Abstract
The molecular mechanisms underlying cell fate determination from common progenitors in the vertebrate CNS remain elusive. We previously reported that the OTX2 homeoprotein regulates retinal photoreceptor cell fate determination. While Otx2 transactivation is a pivotal process for photoreceptor cell fate determination, its transactivation mechanism in the retina is unknown. Here, we identified an evolutionarily conserved Otx2 enhancer of ∼500 bp, named embryonic enhancer locus for photoreceptor Otx2 transcription (EELPOT), which can recapitulate initial Otx2 expression in the embryonic mouse retina. We found that the RAX homeoprotein interacts with EELPOT to transactivate Otx2, mainly in the final cell cycle of retinal progenitors. Conditional inactivation of Rax results in downregulation of Otx2 expression in vivo. We also showed that NOTCH–HES signaling negatively regulates EELPOT to suppress Otx2 expression. These results suggest that the integrated activity of cell-intrinsic and -extrinsic factors on EELPOT underlies the molecular basis of photoreceptor cell fate determination in the embryonic retina.
Introduction
Postmitotic neurons and glial cells are produced from a pool of cycling progenitors in an orderly fashion during development. Studies of cell fate determination in the vertebrate retina have uncovered several fundamental principles by which this is achieved (Livesey and Cepko, 2001). Retinal progenitor cells (RPCs) are multipotent subsets of progenitors and are therefore not limited to the generation of only one or two cell types (Turner and Cepko, 1987; Holt et al., 1988; Wetts and Fraser, 1988; Turner et al., 1990). In the developing brain, many progenitor cells were found to be able to give rise to several different cell types, including different types of neurons and glia, as seen in the developing retina (Walsh and Cepko, 1988, 1993). During vertebrate retinal development, retinal ganglion cells, horizontal cells, rod and cone photoreceptor cells, amacrine cells, bipolar cells, and Müller glial cells arise from multipotent RPC in a conserved order during development.
We previously reported that OTX2 homeoprotein controls photoreceptor cell fate. Otx2 conditional knock-out (CKO) mice, whose Otx2 gene is inactivated in developing photoreceptors, showed a total loss of retinal photoreceptors and a pronounced increase of amacrine-like cells. However, retroviral gene transfer of Otx2 steered RPCs toward becoming photoreceptors, suggesting that OTX2 plays an instructive role in photoreceptor cell fate determination (Nishida et al., 2003). At early embryonic stages in vertebrates, Otx2 has widespread expression in the epiblast, but later in development, Otx2 expression becomes concentrated in the forebrain and midbrain neuroepithelium including the eye domain. Afterward, however, Otx2 expression is downregulated in the developing optic vesicle (Furukawa et al., 1997). When cone photoreceptor precursors begin to differentiate around embryonic day 11.5 (E11.5), Otx2 transcription is activated in cone photoreceptor precursors and exerts a critical role in photoreceptor cell fate determination (Nishida et al., 2003). Therefore, we think that understanding the transcriptional regulatory mechanisms of Otx2 in photoreceptor precursors will lead to the elucidation of a key molecular mechanism underlying photoreceptor cell fate determination.
In the current study, we investigated the transactivation mechanism of Otx2 in retinal photoreceptor precursors. We first found that OTX2 expression begins mainly in the final cell cycle of RPCs. We analyzed the regulatory region of the Otx2 gene during embryonic stages when Otx2 transcripts are distinctly expressed in the presumptive photoreceptor layer in contrast to postnatal stages when Otx2 expression shifts to the bipolar cell layer (Nishida et al., 2003; Koike et al., 2007). We then identified an ∼500 bp cis-regulatory region we called embryonic enhancer locus for photoreceptor Otx2 transcription (EELPOT) that can recapitulate initial Otx2 transcription in early developing photoreceptors. We also provide evidence that the enhancer region is transactivated by RAX, which is a homeoprotein transcription factor expressed in RPCs, and negatively regulated by the HES family of molecules, which are bHLH transcription repressors. Our results suggest that the integrated functions of RAX homeoprotein and canonical NOTCH–HES signaling on a key enhancer is the foundation of embryonic photoreceptor cell fate determination.
Materials and Methods
S-phase labeling
For single S-phase labeling, timed pregnant female mice (E15.5) were injected intraperitoneally with 5-bromo-2′-deoxyuridine (BrdU) (50 μg/g body weight) 1, 2, or 4 h before killing. For double S-phase labeling, timed pregnant female mice (E14.5) were injected intraperitoneally with 5-iodo-2′-deoxyuridine (IdU) (50 μg/g body weight) followed by BrdU injection (50 μg/g body weight) at 1.5, 5.5, 10, and 14.5 h after IdU injection. Embryos were harvested 15 h after IdU injection. For BrdU and IdU immunostaining, sections were pretreated with 2N HCl for 15 min at 37°C before blocking. To detect IdU- and BrdU-positive cells, an anti-BrdU antibody that recognizes both IdU and BrdU was used (BD Biosciences; 347580). An antibody that recognizes only BrdU was used to detect BrdU-incorporating cells (Santa Cruz; sc-56258). Combined use of the anti-BrdU antibody and the anti-BrdU/IdU antibody allowed us to identify only IdU-incorporating cells that had exited the S phase of cell cycle before the first BrdU injection.
Cell culture, transfection, and luciferase assay
Transient transfection was performed using LTX (Invitrogen) according to manufacturer's instructions. NIH3T3 cells were transfected with expression vectors encoding proteins of interest, a luciferase reporter plasmid connected to an EELPOT fragment, and an expression vector encoding β-galactosidase (β-gal) as an internal control. Luciferase activity was measured using the Luciferase Assay System (Promega) according to manufacturer's instructions. Firefly luciferase activities were determined by three independent transfections and normalized by β-gal activity as an internal control.
Immunostaining, in situ hybridization, and X-gal staining
Mouse embryos and eye cups were fixed in 4% paraformaldehyde in PBS for either 30 min to 3 h (for immunostaining) or overnight (for in situ hybridization). The samples were cryoprotected, embedded, frozen, and sectioned (16–20 μm thick). Slides were incubated with blocking solution (4% normal donkey serum and 0.5% Triton X-100 in PBS) for 1 h, and then with primary antibodies for 4 h at room temperature. Slides were washed with PBS three times for 10 min each time and incubated with secondary antibodies for 2 h at room temperature. Rhodamine-labeled peanut agglutinin (PNA) (Vector Laboratories; RL-1072) was used for staining cone photoreceptors. 4′,6-Diamino-2-phenylindole (DAPI) was used for staining DNA. TSAPLUS Fluorescence Kit (PerkinElmer; catalog #NEL753001KT) was used for immunostaining of HES1 and HES5. Sections were boiled in 10 mm sodium citrate buffer, pH 6.0, for 10 min for antigen retrieval and rinsed twice using 0.1 m PBS, and immunostaining was performed according to manufacturer's instructions. Image acquisition and analysis of the signals obtained were performed using a Zeiss confocal LSM700 microscope. In situ hybridization and X-gal staining were performed essentially as described previously (Furukawa et al., 2002; Sanuki et al., 2010).
