Analysis of Transcriptional Regulatory Pathways of Photoreceptor Genes by Expression Profiling of the Otx2-Deficient Retina

Yoshihiro Omori; Kimiko Katoh; Shigeru Sato; Yuki Muranishi; Taro Chaya; Akishi Onishi; Takashi Minami; Takashi Fujikado; Takahisa Furukawa

doi:10.1371/journal.pone.0019685

Abstract

In the vertebrate retina, the Otx2 transcription factor plays a crucial role in the cell fate determination of both rod and cone photoreceptors. We previously reported that Otx2 conditional knockout (CKO) mice exhibited a total absence of rods and cones in the retina due to their cell fate conversion to amacrine-like cells. In order to investigate the entire transcriptome of the Otx2 CKO retina, we compared expression profile of Otx2 CKO and wild-type retinas at P1 and P12 using microarray. We observed that expression of 101- and 1049-probe sets significantly decreased in the Otx2 CKO retina at P1 and P12, respectively, whereas, expression of 3- and 4149-probe sets increased at P1 and P12, respectively. We found that expression of genes encoding transcription factors involved in photoreceptor development, including Crx, Nrl, Nr2e3, Esrrb, and NeuroD, was markedly down-regulated in the Otx2 CKO at both P1 and P12. Furthermore, we identified three human retinal disease loci mapped in close proximity to certain down-regulated genes in the Otx2 CKO retina including Ccdc126, Tnfsf13 and Pitpnm1, suggesting that these genes are possibly responsible for these diseases. These transcriptome data sets of the Otx2 CKO retina provide a resource on developing rods and cones to further understand the molecular mechanisms underlying photoreceptor development, function and disease.

Citation: Omori Y, Katoh K, Sato S, Muranishi Y, Chaya T, Onishi A, et al. (2011) Analysis of Transcriptional Regulatory Pathways of Photoreceptor Genes by Expression Profiling of the Otx2-Deficient Retina. PLoS ONE 6(5): e19685. https://doi.org/10.1371/journal.pone.0019685

Editor: Karl-Wilhelm Koch, University of Oldenburg, Germany

Received: February 1, 2011; Accepted: April 4, 2011; Published: May 13, 2011

Copyright: © 2011 Omori et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Funding: This work was supported by CREST and PRESTO (#4118) from Japan Science and Technology Agency (http://www.jst.go.jp/), and a Grant for Molecular Brain Science, a Grant-in-Aid for Scientific Research (B) (#20390087), Young Scientists (B) (#21790295), from Ministry of Education, Culture, Sports, Science and Technology (http://www.jsps.go.jp/), The Takeda Science Foundation (http://www.takeda-sci.or.jp/), The Uehara Memorial Foundation (http://www.ueharazaidan.com/), Naito Foundation (http://www.naito-f.or.jp/), Novartis Foundation (#20-10, http://novartisfound.or.jp/), Mochida Memorial Foundation for Medical and Pharmaceutical Research (http://www.mochida.co.jp/zaidan/), Senri Life Science Foundation (#S-2144, http://www.senri-life.or.jp/), Kato Memorial Bioscience Foundation (http://www.katokinen.or.jp/), and Japan National Society for the Prevention of Blindness (http://www.nichigan.or.jp/link/situmei.jsp). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

During mammalian retinogenesis, five major types of neurons arise from multipotent progenitor cells, which are common precursors for all retinal neurons and glia [1], [2], [3]. We previously demonstrated that Otx2, an Otx-like homeobox gene, is essential for the cell fate determination of retinal photoreceptor cells [4]. Otx2 conditional knockout (CKO) mice showed a cell fate switch from retinal photoreceptor precursor cells to amacrine-like cells. On the other hand, several transcription factors including Crx, Nrl and Nr2e3 are essential for terminal differentiation of photoreceptors. Crx encodes an Otx-like homeodomain transcription factor essential for terminal differentiation of both rods and cones by regulating genes encoding phototransduction, photoreceptor metabolism and outer segment formation [5], [6]. Crx knockout (KO) mice develop aberrant photoreceptors that lack both rod and cone photoresponses [7]. In humans, mutations in CRX are associated with retinal degeneration diseases such as cone-rod dystrophy-2, retinitis pigmentosa (RP), and Leber congenital amaurosis (LCA) [6], [8], [9], [10]. Nrl (neural retina leucine zipper gene) is a transcription factor of the leucine zipper family expressed predominantly in rods but not in cones [11]. Mice lacking the Nrl gene do not develop rods but produce an increased number of short wavelength-sensitive cones (S-cones) [12]. Nrl promotes rod development by directly activating rod-specific genes while simultaneously suppressing the S-cone related genes through the activation of transcriptional repressor Nuclear receptor subfamily 2 group E member 3 (Nr2e3) [12]. Mutations in human NR2E3 cause enhanced S-cone syndrome [13]. The rd7 mouse has a genetic defect in the Nr2e3 gene and exhibits an increased number of cones [14]. Mice lacking retinoid-related orphan nuclear receptor β (Rorb) were shown to lose rods but overproduce primitive S-cones, similar to Nrl KO mice [15]. In addition, several other nuclear receptors are involved in both photoreceptor development and transcriptional regulation of photoreceptor-specific genes. During the terminal differentiation of cone photoreceptors, thyroid hormone receptor β2 (Trb2) is critical for M-opsin induction [16], whereas retinoid X receptor γ (Rxrg) is essential for suppressing S-opsin in cone photoreceptors [17]. Retinoic acid receptor-related orphan receptor α (Rora) directly controls expression of cone opsins and arrestin3 [18]. In rod photoreceptor cells, estrogen-related receptor β (Esrrb) regulates expression of rod-specific genes and controls rod photoreceptor survival [19]. Recently, Pias3, an E3 SUMO ligase which is selectively expressed in developing photoreceptors, was shown to SUMOylate Nr2e3 and promote the differentiation of rod-photoreceptors [20]. In addition, Pias3 regulates expression of cone opsins by modulating Rxrg, Rora, and Trb1 [21].

