-
express progenitor genes and reduces the overall proliferative response. However, later in the
regeneration process we find that Notch activity prevents more successful regeneration:
inhibiting Notch signaling after the Mller cells have already de-differentiated causes a
significant increase in the extent of neuronal differentiation.
MATERIALS AND METHODS
Animals
The use of animals in this study was in accordance with the guidelines established by the
University of Washington, IACUC, and the National Institute of Health. Newly hatched
leghorn or hyline brown chickens (Gallus gallus domesticus) were obtained from H&M
Highline International (Seattle, WA).
Quantitative Polymerase Chain Reaction Analysis
Quantative polymerase chain reaction (QPCR) was performed as described (Dorsky et al.,
1997; Nelson et al., 2006; Nelson et al., 2007). Intraocular injections of NMDA or saline were
given to P1 chicks. Animals were sacrificed and eyes were dissected at the indicated time
points. Three pairs of eyes were used per time point. The eyes were bisected, separating theperipheral half from the central half. The central retina halves were frozen, homogenized, and
cells were lysed with Trizol (Invitrogen). Genomic DNA was digested by DNAse (Invitrogen)
and RNA was purified using an RNEasy column (Qiagen). cDNA was generated by oligo-dT
primed reverse transcription reaction with Superscript II reverse transcriptase (Invitrogen); an
RT-minus control was included for each sample. Quantative PCR was performed using an
Opticon DNA Engine (Bio-Rad). The cDNAs were normalized to GAPDH levels. The
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following primer sets were used: cGAPDH forward 5 CAT CCA AGG AGT GAG CCA AG,
reverse 5 TGG AGG AAG AAA TTG GAG GA; cPCNA forward 5
GATGTGGAGCAGCTT GGA AT, reverse 5 CCAATGTGGCTGAGGTCTCT, Cash1
forward 5 AGGGAACCACGTTTATGCAG, reverse 5 TTATACAGGGCCTGGTGAGC,
Notch1 forward 5 TTCCCAGCACAGCTATTCCT; reverse 5
CCCACTGGGTCTCACTTGAA; cHes-5 forward 5 CCAGAGACACCAACCCAACT,
reverse 5 CAGAGCTTCTTTGAGGCACC : cHes1 forward 5
GAAGTCCTCCAAACCCATCA, reverse 5 AGGTGCTTCACCGTCATCTC cHey-2forward 5 TCTCCTTCACCAGCACCTTC, reverse 5 GGCTGGATGAGGCTGACAC;
cHey-1 forward 5 CGACTCGTGTCTCACCTCAA, reverse 5
GTGAGGGTGATGTCCAAAGG; cDeltex2 forward 5CAATGAGAAGGGCAGAAAGG,
reverse 5 GGTGGATCTCATTCCACACC; cDNER forward 5
TCAGTGGACACGGGATTAGA, reverse 5 CATCAACAAACAACTCAAACCA; cDelta1
forward 5 CACTGACAACCCTGATGGTG, reverse 5 TGGCACTGGCATATGTAGGA;
cDll4 forward 5 CAAATTGCCGATTCTGTCCT, reverse 5
TGCTGTCGATGCTTGGTAAGA; cFoxN4 forward 5 GCTGCCATTCATAGGAGCAT,
reverse 5CTGGGTCTGGATCTGGTGAT; cSox2 forward 5
AGGCTATGGGATGATGCAAG, reverse 5 GTAGGTAGGCGATCCGTTCA; cPEA3
forward 5 ACCTGTGCAGATTCACCTC, reverse 5 GTACGGGACAGGCACTTCTC; and
cGeminin forward 5 TGCATTATTTGACCAGCATGA, reverse 5
TGTTTCTTGGTTGGATTCGTC.
In Situ Hybridization
In situ hybridization was essentially performed as described (Bermingham-McDonogh et al.,
2006; Nelson et al., 2006). Posthatch eyes were dissected in HBSS; the lens and vitreous humor
were removed. Sections from stage 25 embryonic heads were also stained in parallel, to serve
as controls for the probes. In situ probes were synthesized by in vitro transcription reaction.