Antibodies
For immunostaining, anti-β-GAL antibody (Promega, Z3781, mouse monoclonal, 1:1000; Millipore Bioscience Research Reagents, AB1211, mouse monoclonal, 1:1000), anti-RHODOPSIN (LSL; LB-5597; rabbit polyclonal; 1:10,000), anti-OTX2 antibody (R&D Systems; AF1979; goat polyclonal; 1:1000), anti-HES1 antibody (Santa Cruz; sc-25393; rabbit polyclonal; 1:100), anti-HES5 antibody (Santa Cruz; sc-25395; rabbit polyclonal; 1:100), anti-PAX6 antibody (Developmental Studies Hybridoma Bank; P3U1; mouse monoclonal; 1:200), anti-FLAG antibody (M2) (Sigma-Aldrich; F3165; mouse monoclonal; 1:1000), and anti-BrdU antibodies (BD Biosciences, 347580, mouse monoclonal, 1:100; Santa Cruz, sc-56258, rat monoclonal, 1:100) were used as primary antibodies. Anti-RAX antibody was raised against a peptide (PKAPAGGSESSPPAAPGFVPEYEATRP) followed by affinity purification using the same peptide (guinea pig polyclonal; 1:1000). Anti-CRX antibody was raised against a fusion protein expressed in Escherichia coli using a construct in which the C-terminal portion of mouse CRX (residues 105–299) was subcloned into pET28a, followed by affinity purification (rabbit polyclonal; 1:4000). Cy3-conjugated anti-rabbit IgG (Jackson ImmunoResearch; 711-165-152), Cy3-conjugated anti-mouse IgG (Jackson ImmunoResearch; 711-165-150), Alexa Fluor 647-conjugated anti-goat IgG (Invitrogen; A21447), FITC-conjugated anti-goat IgG (Jackson ImmunoResearch; 705-095-147), FITC-conjugated anti-rabbit IgG (Jackson ImmunoResearch; 712-095-153), and Cy3-conjugated anti-guinea pig IgG (Millipore; AP193C) were used as secondary antibodies.
Chromatin immunoprecipitation assay
Chromatin immunoprecipitation (ChIP) assay was performed essentially as described previously (Shang et al., 2000). Mouse embryonic retinas were cross-linked with 1% formaldehyde in PBS at room temperature for 15 min. Retinas were rinsed with ice-cold PBS twice and incubated with 0.125 m glycine in PBS for 10 min. The immunoprecipitated chromatin DNA was analyzed by semiquantitative PCR or real-time PCR. Primer sequences are as follows: for Hsp3 region, forward (F), 5′-CTCAAACCACATGCAAGGGTATC-3′, and reverse (R), 5′-TAAGGGAAGAAGAAGTAGAGGTC-3′; EELPOT, F, 5′-TGATGCCCAAAAGGTATCCAAA-3′, and R, 5′-TAAAATCACCCCTAAACACAGG-3′; Otx2 gene, F, 5′-CTAGGGCACAGCTCGACGTTCTG-3′, and R, 5′-CCTGGTTCATATGATTAAGGAGG-3′. Twenty-eight to 30 cycles of amplification were used for PCR. Anti-RAX antibody (6 μg) and anti-HES1 (6 μg) antibody were also used for ChIP assay.
Real-time PCR
Total RNA was reverse-transcribed by SuperScript II (Invitrogen) using random primers. Real-time PCR was performed using the Thermal Cycler Dice Real-Time System (Takara) and SYBR GreenER qPCR SuperMix Universal (Invitrogen), according to the manufacturer's protocols. Quantified RNA values were normalized with those of β-actin RNA. Quantitative analysis was performed at least three times and shown with SEs. Primer sequences are as follows: for Otx2, F, 5′-GGTATGGACTTGCTGCATCC-3′, and R, 5′-CGAGCTGTGCCCTAGTAAATG-3′; Hes1, F, 5′-TGCCAGCTGATATAATGGAGAA-3′, and R, 5′-CCATGATAGGCTTTGATGACTTT-3′; LacZ, F, 5′-ATTGAACTGCCTGAACTACCG-3′, and R, 5′-TGAGGTTTTCCGCCAGAC-3′; β-actin, F, 5′-CGTGCGTGACATCAAAGAGAA-3′, and R, 5′-TGGATGCCACAGGATTCCAT-3′.
Retina explant culture
Embryonic mouse eyes, including the retina and lens, were transferred to nucleopore polycarbonate membrane filters, 0.2 μm pore size (Whatman; 110606) after the retinal pigment epithelium (RPE) was removed, and cultured for 6 d in DMEM supplemented with 10% FBS, 100 IU/ml penicillin, and 100 μg/ml streptomycin. Retinas were fixed in 4% paraformaldehyde in PBS for 3 h. The samples were cryoprotected, embedded, and used for immunostaining.
Plasmids
pcDNA3–3FLAG-Rax, pcDNA3–3FLAG-Otx2, pcDNA3–3FLAG-Crx, pcDNA3–3FLAG-NeuroD1, pcDNA3–3FLAG-Mash1, pcDNA3–3FLAG-Math5, pcDNA3-Math3, pCS2(+)-Pax6–4HA, pCS2(+)-Chx10–4HA, pCS2(+)-Ngn2, pCS2(+)-Hes1–4HA, pCS2(+)-Hey1, and pCS2(+)-Hes5 were used. A total of 0.5 μg of each plasmid was used for transfection. A total of 0.1 μg of pCS2(+)-LacZ or EELPOT-luc was used. pCS2(+) and pcDNA3 are CMV promoter-directed expression vectors.
Animal care
All procedures conformed to the Association for Research in Vision and Ophthalmology Statement for the Use of Animals in Ophthalmic and Vision Research, and were approved by the Institutional Safety Committee on Recombinant DNA Experiments and the Animal Research Committee of Osaka Bioscience Institute. Mice were housed in a temperature-controlled room at 22°C with a 12 h light/dark cycle. Fresh water and rodent diet were available at all times.