During the terminal differentiation of photoreceptors, the photoreceptor axon terminal develops a highly specialized synapse, the ribbon synapse, which connects photoreceptor axonal terminals with bipolar and horizontal dendritic terminals in the outer plexiform layer (OPL) of the retina [22]. The functional ribbon synapse structure is organized by the precise assembly of presynaptic components including CtBP2, bassoon, pikachurin, CaBP4 and Cacna1f [23], [24], [25], [26]. Photoreceptor cells develop the photosensitive outer segments which contain molecules involved in phototransduction, such as opsins and transducins, and outer segment morphogenesis factors, such as Rom1 and Peripherin2 [27]. Outer segments are formed from the primary cilia [28]. In humans disruption of photoreceptor ciliary function causes retinal diseases including retinitis pigmentosa, Bardet-Biedl syndrome (BBS) and Nephronophthisis (NPHP) [27], [29], [30]. Mutations in genes encoding ciliary components including Rpgrip1, Rp1, and Mak cause photoreceptor degeneration and retinal dysfunction in mice [31], [32], [33].

To our knowledge, the Otx2 CKO mouse is the only mutant which shows defects of both rods and cones in the retina from early developmental stages. In this study, we investigated the transcriptional profile of both developing rods and cones by taking advantage of the Otx2 CKO retina.

Results

Identification of differentially expressed genes in the Otx2 CKO retina

In order to clarify the molecular role of Otx2 in transcriptional regulation during development, we investigated the expression profile of the Otx2 CKO retina compared with that of the control retina with the genotype Otx2^flox/flox/Crx-cre^- using microarrays at two time points, postnatal day 1 (P1) and P12. From middle late embryonic stages cones are generated with almost all of the cones formed by P0 [34]. Rods begin to form in embryonic stages whereas, photoreceptor maturation, including ribbon synapse and outer segment formation, occurs in P0 to P14 [35], [36]. By P12, all photoreceptor cells are born, however, photoreceptor maturation, such as outer segment formation, is ongoing. Thus, we expect that the expression profile at P1 will mainly reflect cone development and early rod development, and the expression profile at P12 will mainly reflect rod development.

We performed genome-wide expression profiling using a microarray containing 45,101 probe sets covering more than 34,000 genes (Mouse Genome 430 2.0; Affymetrix). In the Otx2 CKO retina at P1, we identified 101 down-regulated probes (signal log ratio ≤−1.0, signal intensity ≥50) and 3 up-regulated probes (signal log ratio ≥+1.0, signal intensity ≥50) compared to the control retina at P1. In the Otx2 CKO retina at P12, we identified 1049 down-regulated probes (signal log ratio ≤−1.0, signal intensity ≥50) and 4149 up-regulated probes (signal log ratio ≥+1.0, signal intensity ≥50) compared to the control retina at P12.

To compare the features of these groups of probe sets, we categorized functions of these genes based on their gene ontology (GO) term annotations (Fig. 1). Genes involved in “phototransduction” and “ciliary function” in the photoreceptor cells were observed in the groups with down-regulated expression in the Otx2 CKO retina at both P1 and P12. The proportion of probe sets involved in these categories increased in the P12 down-regulated group (21% for phototransduction, 6% for ciliary function) compared to P1 down-regulated group (8% for phototransduction, 1% for ciliary function). We found that the proportion of genes categorized in “cell cycle” and “transcription” in the up-regulated probes in the Otx2 CKO retina was higher than that in down-regulated probes both at P1 and P12.

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Figure 1. Categorization of the genes differentially expressed in the Otx2 CKO retina.