The DNA template was digested with DNAse and the probe was precipitated with ethanol. The
probe was resuspended in 0.25% SDS in TE buffer. Notch1 plasmid used to make probe came
from D. Henrique (Henrique et al., 1997) and Hes5 plasmid was described in (Nelson et al.,
2006).
Intraocular InjectionsThe left eye was injected with 20 uL of 0.1 M NMDA. The right eye was injected with 20 L
0.9% saline. For immunohistochemistry and in situ studies, both eyes were injected with 20
L 0.1 10 mg/mL BrdU. Where indicated, eyes were injected twice (4 hours between
injections) with 2.5 uL DMSO or 10 mM DAPT (Sigma). (DAPT (N-[N-(3,5-
difluorophenacetyl)-L-alanyl]-S-phenylgly cine t-butyl ester)).
Immunohistochemistry
A standard immunohistochemical staining protocol was performed as described (Fischer and
Reh, 2000). Antibodies used included: rat anti-BrdU (1:100, Accurate), mouse anti-Hu (1:100,
Monoclonal Antibody Facility, University of Oregon), rabbit anti-Calretinin (1:1000, J.H.
Rogers, University of Cambridge), mouse anti-Vimentin (1:50, DSHB), mouse anti-Islet (1:20,
DSHB), rabbit anti-Pax6 (1:500, Covance), mouse anti-Visinin (1:2000, DSHB) and goat anti-Sox2 (1:1000, Santa Cruz). When rat anti-BrdU antibody was used, slides were treated with a
100Kunitz/mL DNAse (Sigma). Alexa-488 and Alexa-568 secondary antibodies (Invitrogen)
used at 1:500. Alexa-350 (Invitrogen) secondary antibodies were used at 1:80. Apoptotic cells
were detected using terminal deoxynucleotidyl transferase (TdT) (Promega) to transfer Alexa
Fluor 546-14-dUTP (Molecular Probes) to strand breaks of cleaved DNA.
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Counts on Flatmounts
Retinas were flatmounted, fixed and immunolabelled for BrdU. Confocal slice images of retina
flatmounts were taken on a Zeiss confocal microscope. ImageJ (Rasband, 1997-2006)
including extended depths of field plug-in (Forster et al., 2004) were used to flatten image
stacks, threshold and count BrdU positive nuclei per area across the complete retinal depths.
A one tailed Mann-Whitney test was used to determine significance of changes in BrdU
incorporation between control DMSO and DAPT injected eyes; p < 0.05 was considered
significant.
RESULTS
The Notch signaling pathway is upregulated during chicken retinal regeneration
As noted above, in response to toxins, such as NMDA, some chicken Mller glia cells
proliferate and express genes normally only expressed in embryonic progenitors, and
approximately 10% of these progenitor cells go on to differentiate into new neurons. To
determine whether Notch pathway genes are involved in the regenerative process, we used Q-
PCR to measure changes in expression of Notch signaling components following NMDA
treatment in the posthatch chick retina. The left eyes of P1 chicks were injected with NMDA,
while the right eyes were injected with saline and served as controls. We define P1 as the day
the chicken hatched. NMDA and control retinal mRNA was harvested from P2, P3, P4 and P8chickens. To confirm that the NMDA injection elicited a regenerative response, we measured
changes in proliferating cell nuclear antigen (PCNA) and four additional neural progenitor-
specific genes: geminin, Cash1, Pea3 and FoxN4 (Del Bene et al., 2004; Jasoni et al., 1994;
Li et al., 2004; McCabe et al., 2006). We also analyzed expression of Sox2, which is known
to be in progenitor cells, but is also expressed in Muller glia (Taranova et al., 2006). These
genes were all up-regulated in the first few days after NMDA induced damage. Cash1 is
normally only expressed in progenitor cells, but was previously shown to be re-expressed in
the regenerating retina (Fischer and Reh, 2001). We confirmed that Cash1 increased after
damage and was maximally expressed at P4 (Fig. 1H). We found the greatest change in PCNA
occurred at P4, which coincides with what was previously determined (Fischer and Reh,
2003) to be the peak of proliferative response (Fig. 1D, Sup Fig. 1). These data show that
NMDA induces a pattern of gene expression at least partly similar to that observed during
normal embryonic development.