Mouse lines and transgenic or targeting constructs
Rax flox mouse line.
To generate the Rax flox mouse line, we obtained genomic DNA clones covering the Rax gene locus by a screen of the 129/SvEv mouse genomic DNA library (Stratagene). We subcloned a ∼13 kb Rax genomic fragment, inserted a flox cassette upstream of exon1 and intron 2, cloned it into a modified pPNT vector to make a targeting construct, and transfected the linearized targeting construct into the TC1 embryonic stem (ES) cell line (Deng et al., 1996). The culture, electroporation, and selection of TC1 were performed as previously described (Sato et al., 2008). ES cells that were heterozygous for the targeting gene disruption were microinjected into C57BL/6 blastocysts to obtain chimeric mice.
Otx2 bacterial artificial chromosome #2 transgenic mouse line.
To generate an Otx2 bacterial artificial chromosome (BAC) #2 transgenic mouse, a mouse Otx2 genomic BAC clone (RP23-153H20) was used to generate a BAC reporter transgene in which a LacZ gene with the SV40 poly(A) signal (pA) was inserted before the translation start site of the Otx2 gene.
Crx-CreERT2 transgenic mouse line.
β-gal in the pβ-gal-Basic vector (Clontech) was replaced with the CreERT2 fragment, which was excised from pCre-ERT2 using EcoRI (Feil et al., 1997). The ∼2 kb promoter fragment of the Crx gene (Furukawa et al., 2002) was inserted before CreERT2 to generate a Crx-CreERT2 transgene.
EELPOT-Otx2 and EELPOT-LacZ transgenic mouse lines.
EELPOT located at ∼9 kb upstream of the Otx2 gene was connected to a heat shock promoter 68 (Hsp68)-Otx2-pA cassette or a Hsp68-LacZ-pA cassette (Kothary et al., 1989). The resulting constructs were used for generating transgenic mice lines.
Hes1 transgenic mouse.
A FLAG-tag encoding sequence was introduced in front of the initiation codon of rat Hes1 cDNA to generate FLAG-Hes1, and this FLAG-Hes1 fragment was connected after the ∼2 kb promoter fragment of the Crx gene. The resulting construct was used for generating transient transgenic mice, which were harvested at E13.5.
The purified constructs for generating transgenic mice were injected into the pronuclei of C57BL/6 × C3H F1 hybrid eggs at the one-cell stage followed by implantation into pseudopregnant foster mothers (ICR; Japan SLC).
The Otx2 flox mouse line.
CAG-CAT-Z mouse line and BAC #1 reporter transgenic mice were described previously (Sakai and Miyazaki, 1997; Tian et al., 2002; Kurokawa et al., 2004a).
The EELPOT (CR1) region in the BAC #2 clone was replaced with an EGFP-poly(A) signal (pA) cassette using the pLD53.SCA-E-B shuttle vector by homologous recombination (Yang et al., 1997; Gong et al., 2002; Sato et al., 2007), creating BAC #2ΔCR1. Subsequently, the Hsp1-3 region in the resulting BAC was replaced with a Cre-pA cassette using the pLD53.SCA-Cre-B shuttle vector by homologous recombination, creating a BAC #2ΔCR1, ΔHsp1-3. The Hsp1-3 region in BAC #2 was replaced with an EGFP-pA cassette using the pLD53.SCA-E-B shuttle vector by homologous recombination, creating a BAC #2ΔHsp1-3.
Hsp1 was obtained as an EcoRV/EcoRV 12 kb DNA fragment (nucleotides 170,477–182,321 in the Otx2 locus). Hsp3 was obtained as a BamHI/BamHI 7 kb DNA fragment (nucleotides 158,220–165,764). Hsp1-1 was obtained as an EcoRV/HincII 5 kb DNA fragment (nucleotides 170,477–175,530), and Hsp1-3 was obtained as a HincII/EcoRV 5 kb DNA fragment (nucleotides 177,767–182,321). Hsp2, Hsp4, Hsp1-2, and CR2 were produced by PCR using primers as follows: for Hsp2, F, 5′-CGCTCGAGTTACCGTTCTGGAGAGCACCAC-3′, and R, 5′-ATGAATTCGTTATGTGTTGGCTGTGGGTAT-3′; for Hsp4, F, 5′-ACTCGAGGATATCAGCCATAATGTGGGAAT-3′, and R, 5′-AAGTCGACGATTCGCCTGGAGTGGACAGGGTCAG-3′; for Hsp1-2, F, 5′-CAGCTACCGGTGAGGACACGACTCA-3′, and R, 5′-ATCCCGGGATTCAGCATTGTCACCAGATTT-3′; and for CR2, F, 5′-AAGTCGACGAAAAT CCCCGCCAGACCGAAGCC-3′, and R, 5′-AAGGATCCAACTCATCGTAT TTGCTTTTACAA-3′.
Statistical analysis
Data are presented as means ± SD. Statistical significance was calculated with a Student's t test.
Results
OTX2 expression begins in the final cell cycle of RPCs
Cell fate determination in the vertebrate CNS is thought to occur largely during the final cell cycle, suggested from the transplantation study using the developing ferret neocortex (McConnell and Kaznowski, 1991). In the developing retina, lineage studies showed that the RPCs remain uncommitted to a specific cell fate until the final cell division (Turner and Cepko, 1987; Turner et al., 1990). To clarify the timing of the onset of OTX2 expression in the cell cycle of RPCs, we examined in which cell cycle phase Otx2 transcription begins in the embryonic mouse retina by a combination of immunohistochemistry and double S-phase labeling (Fig. 1). We injected BrdU into E15.5 pregnant mice to label cells in S phase (Fig. 1A). Embryos were harvested 1 h (Fig. 1A,B,E), 2 h (Fig. 1A,C,F), or 4 h (Fig. 1A,D,G) after BrdU injection. Previous studies reported that BrdU-labeled retinal cells 1, 2, or 4 h after BrdU injection are in the S, G2, or M phase, respectively (Alexiades and Cepko, 1996; Dyer et al., 2003). We found that OTX2 is expressed in BrdU-positive cells (Fig. 1B–D,H), suggesting that OTX2 expression begins before cell cycle exit. We also examined CRX expression, which is an OTX2 downstream gene expressed in photoreceptor precursors, and observed few or no CRX-positive cells in the BrdU-positive cells, suggesting that CRX expression begins after cell cycle exit (Fig. 1E–H). We observed that the number of OTX2 and BrdU double-positive cells increased in proportion to the amount of time after BrdU injection (Fig. 1H). These observations fit well with the results previously reported that OTX2 expression begins in the late S to early G2 phase of cell cycle and CRX expression begins in the postmitotic phase (Trimarchi et al., 2008).