According to gene ontology (GO) term annotation, the genes differentially expressed in the Otx2 CKO retinas at P1 and P12 were categorized into functional groups. We used GO term data on 101 probes with decreased expression in the Otx2 CKO at P1 (signal log ratio ≤−1.0, signal intensity ≥50), 36 probes with increased expression in the Otx2 CKO at P1 (signal log ratio ≥+0.5, signal intensity ≥50), 241 probes with decreased expression in the Otx2 CKO at P12 (signal log ratio ≤−2.5, signal intensity ≥100), and 121 probes with increased expression in the Otx2 CKO at P12 (signal log ratio ≥+2.5, signal intensity ≥100).

https://doi.org/10.1371/journal.pone.0019685.g001

Using the data from three independent microarray experiments at P1 and P12, we performed hierarchical clustering analysis on 46 strongly down-regulated genes (signal log ratio ≤−5.0, signal intensity ≥100, Table 1) and 37 up-regulated genes (signal log ratio ≥+3.0, signal intensity ≥100, Table 2) in the Otx2 CKO retina at P12 (Fig. 2). Expression levels of all of strongly down-regulated genes were more than 10 times higher in the P12 control retina compared to those of P1. Most of these down-regulated genes encode known photoreceptor-associated genes including transcription factors (Crx, Nrl, Nr2e3), and phototransduction molecules (Rho, Opn1mw, Pde6a, Pde6b, Cnga1) (Fig. 2, Table 1). We also confirmed that the genes encoding photoreceptor ciliary and ribbon synaptic components including Rpgrip1, Rp1, Cabp4, Pikachurin, and Cacna1f showed drastically decreased expression both in microarray and Q-PCR analysis (Fig. 3).

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Figure 2. Clustering analysis of retinal gene expression profiles in the Otx2 CKO and control retinas.

(A, B) Matrices were visualized as hierarchical clustering of down-regulated (A) and up-regulated (B) genes in the Otx2 CKO retina at P1 and P12. Each gene was visualized as a single row of colored squares. The color indicates the relative expression level of a gene. Signal log ratio (SLR) was calculated based on the average of signal intensity of the control retina at P12. The color scale ranges are from signal log ratios of −15 to +15 (A) and −8 to +8 (B) as shown in the scale bar on the bottom of the figure. Gene symbols are indicated in the lists on the right of the matrixes. Hierarchical clustering was performed by the EPCLUST program (http://www.bioinf.ebc.ee/EP/EP/EPCLUST/).

https://doi.org/10.1371/journal.pone.0019685.g002

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Figure 3. Expression of genes encoding photoreceptor ciliary and ribbon synaptic components in the Otx2 CKO and Crx KO retina.

Expression levels of genes encoding photoreceptor ciliary and ribbon synaptic components in the control, Otx2 CKO and Crx KO retinas at P12 were analyzed by Q-PCR. Expression levels of selected genes were normalized to the expression levels of a housekeeping gene, Gapdh. Primer sequences for PCR were shown in Table S1. The mean of the value of control at P12 was set as 1.0. Error bars show the SD (n = 3). *, P<0.03.

https://doi.org/10.1371/journal.pone.0019685.g003

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Table 1. Genes down-regulated in the Otx2 CKO retina (signal log ratio ≤−5.0).

https://doi.org/10.1371/journal.pone.0019685.t001

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Table 2. Genes up-regulated in the Otx2 CKO retina (signal log ratio ≥+3.0).

https://doi.org/10.1371/journal.pone.0019685.t002

In contrast, the expression profile of strongly up-regulated genes was grouped into two clusters (Fig. 2B, Table 2). Most of members in the first group (15 genes) were down-regulated in the P12 control retina compared to that of P1. This cluster includes transcription factors Dlx1, Dlx2, Sox11 and Mycl1. These genes are possibly involved in several retinal development events such as proliferation of progenitor cells, maturation of early photoreceptor precursors, and cell fate determination of progenitor cells. Consistent with this result, more probes categorized in “cell cycle” were observed in the up-regulated groups (8% at P1 and 4% at P12) compared to those in the down-regulated groups (2% at both P1 and P12) (Fig. 1). Most of members in the second cluster (22 genes) were up-regulated in the P12 control retina compared to that of P1. This group includes Car3, Spp1, Cst7 and Col12a1. We suppose that these genes encode components associated with the increase of amacrine-like cells in the Otx2 CKO retina.

To determine whether up- or down-regulated genes in the Otx2 CKO retina are indeed enriched for sets of genes expressed selectively in individual retinal cell subtypes, we performed a statistical analysis. We compared our microarray data sets with previously reported cellular expression patterns of each retinal gene obtained from published in situ hybridization data [37]. Forty-five of 84 probes corresponding to photoreceptor-specific genes previously identified by in situ hybridization analysis were found in the group down-regulated in the Otx2 CKO retina (1049 probes; signal log ratio ≤-1.0, signal intensity ≥50). Twenty-one of 70 probes corresponding to amacrine-specific genes previously identified by in situ hybridization analysis were found in the group up-regulated in the Otx2 CKO retina (4149 probes; signal log ratio ≥+1.0, signal intensity ≥50). This data shows that photoreceptor-specific genes are strongly enriched in the group down-regulated in P12 Otx2 CKO (P<0.01), whereas, the amacrine-specific genes are enriched in the group up-regulated in the P12 Otx2 CKO retina (P<0.01).