The Notch pathway is critical for normal embryonic development (see Introduction), and so
we investigated whether the genes in this pathway were also up-regulated in the NMDA
damaged retina. We carried out a time course for Notch1 and Hes5 (a critical downstream
target of the Notch ICD), and found that both genes reached a peak in expression at P4 (Fig.
1F, 1G). At this same time point, we also analyzed other components of this pathway. We
found that other members of the Hes and Hey family of Notch target genes, Hes1, Hey2 and
Hey1, were not significantly different in the NMDA treated retinas as compared with the saline
treated retinas. We also tested for changes in Deltex, and the Notch ligands: DNER, Dll1, and
Dll4, but did not see significant changes in their expression (data not shown). These results
show that at least some components of the Notch pathway are up-regulated following NMDA
induced retinal damage.
Components of the Notch pathway are expressed in the regenerating cells
We used in situ hybridization, to determine which cells up-regulate Notch1 and Hes5 during
retinal regeneration. The probes were tested in embryonic retina to ensure they gave specific
labeling similar to that which has been previously reported (Fischer and Reh, 2001; Henrique
et al., 1997; Nelson et al., 2006) (Sup Fig.2). We also performed in situ hybridization with the
corresponding sense probes; the sense probe gave a background staining, but not the distinctive
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staining pattern seen with the anti-sense probe (Sup Fig. 2). In normal posthatch chick eyes
(saline-injected), Notch1 was expressed in a small cluster of cells at the ciliary marginal zone
(CMZ) (Fig. 2A), similar to that reported in other non-mammalian vertebrates (Perron et al.,
1998). In addition, faint Notch staining was observed in the center of the inner nuclear layer
(INL; Fig. 2B). The position of the Notch1 positive cells, in the middle of the INL, suggested
that they might be Mller glia. Previous studies have described Notch1 expression in mouse
Mller glia (Furukawa et al., 2000). To confirm that Notch positive cells were Mller glia, we
labeled the sections with an antibody to vimentin, a Mller glial marker, following in situhybridization. Although the expression levels of Notch mRNA were very low, we found that
some of the Notch positive cells were also vimentin positive (Fig. 2C-F, arrow).
After NMDA treatment, the in situ hybridization for Notch1 mRNA showed an overall increase
in the intensity of labeling (Fig. 2F,G). Co-labeling the in situ hybridizations with antibodies
to BrdU and vimentin allowed us to determine whether the Notch expressing cells were Mller
glia and/or their progeny. All of the BrdU labeled cells were also labeled with vimentin,
confirming previous reports (Fischer and Reh, 2001); in addition, most, if not all, of the Notch1
expressing cells were also labeled with vimentin (Fig. 2G-J, arrow). However, we found
examples of cells that expressed Notch1 (Fig. 2G-J. asterisk), but did not label with BrdU,
suggesting either that our BrdU pulse was not sufficient to label all of the Mller glial-derived
progenitors, or alternatively that Mller glia can up-regulate Notch1 without re-entering the
cell cycle.
We looked to see if the Notch target gene, Hes5, was also expressed in a similar pattern. In the
CMZ of normal eyes, there was a small cluster of Hes5 expressing cells (Fig. 3A), similar to
those that express Notch1 (Fig. 2A). We could not detect Hes5 staining in the central region
of the normal (saline injected) retina (Fig. 3B). The inability to detect Hes5 staining was not
due to a problem with the probe, as the same probe on embryonic control slides detected robust
Hes5 expression (Sup Fig. 2). In the NMDA treated eye, scattered cells in the INL expressed
Hes5 (Fig. 3C). We found that nearly all of the Hes5 expressing cells were also labeled with
BrdU and vimentin (Fig. 3D-G). We did however find a few examples of cells that expressed
Hes5 (Fig. 3 D-G, asterisk), but did not label with BrdU, suggesting again that either our BrdU
pulse was not sufficient to label all of the Mller glial-derived progenitors, or alternatively that
Mller glia can up-regulate Hes5 without re-entering the cell cycle. These data are consistent
with the QPCR results, demonstrating that some of the proliferating cells in NMDA treatedretinas up-regulate Notch1 and Hes5. The function of these two genes during normal retinal
development and their expression during regeneration in fish suggests that this same molecular
pathway is re-utilized during retinal regeneration in birds.