We further extended our analysis to estimate the timing of OTX2 expression by double labeling. We injected IdU into E14.5 pregnant mice followed by BrdU injection 1.5, 5.5, 10, and 14.5 h after IdU injection to label progenitor cells in S phase (Fig. 1A). The IdU-positive and BrdU-negative cells are the cells that exit their S phase before the first BrdU injection at 1.5 h after IdU injection. We chased the fate of these IdU-positive and BrdU-negative cells until 15 h later when they are supposed to enter the G1 or G0 phase (Alexiades and Cepko, 1996; Dyer et al., 2003). We examined whether IdU-positive, BrdU-negative, and OTX2-positive cells became postmitotic by coimmunostaining using an antibody against CRX. We observed at least ∼70% of IdU-positive, BrdU-negative, and OTX2-positive cells were also CRX positive (Fig. 1I,J). These results strongly suggest that OTX2 expression begins mainly during the last cell cycle just before they exit the cell cycle.
Our observations suggest that molecular mechanisms governing photoreceptor cell fate determination during the final RPC cell division and molecular mechanisms regulating Otx2 expression are closely related. We then investigated the regulatory mechanism of Otx2 expression in the developing retina.
Identification of Otx2 enhancer in embryonic photoreceptor precursors
To identify the mouse Otx2 regulatory locus directing expression in the embryonic photoreceptor precursors, we first analyzed two transgenic mouse lines harboring BACs, containing the mouse Otx2 gene inserted with a β-galactosidase (LacZ) reporter (Fig. 2A). The BAC #1 line was previously established to investigate Otx2 cis-regulatory elements important for developing forebrain and midbrain expression (Kurokawa et al., 2004a,b). The BAC #2 clone, spanning −150 kb 5′-upstream to +70 kb 3′-downstream with respect to the site corresponding to the initiation codon of the Otx2 gene, was inserted with LacZ immediately before the Otx2 initiation codon site. At E13.5, endogenous Otx2 transcripts were observed in the outer region of the developing mouse retina, a presumptive photoreceptor layer, by in situ hybridization (Fig. 2B). Similarly, we observed LacZ-positive cells in the presumptive photoreceptor layer in both the BAC #2 germline-transmitted transgenic line retina and BAC #2 transient transgenic retina at E13.5 (data not shown; Fig. 2C). We observed LacZ-positive cells in the presumptive photoreceptor layer during postnatal stages in the retinas of BAC #2 transgenic mice, indicating that BAC #2 recapitulates Otx2 expression in the developing retina (Fig. 2D,E). In contrast, we did not observe a significant number of LacZ-positive cells in the E13.5 retina of BAC #1 harboring BAC spanning −170 kb 5′-upstream to −30 kb 5′-upstream of the Otx2 gene (Fig. 2F), suggesting that the Otx2 regulatory region resides between −30 and +70 kb of the Otx2 gene.
To further narrow down the critical region for the Otx2 regulatory activity, we examined the −32 kb 5′-upstream region of the Otx2 gene first. We prepared DNA fragments of up to ∼12 kb in length overlapping each other, spanning from −32 kb to the OTX2 initiation codon site of the Otx2 gene (Fig. 2A). We fused each of these DNA fragments to the LacZ gene or the minimal mouse heat shock protein 68 promoter connected immediately before LacZ, and named them as Hsp1, 2, 3, and 4, respectively (Fig. 2A). We generated transient transgenic mice injected with these DNA constructs, and harvested embryos at E13.5. We observed LacZ-positive cells only in the retinas of Hsp1-injected mice in a similar pattern to Otx2 expression, suggesting that Hsp1 contains a regulatory region responsible for Otx2 expression in the presumptive photoreceptor layer of the retina at E13.5 (Fig. 2B,C,G–I). We divided Hsp1 into three fragments with short overlapping regions, and produced LacZ reporter constructs, designated Hsp1-1, Hsp1-2, and Hsp1-3 (Fig. 2A). We generated transient transgenic mice using these constructs, and detected LacZ-positive cells in the presumptive photoreceptor layer of the retina of mice injected with Hsp1-1 or Hsp1-3 (Fig. 2J,K). It should be noted that multiple potential OTX2-binding consensus sites are present in both Hsp1-1 and Hsp1-3 regions (Fig. 2A), suggesting that these OTX2-binding sites may serve as an OTX2 auto-positive feedback.
To confirm whether the Hsp1 region in BAC #2 is responsible for Otx2 expression in the retina at E13.5, we prepared a BAC #2 construct deleting the region corresponding to Hsp1, designated BAC #2ΔHsp1. We did not observe a significant number of LacZ-positive cells in the retina of mice injected with the BAC #2ΔHsp1 transgene, suggesting that the Hsp1 region is necessary for Otx2 expression in the developing retina at E13.5 (Fig. 3A,A′). We then searched for conserved regions among species in Hsp1-1 or Hsp1-3. We found two ∼500 bp evolutionarily well conserved regions from opossum to human (Fig. 3E), and called them conserved region 1 (CR1) and 2 (CR2), in Hsp1-1 and Hsp1-3, respectively (Fig. 2A). Since CR2 contains at least three potential OTX2-binding sites, we focused more on CR1 than on CR2. To evaluate the importance of CR1, we first prepared the BAC #2 construct deleting both CR1 and Hsp1-3 to examine whether these regions are required for Hsp1 to induce gene expression in the developing retina. We did not observe a significant number of LacZ-positive cells in the retina of transgenic mice with CR1- and Hsp1-3-deleted BAC #2 (Fig. 3B,B′). We then deleted CR1 or Hsp1-3 to further examine the significance of CR1 or Hsp1-3 for induction of LacZ (Fig. 3C,D). While we observed LacZ-positive cells in the BAC #2ΔHsp1-3 retinas, we failed to observe LacZ-positive cells in BAC #2ΔCR1 transgenic mice (Fig. 3C–D′). Although the Hsp1-3 transgene alone can produce a signal (Fig. 2K), we assume that BAC #2 may contain a silencer region that suppresses Hsp1-3 activity. These results suggest that CR1 has a significant role in the regulatory activity of Otx2 in the developing retina at E13.5.