Furthermore, we compared our microarray data with previously reported cellular expression patterns of each retinal gene obtained from published results of in situ hybridization [37], [38], immunohistochemistry [39], [40], and cell type–specific GFP expression in the retina using BAC transgenic mice from the GENSAT project [41] (Table 1 and 2). In addition, we searched cone- and rod-specific genes based on the microarray data from Nrl KO mice [42] (signal log ratio ≤−2.0 for “down” or ≥+2.0 for “up”). Most of the down-regulated genes in P12 Otx2 CKO were known cone, rod or pan-photoreceptor genes (Table 1), whereas, several genes up-regulated in the Otx2 CKO retina were known amacrine- or INL-expressed genes. Expression patterns of many genes in the latter group were previously unidentified in the retina (Table 2).

Expression profiles of Crx, Nrl, and Nr2e3-null retinas were reported previously [42], [43], [44], [45]. We compared datasets of the Otx2 CKO retina with those of the Crx, Nrl, and Nr2e3-null retinas (Fig. 4, Text S1). We found that the expression of 84 probes was strongly decreased in both the Otx2 CKO and Crx KO retinas (signal log ratio ≤−2.0, Fig. 4A). This group includes both rod and cone photoreceptor genes such as Rhodopsin (Rho) and S-opsin (Opn1sw). The expression of 48 probes was markedly decreased in both the Otx2 CKO and Nrl KO retinas (signal log ratio ≤−2.0, Fig. 4B). These genes include rod-specific genes such as Pde6b and Rho. We identified 18 probes that were down-regulated in the Otx2 CKO retina but up-regulated in the Nrl KO retina, including cone photoreceptor genes such as Opn1sw, cone arrestin (Arr3) and Pde6c (Fig. 4B). Five of six genes down-regulated in the Otx2 CKO retina but up-regulated in the Nr2e3-null retina overlapped with the probes down-regulated in the Otx2 CKO and up-regulated in the Nrl KO retina (Fig. 4C).

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Figure 4. Comparison gene expression profiles with the Otx2-CKO retina.

(A-C) Microarray analysis datasets from Crx (A), Nrl (B), Nr2e3 (C) KO retinas were compared with that from the Otx2 CKO retina at P12. We identified 367 down-regulated probes in the Otx2 CKO retina (signal log ratio ≤−2.0, signal intensity ≥74). We used datasets from previous microarray analysis of the Crx, Nrl and Nr2e3-null retinas at P21 with the following results: 154 probes down-regulated in the Crx KO retina (signal log ratio ≤−2.0, signal intensity ≥352), 63 probes up-regulated in the Crx KO retina (signal log ratio ≥+2.0, signal intensity ≥345), 95 probes down-regulated in the Nrl KO retina (signal log ratio ≤−2.0, signal intensity ≥354), 186 probes up-regulated in the Nrl KO retina (signal log ratio ≥+2.0, signal intensity ≥347), 9 probes down-regulated in the Nr2e3-null (rd7) retina (signal log ratio ≤−2.0, signal intensity ≥354), 37 probes up-regulated in the Nr2e3-null retina (signal log ratio ≥+2.0, signal intensity ≥358). The numbers of probes in each category were indicated.

https://doi.org/10.1371/journal.pone.0019685.g004

Otx2 regulates expression of transcription factors involved in retinal development

To investigate the transcriptional network of Otx2-regulated genes, we first focused on the expression of transcription factors involved in retinal development. We previously showed that Crx expression was absent in the Otx2 CKO retina at E18.5, however, the expression of other transcription factors involved in photoreceptor development was not determined [4]. We selected the microarray data sets of 28 transcription factors known to be involved in retinal development (Table 3), and found that the expression of several transcription factor genes (Crx, Nrl, Nr2e3, Esrrb, Isl1, Blimp1, Pias3 and NeuroD) was strongly reduced at P12 (signal log ratio ≤−2.1), whereas the expression level of Pax6 was increased consistent with the previous result by immunohistochemical analysis [4], [46](Table 3). In addition, we found that the expression of Crx, Nrl and Nr2e3 was strongly reduced at P1 as well (signal log ratio ≤−3.7, Table 3). To validate these microarray results, we carried out quantitative real-time RT-PCR analysis (Q-PCR) for these genes. The Q-PCR results clearly reflect the changes observed in the microarray analysis for all of the genes we tested (Fig. 5).

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Figure 5. Otx2 regulates expression of transcription factors involved in retinal development.