Notch Signaling is Necessary for Regeneration
The up-regulation of Notch signaling components correlates with the proliferation and
transition of Mller glia into progenitor cells. To determine whether the Notch pathway is
necessary for the proliferation and/or transition of Mller glia to progenitor cells, we blocked
the Notch pathway using a small molecule inhibitor of-secretase, DAPT, as outlined in Fig.
4A. Application of DAPT, is a well-established method for inhibiting the Notch pathway.
Previous studies have shown that DAPT and inhibitory mutations in the Notch pathway have
the same effect on development (Geling et al., 2002;Micchelli et al., 2003;Nelson et al.,2006;Nelson et al., 2007).
We injected eyes with NMDA at P1, DAPT or DMSO (vehicle control) at P2 and BrdU at P3.
We found that injection of DAPT significantly inhibited the Hes5 up-regulation caused by the
NMDA injection (Sup Fig3A). We predicted that if Notch signaling is necessary for Mller
glial de-differentiation, we would see a decrease in the number of BrdU labeled cells. We
quantified the amount of BrdU staining in flatmount retinas from chickens sacrificed at P8
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(compare 4B and 4C), there was a significant decrease in proliferation in the DAPT treated
retinas (about 65% less, p < 0.019, Fig. 4D). The decline in BrdU labeled cells in the DAPT
treated retina was consistent with the hypothesis that Notch activity is necessary for the
transition of Mller glia to proliferating progenitor cells; however, it is possible that DAPT
prevented the NMDA-induced damage. To test for this alternative explanation of the result,
we labeled the DMSO and DAPT treated retinas with an apoptotic marker. We found NMDA
induced apoptotic cells in both treated and control retinas, indicating that the difference in
BrdU incorporation was not due to a lack of apoptosis induced by the NMDA in the DAPTtreated retinas (Sup Fig.3B-C).
To determine if DAPT treatment was inhibiting the dedifferentiation process, we performed a
similar experiment and counted the percentage of proliferating cells that also stained with a
progenitor marker. We predicted that if Notch signaling is necessary for the de-differentiation
of Muller glia into progenitors, fewer cells would co-stain for BrdU and a progenitor marker
following DAPT treatment. In the NMDA treated posthatch chick retina, the progenitor cells
express Pax6 (Fischer and Reh, 2001). We treated chicks with NMDA at P1, DAPT or DMSO
(vehicle control) at P2, BrdU at P3 and sacrificed the animals 4 hours after the BrdU pulse.
We sacrificed the animals at this early time-point because most of the de-differentiation occurs
2-3 days after NMDA injection and therefore most of the BrdU positive cells are the new
progenitors (Fischer and Reh, 2001). If Notch signaling is necessary for de-differentiation,
fewer cells would co-stain for Pax6 and BrdU in the DAPT treated retinas. We found about a25% decrease in the number of BrdU/Pax6 double-labeled cells (de-differentiating Mller glia)
in the DAPT treated retinas compared to DMSO treated retinas (p < 0.0364, Fig. 4E-I). These
data support the conclusion that inhibition of the Notch pathway early in the regeneration
process inhibits the de-differentiation of Mller glia into retinal progenitors.