An evolutionarily conserved genomic region is critical for Otx2 transactivation
We then examined whether CR1 is sufficient to recapitulate Otx2 expression by a transient transgenic assay using the LacZ reporter in which a CR1 DNA fragment is linked with an Hsp68-LacZ-pA cassette to produce CR1-LacZ (Fig. 4A). We observed five CR1-LacZ transgenic mice expressing LacZ in the outer region of the retina of 11 transient transgenic mice (Fig. 4B,C). Next, we generated three germline-transmitted CR1-LacZ transgenic mice lines to further investigate this region. Since all of these lines exhibited similar LacZ expression patterns (data not shown), we performed further analysis using the transgenic CR1 line 1, which exhibited slightly more LacZ-positive cells than the other CR1 lines. We observed LacZ-positive cells in the presumptive photoreceptor layer of the retina from CR1 line 1 (Fig. 4D,E), although the number of LacZ-positive cells observed in the CR1 line 1 transgenic mouse seemed to be smaller compared with that in the BAC #2 transgenic mouse. It should be noted that CR1-driven LacZ expression decreases significantly after late embryonic stages (Fig. 4F,G), suggesting that EELPOT plays a crucial role for the initial Otx2 expression but not for the maintenance of Otx2 expression. We also examined whether CR2 has a similar transcriptional activity to EELPOT by generating transient transgenic mice using a CR2-LacZ construct (Fig. 4H). We observed LacZ-positive cells throughout the retina at E13.5, suggesting that the CR2 region contains a regulatory region other than that for Otx2 (Fig. 4I). We observed LacZ-positive cells in the outer region of the CR2-LacZ transgenic retina at P0 (Fig. 4J) in contrast to the absence of LacZ-positive cells in the CR1-LacZ transgenic P0 retina (Fig. 4G). These results suggest that CR2 has different transcriptional regulatory activities than CR1 in embryonic retinal development.
We further examined whether CR1 can recapitulate OTX2 expression in the developing retina by immunohistochemistry (Fig. 4K–P). We measured the percentage of OTX2-positive cells in LacZ-positive cells (Fig. 4Q). We observed that most LacZ-positive cells were OTX2-positive, indicating that CR1 can at least partially recapitulate OTX2 expression in the embryonic retina (Fig. 4N–Q). Based on these observations, we named CR1 embryonic enhancer locus for photoreceptor Otx2 transcription (EELPOT).
We then investigated whether the Otx2 gene driven by EELPOT can rescue photoreceptor development in the Otx2 CKO retina by generating transgenic mouse line EELPOT-Otx2, which expresses an exogenous mouse Otx2 cDNA under the control of EELPOT (Fig. 4R). We generated three Otx2flox/flox; Crx-Cre; EELPOT-Otx2 mouse lines, and examined their retinal photoreceptors at P14. While the Otx2flox/flox; Crx-Cre mice did not develop retinal photoreceptor cells, including both rods and cones (Nishida et al., 2003), the wild-type mouse retina expresses rhodopsin in rod photoreceptors and PNA in cone photoreceptors at P14 (Fig. 4S). We detected neither RHODOPSIN-positive cells nor PNA-positive cells, in the Otx2flox/flox; Crx-Cre retina (Fig. 4T). In contrast, we observed both RHODOPSIN-positive and PNA-positive cells in the retina in three of three Otx2flox/flox; Crx-Cre; EELPOT-Otx2 lines (Fig. 4U), although the morphology of the photoreceptor cells was abnormal. Thus, EELPOT-directed Otx2 insufficiently but significantly rescued the photoreceptor development of the Otx2 CKO retina. The partial rescue of photoreceptor development is probably due to an insufficient level of and/or improper timing of Otx2 expression in photoreceptor precursors in the EELPOT-Otx2 transgenic retina.
It should be noted that we failed to further narrow down ∼500 bp EELPOT by transgenic mouse assay as far as we attempted, suggesting that EELPOT may function as a unit. Therefore, we next investigated the factors which possibly activate or repress EELPOT based on the cis-elements that appeared in the EELPOT sequence.
Regulation of EELPOT by RAX homeoprotein
Our observation that OTX2 expression begins in embryonic RPCs mainly during the final cell division (Fig. 1) suggests that the transactivation of Otx2 is regulated by the transcription factor(s) expressed in RPCs and also in postmitotic photoreceptor precursors for a short while. To identify the transcription factor(s) that regulate EELPOT, we searched possible transcription binding sites by a database search, and found paired-type homeoprotein binding sites (Wilson et al., 1993), E-box (class A and class B) and N-box motifs in EELPOT (Fig. 5A). Several paired-type homeoproteins expressed in RPCs are known, including CHX10, PAX6, and RAX (Levine and Green, 2004). We compared the expression patterns of Chx10, Pax6, Rax, and Otx2 in the embryonic retina at E15.5 by in situ hybridization to identify which factor is expressed both in progenitors and developing photoreceptor precursors (Fig. 5B–E). Both Rax and Otx2 expression were observed in the presumptive photoreceptor layer, while Chx10 and Pax6 were expressed in RPCs but weakly observed in the outermost region of the retina at late embryonic stages (Fig. 5B–E). Thus, we investigated the possibility that RAX may transactivate EELPOT by luciferase assay using NIH3T3 cells. We observed that RAX significantly transactivated a luciferase reporter in which EELPOT was linked with thymidine kinase minimal promoter and the luciferase gene (EELPOT-luc), while PAX6 and CHX10 did not significantly transactivate EELPOT (Fig. 5F,G). bHLH factors, NEUROD1, MASH1, and NEUROGENIN2 (NGN2), can bind to E-box and have been implicated in photoreceptor fate determination and/or photoreceptor differentiation. This raises the possibility that EELPOT is regulated by bHLH transcription factors. We observed that NGN2 and MATH3 activated EELPOT-luc reporter expression only very weakly, and neither NEUROD1 nor MASH1 significantly activated EELPOT-luc (Fig. 5H). In addition, we performed luciferase assay using a neuronal cell line, Neuro2A. We observed that RAX significantly activated EELPOT as observed in NIH3T3 cells. It should be noted that we observed weak activation of EELPOT by NGN2 (Fig. 5I). However, photoreceptor development was not significantly affected in either Ngn2−/−; Ascl1−/−; Math3−/− or Ngn2GFP/GFP mutant retinas (Akagi et al., 2004; Hufnagel et al., 2010), suggesting that NGN2 does not play a critical role in regulating EELPOT. These results suggest that EELPOT can be directly regulated by RAX homeoprotein.