Expression levels of selected transcription factor genes in the control (at P1 and P12), Otx2 CKO (at P1 and P12) and Crx KO (at P12) retinas were analyzed by Q-PCR. Expression levels of selected genes were normalized to the expression levels of a housekeeping gene, Gapdh. The mean of the value of each control at P12 was set as 1.0. Error bars show the SD (n = 3). *, P<0.03.

https://doi.org/10.1371/journal.pone.0019685.g005

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Table 3. Expression of transcription factors involved in retinal development in the Otx2 CKO retina.

https://doi.org/10.1371/journal.pone.0019685.t003

To compare expression of the transcription factor genes examined with those in the Crx KO retina, we analyzed their expression level in the P12 Crx KO retina by Q-PCR. In contrast to the drastic decrease of expression in the Otx2 CKO retina, the expression of most of the transcription factors examined showed only a minor change in the Crx KO retina at P12 compared to that of the control retina from wild-type 129/SvEv. The only notable exception was Esrrb which was strongly down-regulated in the Crx KO (Fig. 5) [43]. Similar to these transcription factors, we found that the expression changes in genes encoding ciliary and ribbon synaptic components in the Crx KO retina were milder than those in the Otx2 CKO retina (Fig. 3).

Identification of retinal disease candidate genes

Human homolog mutations of many genes with photoreceptor-associated expression have been shown to be associated with retinal diseases including RP [27]. Since many of the Otx2 CKO down-regulated genes at P12 were photoreceptor-associated genes (Table 1), we supposed that mutations of human homologs of these down-regulated genes may be responsible for retinal degeneration diseases. To identify retinal disease candidate genes, we determined the chromosomal loci of human homologs of these down-regulated genes and compared these loci with the mapped loci of various hereditary retinal diseases (RetNet, the Retinal Information Network, http://www.sph.uth.tmc.edu/RetNet/). We found that three human retinal disease loci were mapped in close proximity to the markedly down-regulated genes in the Otx2 CKO retina. Human CCDC126 is located on 7p15.3 where dominant cystoid macular dystrophy has been mapped [47]. Human PITPNM1 is located on 11q13 where autosomal dominant neovascular inflammatory vitreoretinopathy was reported [48].

Central areolar choroidal dystrophy was confined to a critical region, an interval of approximately 2.4 Mb (5 cM) flanked by polymorphic markers D17S1810 and CHLC GATA7B03 on chromosome 17p13 [49]. Human TNFSF13 is located between these intervals. The photoreceptor-enriched expression pattern and genomic localization of Tnfsf13 have been previously reported [37], [38]. Ccdc126, Tnfsf13 and Pitpnm1 were strongly down-regulated in the Otx2-CKO retina, showing signal log ratios of −3.5, −3.0 and −2.4, respectively. We confirmed the decreased expression of these genes in the Otx2-null retina by Q-PCR analysis (Fig. 6).

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Figure 6. Expression of identified candidate genes for human retinal diseases in the Otx2 CKO retina.

Expression of identified candidate genes for human retinal diseases was analyzed by Q-PCR. Expression levels of selected genes were normalized to the expression levels of a housekeeping gene, Gapdh. The mean of the value of control at P12 was set as 1.0. Error bars show the SD (n = 3). *, P<0.03.

https://doi.org/10.1371/journal.pone.0019685.g006

Discussion

Otx2 regulates the transcriptional network in photoreceptor development

The main goal of this study is to obtain information and gain insights into the transcriptional network in photoreceptor development regulated by Otx2. Thus, we examined the retinal gene expression profiles of the Otx2 CKO retina at P1 and P12, and identified significant changes in the expression of genes encoding transcription factors, components of the cilium and ribbon synapse. Our microarray analysis and Q-PCR validation of the Otx2 CKO retina revealed strong down-regulation of multiple transcription factors involved in photoreceptor development, including Crx, Nrl, Esrrb, NeuroD, Isl1, Blimp1, Pias3 and Nr2e3. These data support the hypothesis that Otx2 organizes a transcription factor network in photoreceptor development. A previous study showed that a considerable amount of Nrl expression remains in the Crx KO retina, and, similarly, Crx expression remains in the Nrl KO retinas [43], [44], suggesting that Otx2 regulates the expression of Nrl and Crx by parallel pathways. Otx2 directly regulates Crx expression through binding to cis-regulatory elements on the Crx promoter region [4]. Does Otx2 directly regulate other transcription factors involved in photoreceptor development? The 2.4 kb fragment in the 5′ region of the Nrl locus is essential for its expression in photoreceptors and contains Crx/Otx2 binding sites [43]. Since Otx2 and Crx can bind to the same DNA consensus sequence [5], [50], it is possible that Otx2 binds to these cis-regulatory elements and directly regulates Nrl expression. In contrast, we found that Esrrb expression is almost abolished in both the Otx2 CKO and the Crx KO retinas, showing that Esrrb is likely to be regulated directly by Crx and indirectly by Otx2. Similarly, Nr2e3 expression in the Nrl KO was almost abolished [12], suggesting that Nr2e3 expression is directly regulated by Nrl and indirectly regulated by Otx2. We found that expression of Isl1, NeuroD, Blimp1, and Pias3 was markedly decreased in the P12 Otx2 CKO retina, however, considerable amounts of expression remained in the Nrl KO and Crx KO retinas [43]. This result suggests that Isl1, NeuroD, Blimp1, and Pias3 are the direct targets of Otx2. We searched for the Otx2/Crx-binding consensus sequence “TAATC” within 5 kb of the 5′ upstream region of each gene, and found that each of the 5′ regions of Isl1, NeuroD and Pias3 genes contains clusters of the Otx2/Crx-binding sequence (−2.3 to −2.7 kb, 5 sites for Isl1; −4.2 to −4.9 kb, 4 sites for NeuroD; and −1.3 to −2.0 kb, 4 sites for Pias3). Otx2 may directly regulate expression of these transcription factors through these Otx2/Crx-binding sequence clusters. In contrast to the down-regulation of transcription factors involved in photoreceptor development, we observed a 3.0-fold increase of Pax6 expression in the P12 Otx2 CKO retina. This is probably due to the increase of the amacrine cell population, since amacrine cell markers including Glyt1 and Gad65 also increased in the Otx2 CKO at a similar level (3.0-fold increase for Glyt1, 3.5-fold increase for Gad65). The result from microarray analysis is consistent with that from immunohistochemical analysis of the Otx2 CKO retina [4].