Downregulation of Notch Signaling Enhances Retinal Regeneration
The data from the early treatment with DAPT indicates that activation of the Notch pathway
may be necessary for Mller cells to de-differentiate, and become neurons. However, previous
studies have also found that once the Mller glia de-differentiate into progenitor cells, only a
small percentage of the cells go on to differentiate into neurons, while most of the cells remain
in an undifferentiated state. Our time-course data (Fig. 1) shows that the expression of Notch
signaling components persists until at least P8. Thus, we hypothesized that the maintained
activation of Notch in these cells may prevent more of the progeny of the Mller glia from
differentiating into neurons. To test this hypothesis, we injected eyes with NMDA at P1, BrdU
at P3, and DAPT or DMSO (vehicle control) at P4, and sacrificed the animals at P8 (Fig 5A).
The eyes were analyzed by immunohistochemistry for neuronal markers (Hu, calretinin, and
islet) and BrdU. Since normally at this stage, all the retinal cells are postmitotic, we used BrdU
to label the newly generated retinal neurons.
DAPT treatment at P4, led to an increase in the number of newly generated neurons (Fig. 5).
Cells labeled with BrdU and several neuronal markers (Hu (ganglion and amacrine cells),
calretinin (ganglion, amacrine, horizontal cells), islet (ganglion, amacrine, bipolar cells) and
visinin (cone photoreceptors)) were more commonly observed in the DAPT treated retinas
compared to retinas from the group that received DMSO. There were roughly 3.5x more new
Hu (Fig. 5B), 2x more new calretinin (Fig. 5C) and 4.7x more islet (Fig. 5D) labeled neuronsin the DAPT treated retinas than in the DMSO treated retinas. The number of visinin and BrdU
labeled cells was extremely rare (Fig. 5E). Out of seven DMSO treated retinas, we found one
retina that had one new visinin cell. Out of eight DAPT treated retinas, we found three retinas
that had new visinin cells. The occurrence of new visinin cells was too rare to reach statistical
significance. The overall number of BrdU labeled cells was similar between the DAPT treated
group and the DMSO control (Sup. Fig 4). Quantification of the number of cells that were
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double-labeled with BrdU and the various neural markers is shown in Fig. 5E. We also looked
for any cells that coexpress the neural marker, Hu, and the Muller glia marker, CRALBP, to
determine whether the Muller glia undergo an abnormal plasticity. Out of 2,429 Hu positive
cells, in 7 NMDA treated birds (4 DAPT treated and 3DMSO treated) we did not find any cells
that coexpressed Hu and CRALBP (Sup. Fig 5).
These results indicate that inactivation of the Notch pathway led to an increase in the neural
differentiation of the Mller glial-derived progenitors. We analyzed the DAPT treated retinasto determine whether there was a concomitant decrease in the number of Mller-glial derived
progenitors, when compared to the DMSO-treated control retinas. We identified these de-
differentiated progenitor cells as cells that were triple labeled for BrdU, Sox2 and Pax6. Sox2
labels Mller glia and progenitors (Ellis et al., 2004). Therefore one would predict that de-
differentiated Mller glia would co-express Sox2 and Pax6. We found a significant decline in
the number of progenitor cells in the DAPT treated retinas compared to the DMSO treated
retinas (about 45% less, p < 0.0317, Fig. 6), consistent with the hypothesis that Notch signaling
maintains the progenitors from differentiating in the toxin treated retina.
The inhibition of Notch with DAPT thus leads to a shift in the BrdU labeled population from
a progenitor state to neuronal differentiation. To determine whether the new neurons persist in
the retina, we analyzed some birds after survival periods of up to two weeks following the
NMDA treatment (Sup. Fig 4). We found that most of the new neurons do not survive afterone week. Two weeks after the NMDA treatment there was a significant decrease in the total
number of BrdU labeled cells in both the DMSO and DAPT treated retinas. However among
the remaining BrdU labeled cells, we found that a significantly higher percentage co-labeled
with BrdU and Hu in the DAPT treated retinas as compared to the DMSO treated retinas (about
1.97-times more BrdU and Hu labeled cells in DAPT compared to DMSO, p < 0.05). Thus,
although most of the newly generated neurons do not persist, the effects of DAPT treatment
are still present two weeks after the NMDA-induced damage.