We next tested whether RAX binds to EELPOT by ChIP assay (Fig. 5J). We performed a ChIP assay using E15.5 mouse retinal lysate with an anti-RAX antibody. We PCR-amplified three distinct genomic regions with primers corresponding to the 5′-upstream region of EELPOT (Hsp3 region), to EELPOT, and to Otx2 coding region (Otx2 gene) following immunoprecipitation (Fig. 5J). We observed a significant amplified band only with the primers for EELPOT, suggesting that RAX binds to EELPOT to transactivate Otx2 in the embryonic mouse retina. However, we did not observe EELPOT activation by RAX in the P0 retina (Fig. 4G). We, therefore, examined whether RAX binds to EELPOT in the P0 retina. We did not observe a significant RAX binding to EELPOT (Fig. 5K), consistent with the observation that EELPOT was inactive at P0. We then examined whether RAX and OTX2 are coexpressed in photoreceptor precursors by immunostaining at E13.5. We observed that almost all OTX2-expressing cells are positive for RAX (Fig. 5L–N,P), consistent with the observation that RAX transactivates EELPOT. Similarly, we observed coexpression of RAX and CRX in differentiating photoreceptor precursors at E13.5 (Fig. 5O).
We tried to identify a RAX-binding site(s) in EELPOT; however, we could not narrow down EELPOT into a smaller region activated by RAX using a luciferase assay as far as we attempted. There may be multiple atypical RAX-binding sites that have a low affinity to RAX in EELPOT. This result may be consistent with our inability to narrow down EELPOT by transgenic mouse assay.
RAX is required for Otx2 expression in early photoreceptor precursors
We inactivated Rax by conditional targeted gene disruption to examine whether RAX is required for Otx2 expression in the developing retina in vivo (Fig. 6A–O). We established a transgenic mouse line harboring a BAC containing a Cre recombinase gene immediately before the site corresponding to the CHX10 initiation codon, and named this transgenic mice line Chx10-Cre (Fig. 6B). This transgenic mouse line expresses Cre in RPCs, and recombination is detected from E11.5 in the retina by mating with the CAG-CAT-Z Cre monitor mouse line (Fig. 6B–F). We generated Raxflox/flox; Chx10-Cre mice, which we referred to as Rax CKO mice, and examined Otx2 expression in the E15.5 retina. Since Rax is essential for RPC proliferation (Mathers et al., 1997), the size of the Rax CKO retina was significantly smaller than that of the WT retina (Fig. 6G). Otx2 mRNA is expressed mainly in the presumptive photoreceptor layer at E15.5. We observed a severe attenuation of Otx2 expression in the Rax CKO retina (Fig. 6H,I), in which the Rax gene was inactivated in RPCs (Fig. 6N,O). Crx, a downstream target gene of OTX2, was also strongly reduced (Fig. 6J,K). In contrast, we observed almost normal or slightly enhanced expression of Chx10 in the Rax CKO retina compared with that in the WT retina (Fig. 6L,M). We, therefore, could not exclude the possibility that Rax inactivation in the progenitor cells affects internal properties of RPCs, resulting in the severe attenuation of Otx2 and Crx expression in the Rax CKO retina by an indirect effect of Rax inactivation. To exclude this possibility, we inactivated the Rax gene in the early postmitotic photoreceptor precursors using the CreERT2 system. To attain a tight regulation of Cre expression in photoreceptor precursors, we established a transgenic mouse line, referred to as Crx-CreERT2 that expresses CreERT2 under the control of the 2 kb Crx promoter (Fig. 6P). We confirmed that application of tamoxifen to this mouse line induced Cre-mediated recombination of a LacZ reporter transgene in the developing photoreceptor layer (Fig. 6Q–Z).
We then generated Raxflox/flox; Crx-CreERT2 mice and treated them with tamoxifen at E14.5 to inactivate Rax in embryonic photoreceptor precursors (Fig. 7A). We referred to this mouse as the Rax-induced CKO (Rax iCKO) mouse in this study. To examine whether induced Rax inactivation occurs, we analyzed E15.5 retinas by in situ hybridization. We observed a loss of Rax expression in the presumptive photoreceptor layer of the retina corresponding to the Crx-expressing region (Fig. 7B–E). We observed that Otx2 expression was severely attenuated in the Rax iCKO retina, while Pax6 expression was barely affected and Chx10 expression was slightly upregulated in the presumptive photoreceptor layer (Fig. 7F–Q). These results suggest that Rax is required for normal Otx2 expression in embryonic photoreceptor precursors.
We previously reported that the Otx2-deficient retina showed a total loss of photoreceptors and a remarkable increase of Pax6-positive amacrine-like neurons (Nishida et al., 2003). We, therefore, examined whether the Rax iCKO retina showed an increase of Pax6-positive amacrine-like neurons as observed in the Otx2 CKO retina. Cell fate determination of amacrine cells mainly occurs at late embryonic stages. Since the embryos did not survive until the late embryonic stages when pregnant females received tamoxifen, we performed a retinal explant culture using the E13.5 Raxflox/flox; Crx-CreERT2 retina (Fig. 7R,S). Retinal explants were cultured in tamoxifen-containing medium for 6 d and subjected to immunostaining (Fig. 7T–W). We observed Pax6-positive cells, which marks RPCs and amacrine cells, at this stage, in the region where RPCs and amacrine cells reside in the control retina (Fig. 7T,U). In contrast, in the Rax iCKO retina, we observed a significant number of ectopic Pax6-positive cells across the retina (Fig. 7V,W).