We found that photoreceptor-specific genes are strongly enriched in the group of down-regulated probes in the P12 Otx2 CKO retina, whereas amacrine-specific genes are enriched in the group of up-regulated probes in the P12 Otx2 CKO retina. Although many of down-regulated genes in the P12 Otx2 CKO retina were known photoreceptor genes, the expression patterns of several genes, including BC027072/C2orf71, LOC100048701, A930003A15Rik, and 2610034M16Rik, have not been analyzed in the retina. These genes are strong candidates for photoreceptor-specific genes. Expression of 2610034M16Rik was decreased in the Nrl KO retina, suggesting that this gene is expressed in rod photoreceptors. In contrast to the high enrichment of photoreceptor genes in the Otx2 down-regulated probes, amacrine genes were enriched in the group up-regulated in the Otx2 CKO retina. This group seems to contain not only amacrine associated genes but also various genes from cell types including Muller glia and cells in ganglion cell layer. This result may reflect the increase of aberrant “amacrine-like cells” in the Otx2 CKO retina.

We found that genes encoding synaptic components (e.g. CaBP4, Cacna1f and Pikachurin) and ciliary components (e.g. Rpgrip1 and Rp1) were also significantly downregulated in the Otx2 CKO retina. We previously demonstrated that rhodopsin- and Crx-positive cells were absent in the Otx2 CKO retina [4], however, there is a possibility that the increased amacrine-like cells converted from photoreceptors in the Otx2 CKO retina still express photoreceptor-related molecules. Our findings in the present study excluded this possibility and support the idea that Otx2 executes a genetic program on photoreceptor cell fate determination and differentiation. Thus, the transcriptional profile data in this study will be a useful resource to identify genes involved in development and maintenance of both rods and cones.

Previously, we showed that Otx2 is essential for bipolar cell development [51]. Consistent with this, we observed significant decreases in bipolar genes, including Bhlhb4, Chx10, Cabp5 and Pcp2, in the Otx2 CKO retina.

The morphological features of rod and cone photoreceptor ribbon synaptic terminals are different; rod photoreceptors form small synaptic terminals with a single ribbon, whereas, cone photoreceptors form larger terminals containing several ribbons with a shorter active zone [24]. These structural differences might be derived from differences of synaptic components. Transcription factors involved in photoreceptor terminal differentiation such as Nrl and Nr2e3 may regulate the expression of rod- or cone-specific synaptic components and contribute to the formation of different structures between cone and rod photoreceptors. Compared with the previous microarray studies, we identified 48 down-regulated probes in both the Otx2 CKO and Nrl KO retinas, while at the same time, 18 probes were down-regulated in the Otx2 CKO but up-regulated in the Nrl KO retina. These data can be a useful resource for finding different mechanisms between cone and rod photoreceptor formation, including ribbon synapse structures.