DISCUSSION
The chick retina is capable of limited regeneration following neurotoxic damage. In this study,
we have investigated the role of Notch in the regulation of regeneration in the posthatch chick
retina. We find that 1.) components of the Notch pathway are up-regulated in Mller glia afterretinal damage; 2.) this up-regulation of Notch is important for the de-differentiation process,
since inhibition of Notch signaling soon after damage leads to a reduction in the number of
progenitors produced by the Mller cells; and 3.) sustained Notch activity limits the process
of regeneration, since inhibition of Notch signaling late in the process leads to an increase in
the number of new neurons produced by the Mller glial-derived progenitors. Taken together,
our results implicate Notch signaling at two key steps in the process of regeneration in the
retina, as outlined in Figure 7.
Previous studies have shown that Notch pathway components are expressed in adult
mammalian brain regions that retain neurogenic and regenerative capability, such as the
subventricular zone, dentate gyrus, and the rostral migratory stream (Stump et al., 2002). In
addition, in lower vertebrates, Notch and related components of the pathway are expressed in
the neurogenic zone of the mature retina, the ciliary marginal zone (Perron et al., 1998;Raymond et al., 2006). The most peripheral region of the chicken retina also contains a CMZ
(Fischer and Reh, 2000), similar to that of cold-blooded vertebrates, and the results of our study
show that Notch1 and Hes5 are localized to this zone in the posthatch chick retina.
Our results also show that Mller glia normally express a low level of Notch1, and that this
gene is rapidly up-regulated following damage, reaching a peak three days after the toxin
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treatment, correlating with the peak of progenitor proliferation. During retinal regeneration,
we were also able to detect expression of Hes5, a key downstream Notch effector, in the
responsive Mller cells. These data are consistent with recent findings in other parts of the
nervous system that show an increase in Notch signaling following damage. For example,
following a cortical stab wound, the Notch pathway is activated in the subventricular zone
(Givogri et al., 2006). In addition, Raymond et al have reported an increase in Notch expression
in the regenerating zebrafish retina (Raymond et al., 2006). The Notch pathway was also
recently shown to play a role in retinal regeneration in newt. The newt regenerates its retinafrom the pigment epithelium. The pigment epithelium must first dedifferentiate into retinal
progenitor cells, which go on to generate a new retina, and the de-differentiation process is
accompanied by an increase in Notch expression (Nakamura and Chiba, 2006). It is interesting
that regenerating newt and chick retinas, which have a very different source of regeneration,
both require Notch during the regeneration process; this provides further evidence that the
Notch pathway regulates differentiation of the progenitor cells, regardless of their source.
Although it has been shown previously that Mller glia retain stem cell-like properties and are
the source of regenerated retinal neurons in fish and posthatch chickens (Fischer et al., 2002;
Fischer and Reh, 2001; Fischer and Reh, 2002; Fischer and Reh, 2003; Raymond et al.,
2006), the mechanisms by which Mller glia de-differentiate into neurogenic progenitors is
not understood. Our results show that Notch signaling is necessary for the de-differentiation
and proliferation of Mller glia, since blocking Notch results in reduction of both proliferationand progenitor gene expression. A recent study in an ischemically injured rat brain, also
suggests that Notch signaling may be necessary for progenitor activation after trauma. In this
study, administering the ligand, Dll4, activated Notch signaling; as a result, there were more
newly generated precursor cells and the rats had improved motor skills (Androutsellis-
Theotokis et al., 2006). Attempts to stimulate regeneration from the mammalian retina have
shown the response to toxin damage is even more limited than that of the posthatch chick
(Ooto et al., 2004), however, recent evidence indicates that activation of the Wnt pathway
stimulates proliferation of Mller glia and promotes their de-differentiation into retinal
progenitors (Osakada et al., 2007). While it is not known whether Notch signaling is involved
in the de-differentiation of mammalian Mller glia, and/or their production of new neurons,
another study in the rodent retina has implicated Notch signaling in the response of the
mammalian retina to damage. A FACS sorted side population that possesses some
progenitor-like qualities can be isolated from the toxin-treated rat retina. When the Notchsignaling pathway was inhibited at the same time as the damage was induced, the pool of side
population cells was lost (Das et al., 2006).