HES family repressors antagonize the RAX activity on EELPOT
In EELPOT, one N-box, a HES family protein-binding sequence, and three E-boxes overlapping with class A or class B bHLH transcription factor-binding sequences are present (Iso et al., 2003) (Fig. 5A). RAX and HES proteins are implicated in the maintenance of RPCs, whereas bHLH transcription factors appear to induce neuronal differentiation (Levine and Green, 2004; Ohsawa and Kageyama, 2008). To investigate whether HES family proteins affect RAX-dependent reporter gene activation, we performed a luciferase assay using NIH3T3 cells. We focused on HES1, HES5, and HEY1/HESR1. These molecules function downstream of the NOTCH pathway (Jadhav et al., 2006; Fischer and Gessler, 2007; Ohsawa and Kageyama, 2008) and are significantly expressed in the embryonic retina but downregulated in FACS-sorted postmitotic Crx-promoter-driven-EGFP-positive photoreceptor precursor cells (data not shown) (Muranishi et al., 2010). These observations raised the possibility that HES1, HES5, or HEY1 act on EELPOT in RPCs but are downregulated in postmitotic cells. We cotransfected a Hes1, Hes5, or Hey1 expression plasmid together with a Rax expression plasmid and an EELPOT reporter plasmid. We observed that HES1, HES5, and HEY1 suppressed RAX-induced luciferase activation in a dose-dependent manner (Fig. 8A–C). Next, we performed a ChIP assay using E14.5 mouse retinal lysate with an anti-HES1 antibody (Fig. 8D). We observed a significant amplified band only with the primers for EELPOT, suggesting that HES1 is directly involved in regulating Otx2 transcription through EELPOT at E14.5 (Fig. 8D). We next examined whether HES1 binds to EELPOT in the P0 retina and did not observe any significant HES1 binding to EELPOT (Fig. 8E), suggesting that HES1 binding is not required for the suppression of EELPOT at P0, consistent with the observation that RAX did not bind to EELPOT at P0 (Fig. 5K).
We then performed immunostaining of OTX2 and HES in the developing mouse retina at E13.5, and observed that most of the OTX2-positive cells were HES1 and HES5 negative (Fig. 8F,G), supporting the idea that HES proteins negatively regulate Otx2 transcription. However, RAX and HES proteins are expressed in proliferating RPCs.
HES family molecules function downstream of RBPJ in the canonical NOTCH signaling pathway. It was reported that RBPj inactivation using another Chx10-Cre transgenic line showed significant upregulation of Otx2 and Crx in the developing retina at E13.5 and E16.5 by in situ hybridization (Zheng et al., 2009). In addition, we observed significant upregulation of Otx2 transcription in the organ-cultured embryonic retina from E13.5 to E15.5 in the presence of DAPT, a NOTCH signal inhibitor (Fig. 8H,I). We further investigated whether EELPOT is suppressed by NOTCH signaling using organ-cultured embryonic retinas isolated from EELPOT (CR1)-LacZ transgenic mice (Fig. 8J). We observed a significant increase in the number of LacZ-positive cells in the retina treated with DAPT compared with that in the DMSO-treated retina (Fig. 8K,L). We also detected a significant increase in the amount of LacZ mRNA in the DAPT-treated retina (Fig. 8M). These results support our hypothesis that EELPOT is directly suppressed by the NOTCH–HES canonical pathway in the developing retina.
We further investigated RAX, OTX2, and HES1 expression in the embryonic mouse retina by immunostaining to examine whether both RAX- and OTX2-expressing cells express HES1 (Fig. 8N–P). Most RAX and OTX2 double-expressing cells express notably low levels of HES1 (Fig. 8N,O), supporting the idea that RAX is also expressed in postmitotic photoreceptor precursors as well as in mitotic RPCs. We also investigated whether both RAX- and HES1-expressing cells express OTX2. Most RAX- and HES1-expressing cells did not express OTX2 (Fig. 8N,P), suggesting that activation of Otx2 transcription by RAX requires the downregulation of HES family proteins, consistent with our observations obtained by luciferase reporter assay (Fig. 8A–C).
We further examined the effect of HES1 on Otx2 expression in vivo using transgenic mice. We generated transient transgenic mice using the Crx promoter-driven LacZ control construct or the Crx promoter-driven Hes1 construct (Fig. 9A,F), and examined their retinas by immunostaining at E13.5 (Fig. 9B–D,G–I). While most LacZ-expressing cells overlapped with OTX2-expressing cells (Fig. 9B–E), most HES1-expressing cells did not express OTX2 (Fig. 9G–J), suggesting that HES proteins can suppress Otx2 transcription even in postmitotic photoreceptor precursors by forced expression, because the Crx promoter is active in the postmitotic photoreceptor precursors. HES family protein-mediated Otx2 repression appears to be consistent with the observation that OTX2 expression begins in the final cell cycle of RPCs.
Discussion
Otx2 expression mechanism in embryonic photoreceptor cell fate determination
In the current study, we first observed that OTX2 protein expression begins mainly in the final cell cycle of RPCs (Fig. 1). Expression patterns are similar between Otx2 transcripts detected by in situ hybridization (Fig. 2B) and OTX2 protein detected by immunostaining (Fig. 5L) in the E13.5 retina, indicating that OTX2 protein is expressed soon after Otx2 transcription. We then identified an evolutionarily conserved Otx2 retinal enhancer, EELPOT, which is essential for Otx2 transcription in embryonic photoreceptor precursors. Our results showed that EELPOT is an Otx2 enhancer distinct from the Otx2 brain enhancers (Kurokawa et al., 2004a,b) and directs Otx2 expression in the embryonic retina.
Although Otx2 is required both for cone cell fate determination during embryonic stages and rod cell fate determination mainly at postnatal stages, EELPOT did not appear to direct reporter gene transcription after P0 in the transgenic mouse retina (Fig. 4F,G), suggesting that EELPOT mainly functions to initiate the Otx2 expression required for embryonic photoreceptor cell fate determination but not for the maintenance of Otx2 expression in photoreceptor precursors. This idea is consistent with the observation that the smaller number of LacZ-positive cells were observed in the retina in which the LacZ gene was directed by EELPOT compared with the number of LacZ-positive cells observed in the retina in which LacZ gene expression was directed by Otx2 BAC #2. In addition, RAX did not bind to EELPOT in the P0 retina, supporting the observation that EELPOT is not active in the P0 retina.
The Otx2 expression in photoreceptor cells is significantly downregulated after birth when retinal bipolar cells begin expressing Otx2 in the postnatal retina. The mechanism that downregulates Otx2 expression in photoreceptor cells after birth remains unclear.
Based on our analysis of the EELPOT enhancer, we propose a hypothetical model of the mechanisms of Otx2 expression that directs embryonic photoreceptor cell fate determination (Fig. 10). In proliferating RPCs, activated-NOTCH signaling represses Otx2 expression through HES family molecule-mediated suppression of the EELPOT enhancer, although RAX homeoprotein is expressed in proliferating RPCs. During the final cell cycle, the cell-extrinsic signal activating NOTCH turns off, leading to both the end of cell cycling and the removal of EELPOT suppression by HES. Then RAX is able to transactivate EELPOT resulting in Otx2 transactivation. Our model also may explain how the timing of cell fate determination occurs in the final cell cycle.