Identification of retinal disease candidate genes from Otx2 downstream genes

The expression profiles of several transcription factors which were shown to be critical for photoreceptor terminal differentiation have been analyzed by microarray or SAGE analysis. The expression profile of the Crx KO retina was analyzed using both cDNA microarray and SAGE [38], [43], [52]. Analyses of the expression profiles of Nrl KO, Nr2e3 KO or Nrl & Nr2e3 double KO retinas were performed using microarrays [42], [43], [44], [45]. Lack of Crx does not affect photoreceptor cell fate but does result in abnormal photoreceptor morphogenesis [7]. Lack of either Nrl or Nr2e3 causes photoreceptor subtype conversion from rod photoreceptor to S-cone photoreceptors [12], [14]. Since deletion of Otx2 leads to a total loss of photoreceptors in the retina, by comparing expression profiles between the Otx2 CKO retina and control retina, we were able to identify photoreceptor-associated genes more clearly than by using other mutant retinas. Comparing the expression profiles between the Otx2 CKO and other mutant mice may provide novel insight into genetic transcriptional networks in photoreceptor development. Furthermore, we identified several retinal disease candidate genes among the genes down-regulated in the Otx2 CKO retina based on information from RetNet's mapped retinal disease loci. Linking information from other databases to the set of Otx2 down-regulated genes presented in our study may give unexpected insights into photoreceptor biology. For example, proteome analysis of purified photoreceptor sensory cilium revealed that this complex contains 1,968 proteins [53]. By comparing our data and the data from other studies, a novel insight on the mechanisms of retinal disease might be obtained in the future.

Materials and Methods

Animals

The Otx2 CKO and Crx KO mice were generated in our previous studies [4], [7]. All procedures conformed to the ARVO statement for the Use of Animals in Ophthalmic and Vision Research, and these procedures were approved by the Institutional Safety Committee on Recombinant DNA Experiments and the Animal Research Committee of Osaka Bioscience Institute (approval ID 10-401). Mice were housed in a temperature-controlled room with a 12 h light/dark cycle. Fresh water and rodent diet were available at all times.

Microarray profiling

The P1 or P12 retinas of mouse were dissected. Total RNA (5 µg) of the retina was isolated using TRIzol reagent (Invitrogen) and converted to cDNA using One-Cycle cDNA synthesis kit (Affymetrix) according to the manufacture's instruction. Biotin-labeled cRNA was prepared using IVT labeling kit and hybridized to GeneChip mouse genome 430 2.0 array (Affymetrix). Signal intensity was determined using GeneChip Operating Software 1.4. Microarray expression data are MIAME compliant and have been deposited in a MIAME compliant database (GEO accession number GSE21900).

Q-PCR

The P1 or P12 retinas of mouse were dissected. Total RNA (1 µg) of the retina was isolated using TRIzol reagent (Invitrogen) and converted to cDNA using Superscript II RTase (Invitrogen). Real time qPCR was performed using Cyber Green ER qPCR Super MIX (Invitrogen) and Thermal Cycler Dice Real Time System single MRQ TP870 (Takara) according to the manufacture's instruction. Quantification was performed by Thermal Cycler Dice Real Time System software Ver. 2.0 (Takara). To amplify the gene fragments, we used primers as listed in Table S1.

Supporting Information

Table S1.

Primers for Q-PCR analysis.

https://doi.org/10.1371/journal.pone.0019685.s001

(XLS)

Text S1.

Probe IDs and gene symbols for each group in Figure 4.

https://doi.org/10.1371/journal.pone.0019685.s002

(DOC)

Acknowledgments

We thank M. Kadowaki, M. Joukan, A. Tani, T. Tsujii, A. Ishimaru, Y. Saioka, K. Sone and S. Kennedy for technical assistance.

Author Contributions

Conceived and designed the experiments: T. Furukawa. Performed the experiments: YO KK SS YM TC AO TM. Analyzed the data: YO KK SS T. Furukawa. Wrote the paper: YO T. Furukawa. Supervised the experiments: T. Fujikado T. Furukawa.

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33. Omori Y, Chaya T, Katoh K, Kajimura N, Sato S, et al. (2010) Negative regulation of ciliary length by ciliary male germ cell-associated kinase (Mak) is required for retinal photoreceptor survival. Proc Natl Acad Sci U S A 107: 22671–22676.
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44. Yoshida S, Mears AJ, Friedman JS, Carter T, He S, et al. (2004) Expression profiling of the developing and mature Nrl-/- mouse retina: identification of retinal disease candidates and transcriptional regulatory targets of Nrl. Hum Mol Genet 13: 1487–1503.
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45. Corbo JC, Cepko CL (2005) A hybrid photoreceptor expressing both rod and cone genes in a mouse model of enhanced S-cone syndrome. PLoS Genet 1: e11.
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- Google Scholar
46. Katoh K, Omori Y, Onishi A, Sato S, Kondo M, et al. (2010) Blimp1 suppresses Chx10 expression in differentiating retinal photoreceptor precursors to ensure proper photoreceptor development. J Neurosci 30: 6515–6526.
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- Google Scholar
47. Kremer H, Pinckers A, van den Helm B, Deutman AF, Ropers HH, et al. (1994) Localization of the gene for dominant cystoid macular dystrophy on chromosome 7p. Hum Mol Genet 3: 299–302.
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50. Bobola N, Briata P, Ilengo C, Rosatto N, Craft C, et al. (1999) OTX2 homeodomain protein binds a DNA element necessary for interphotoreceptor retinoid binding protein gene expression. Mech Dev 82: 165–169.
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Google Scholar