In previous studies of regeneration in the chick retina, it was noted that a majority of the Mller
glial-derived progenitors do not differentiate into neurons, but rather remain as undifferentiated
progenitors (Fischer and Reh, 2001). We tested whether a persistent activation of the Notch
pathway may be preventing these progenitors from completing the regenerative process. Our
data are consistent with this hypothesis, since experimentally inhibiting the pathway by
treatment with DAPT causes an increase in the percentage of these progenitors that differentiate
into neurons. This result begs the question as to which ligands might be activating the Notch
receptor in the damaged retina. While we found that Notch1 and Hes5 were upregulated during
regeneration, we did not see a significant up-regulation of either the canonical or non-canonical
Notch ligands: DNER, Dll1, and Dll4. Nevertheless, we could detect expression of theseligands by QPCR, and so it is possible that one or more of them may be activating the Notch
receptor, but that the overall expression levels of these ligands do not change after damage.
The Notch pathway has also been implicated in regeneration of other non-retinal tissues, such
as the pancreas (Su et al., 2006), bone marrow (Han et al., 2000; Han et al., 2006), skin (Adolphe
and Wainwright, 2005), muscle (Luo et al., 2005, Carey et al, 2007) and cochlea (Bermingham-
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McDonogh and Rubel, 2003; Stone and Rubel, 1999) and thus some of the mechanisms for
regeneration are likely to be conserved across tissue types and species. When muscle cells are
stressed, for example through exercise, new muscles cells are generated. The source of this
regeneration is an intrinsic stem population, called satellite cells. During this myogenesis, there
is increased expression of several Notch signaling components. Coincidently, it was found that
older muscles cells, which have less regenerative capabilities, express lower levels of Notch
signaling molecules than younger muscles. Interestingly, if older muscles underwent resistance
training, the expression levels of Notch signaling components between age groups wereindistinguishable (Carey et al., 2007). Thus Notch signaling is necessary for the expansion of
the satellite cell population, however later in myogenesis, the Notch pathway is downregulated
as the newly differentiated muscle cells emerge. One theme that appears to be emerging in the
study of Notch signaling during regeneration, regardless of the tissue type, is that there is a
need for tight spatial and temporal regulation of Notch signaling.
In summary, there is an increasing body of data that supports the importance of Notch signaling
during regeneration. In most of the these cases, Notch signaling functions to maintain stem cell
properties in progenitor/stem cell populations while restricting differentiation. We have shown
that Notch signaling is transiently upregulated during retinal regeneration in the chick, and that
Notch signaling plays a biphasic role during the regeneration. Initially, Notch is necessary for
dedifferentiation of Mller glia into progenitor cells, but later in the process the activation of
Notch limits successful regeneration in these animals. It is possible that a similar limit occursin the mammalian retina, and manipulation of the Notch pathway may be critical to promote
retinal repair in mammals.
Supplementary Material
Refer to Web version on PubMed Central for supplementary material.
Acknowledgements
We would like to thank Paige Etter, Samuel Reh and Christa Younkins for the assistance with sectioning, Toshinori
Hayashi and Byron Hartman for advice on in situ protocol and all the members of the Reh lab, especially Mike Karl
and Deepak Lamba, for their constructive comments. This work was supported by NRSA postdoctoral fellowship F32
EY016636 to S.H. and NIH grant EY13475 to T.A. R.
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Fig. 1.
QPCR of central retina shows Notch signaling pathway components are upregulated after
NMDA treatment. (A) Geminin (progenitor specific marker) increases after damage. (B) Sox2
increases after damage. (C) Pea3 (progenitor specific marker) increases after damage. (D)
PCNA (a measure of cell proliferation) increases after NMDA damage (P3 p < 0.07, P4 p