It remains unclear whether EELPOT is involved in rod cell fate determination. A different regulatory region(s) from EELPOT may be involved in activating Otx2 transcription in rod cell fate determination. Alternatively, although the EELPOT enhancer becomes very weak after P0, a low level of Otx2 expression may be sufficient for rod cell fate determination. Our observation that EELPOT-driven Otx2 expression restored not only the cone marker but also rhodopsin expression in the Otx2 CKO retina may support this idea. Extensive future analysis of an Otx2 enhancer region at postnatal stages might provide a definitive answer.
Regulation of Otx2 transcription in RPCs by RAX
Rax is a homeodomain-containing transcription factor expressed in RPCs, developing photoreceptor cells, and developing Müller glial cells in the vertebrate retina (Furukawa et al., 1997, 2000; Mathers et al., 1997; Chuang et al., 1999; Nelson et al., 2009; Pan et al., 2010). Since RAX is essential for RPC proliferation, we suppose that ectopic Pax6-positive cells observed in the Rax iCKO retina are amacrine-like cells rather than RPCs (Fig. 7V,W), which are similar to the ones we reported in the Otx2 CKO retina (Nishida et al., 2003). These observations suggest that RAX plays multiple roles, including regulation of progenitor proliferation and cell differentiation, during retinal development. In chick, there are two Rax-like molecules, Rax and RaxL. RaxL, a Rax paralog in chicken, has been implicated in cone photoreceptor differentiation (Chen and Cepko, 2002), while Rax was reported to be involved in progenitor proliferation. No mouse ortholog of chicken RaxL has been identified, raising the possibility that mouse Rax might play roles both in progenitor proliferation and in cone development in mammals. However, it has not been investigated whether RAX regulates Otx2 transcription. Our results suggest that RAX acts as a direct activator of Otx2 transcription in RPCs. We showed that RAX can transactivate EELPOT in cultured cells. Moreover, through ChIP analysis we showed that RAX protein directly binds to EELPOT in the embryonic retina. We also observed that Otx2 expression was reduced in the Rax iCKO retina, indicating that RAX is essential for Otx2 transactivation in the embryonic retina.
We recently reported that the absence of BLIMP1, an OTX2 downstream transcription factor, led to an aberrant increase of Chx10 expression in developing photoreceptors (Katoh et al., 2010). In the Rax iCKO retina, Chx10 might be upregulated due to a defect of the OTX2–BLIMP1 pathway.
Rax has been implicated in the cell fate determination of Müller glia cells in the postnatal retina (Furukawa et al., 2000). However, it is unclear how Rax regulates both cone and Müller glia fate determination. Cell-intrinsic changes of RPC competence during retinal development may be associated with this mechanism. RAX function in cell fate determination may vary in a RPC competence-dependent manner.
Negative regulation of Otx2 by NOTCH–HES signaling
NOTCH signaling has been implicated in retinal cell differentiation (Cayouette and Raff, 2003; Baye and Link, 2007; Del Bene et al., 2008). It was recently reported that NOTCH1 inhibits photoreceptor production in the mammalian retina and that targeted disruption of Notch1 in the developing retina resulted in the enhanced expression of not only proneural genes like NeuroD1 and Math3, but also Otx2 and Crx, which are expressed exclusively in the photoreceptor cells in the embryonic retina at E13.5, suggesting that NOTCH signaling is involved in photoreceptor cell fate determination (Jadhav et al., 2006; Yaron et al., 2006). However, it has not been determined whether Otx2 expression was directly regulated by NOTCH signaling or not, because blocking NOTCH signaling induces neuronal differentiation in RPCs whereby transcription factors such as OTX2 are induced independently of NOTCH signaling as an indirect effect. Otx2 expression is upregulated in the RBPj-null retina, suggesting that RBPj-regulated genes, including Hes and Hey genes, are involved in Otx2 gene regulation. HES1 or HES5 single knock-out mice did not exhibit overproduction of photoreceptors (Hojo et al., 2000; Takatsuka et al., 2004; Riesenberg et al., 2009), suggesting that HES and/or HEY proteins are functionally redundant in repressing Otx2 transcription. Our ChIP assay results suggest that HES1, at least, binds to EELPOT. Together, our results suggest that N-box binding proteins, including HES or HEY family proteins, are involved in Otx2 regulation directly in RPCs, serving a permissive role in Otx2 transcription. Since RAX, a transcriptional activator, is expressed in OTX2-positive photoreceptor precursors and HES1 expression, a transcriptional repressor, does not overlap with OTX2-positive cells, we suppose that HES family proteins may function as permissive factors, although we cannot exclude the possibility that NOTCH signaling may have an instructive role rather than a permissive role in photoreceptor cell fate determination. Our current study on EELPOT is consistent with various reports that NOTCH signaling has a role in photoreceptor cell fate determination (Jadhav et al., 2006; Yaron et al., 2006). Our results also suggest that HES and/or HEY proteins may regulate photoreceptor production, at least in part, by directly controlling Otx2 transcription machinery, although the molecular mechanisms that regulate the timing of NOTCH downregulation remain unknown. A cell-extrinsic signal is likely to regulate the NOTCH–RBPJ–HES pathway; however, understanding exactly what and how extrinsic signals regulate the NOTCH pathway in photoreceptor cell fate determination will await future study.
Our current study suggests that photoreceptor cell fate determination is realized, at least in part, through the activities of both cell intrinsic (RAX homeoprotein) and extrinsic (NOTCH–HES family) factors on a key enhancer locus (EELPOT) during the final cell cycle.
Footnotes
This work was supported by Core Research for Evolutional Science and Technology from Japan Science and Technology Agency, Grant-in-Aid for Scientific Research (B), and Young Scientists (B) from Ministry of Education, Culture, Sports, Science and Technology, The Takeda Science Foundation, The Uehara Memorial Foundation, Naito Foundation, Kato Memorial Bioscience Foundation, and Japan National Society for the Prevention of Blindness. We thank Akiko Tani, Mikiko Kadowaki, Aiko Ishimaru, Hiroko Abe, and Shawna Kennedy for technical assistance, and Dr. Miyazaki for providing us the CAG-CAT-Z mouse.
The authors declare no competing financial interests.
- Correspondence should be addressed to Takahisa Furukawa, Department of Developmental Biology, Osaka Bioscience Institute, 6-2-4 Furuedai, Suita, Osaka 565-0874, Japan. furukawa{at}obi.or.jp