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[36] Google Scholar

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Google Scholar

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[ref14] 14. Haider NB, Naggert JK, Nishina PM (2001) Excess cone cell proliferation due to lack of a functional NR2E3 causes retinal dysplasia and degeneration in rd7/rd7 mice. Hum Mol Genet 10: 1619–1626.
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Google Scholar

[41] View Article

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View Article
Google Scholar

[44] View Article

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[ref16] 16. Ng L, Hurley JB, Dierks B, Srinivas M, Salto C, et al. (2001) A thyroid hormone receptor that is required for the development of green cone photoreceptors. Nat Genet 27: 94–98.
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Google Scholar

[47] View Article

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Google Scholar

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View Article
Google Scholar

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Google Scholar

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Google Scholar

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View Article
Google Scholar

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View Article
Google Scholar

[68] View Article

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View Article
Google Scholar

[71] View Article

[72] Google Scholar

[ref25] 25. Zeitz C, Kloeckener-Gruissem B, Forster U, Kohl S, Magyar I, et al. (2006) Mutations in CABP4, the gene encoding the Ca2+-binding protein 4, cause autosomal recessive night blindness. Am J Hum Genet 79: 657–667.
View Article
Google Scholar

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[ref26] 26. Sato S, Omori Y, Katoh K, Kondo M, Kanagawa M, et al. (2008) Pikachurin, a dystroglycan ligand, is essential for photoreceptor ribbon synapse formation. Nat Neurosci 11: 923–931.
View Article
Google Scholar

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View Article
Google Scholar

[80] View Article

[81] Google Scholar

[ref28] 28. Tokuyasu K, Yamada E (1959) The fine structure of the retina studied with the electron microscope. IV. Morphogenesis of outer segments of retinal rods. J Biophys Biochem Cytol 6: 225–230.
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Google Scholar

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[ref30] 30. Gerdes JM, Davis EE, Katsanis N (2009) The vertebrate primary cilium in development, homeostasis, and disease. Cell 137: 32–45.
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Google Scholar

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Google Scholar

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View Article
Google Scholar

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Google Scholar

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View Article
Google Scholar

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View Article
Google Scholar

[104] View Article

[105] Google Scholar

[ref36] 36. Blanks JC, Adinolfi AM, Lolley RN (1974) Synaptogenesis in the photoreceptor terminal of the mouse retina. J Comp Neurol 156: 81–93.
View Article
Google Scholar

[107] View Article

[108] Google Scholar

[ref37] 37. Blackshaw S, Harpavat S, Trimarchi J, Cai L, Huang H, et al. (2004) Genomic analysis of mouse retinal development. PLoS Biol 2: E247.
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Google Scholar

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Google Scholar

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View Article
Google Scholar

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[ref40] 40. Wakabayashi T, Kosaka J, Mori T, Takamori Y, Yamada H (2008) Doublecortin expression continues into adulthood in horizontal cells in the rat retina. Neurosci Lett 442: 249–252.
View Article
Google Scholar

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[120] Google Scholar

[ref41] 41. Siegert S, Scherf BG, Del Punta K, Didkovsky N, Heintz N, et al. (2009) Genetic address book for retinal cell types. Nat Neurosci 12: 1197–1204.
View Article
Google Scholar

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[123] Google Scholar

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View Article
Google Scholar

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[126] Google Scholar

[ref43] 43. Hsiau TH, Diaconu C, Myers CA, Lee J, Cepko CL, et al. (2007) The cis-regulatory logic of the mammalian photoreceptor transcriptional network. PLoS One 2: e643.
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[129] Google Scholar

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View Article
Google Scholar

[134] View Article

[135] Google Scholar

[ref46] 46. Katoh K, Omori Y, Onishi A, Sato S, Kondo M, et al. (2010) Blimp1 suppresses Chx10 expression in differentiating retinal photoreceptor precursors to ensure proper photoreceptor development. J Neurosci 30: 6515–6526.
View Article
Google Scholar

[137] View Article

[138] Google Scholar

[ref47] 47. Kremer H, Pinckers A, van den Helm B, Deutman AF, Ropers HH, et al. (1994) Localization of the gene for dominant cystoid macular dystrophy on chromosome 7p. Hum Mol Genet 3: 299–302.
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Google Scholar

[140] View Article

[141] Google Scholar

[ref48] 48. Stone EM, Kimura AE, Folk JC, Bennett SR, Nichols BE, et al. (1992) Genetic linkage of autosomal dominant neovascular inflammatory vitreoretinopathy to chromosome 11q13. Hum Mol Genet 1: 685–689.
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[143] View Article

[144] Google Scholar

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Google Scholar

[146] View Article

[147] Google Scholar

[ref50] 50. Bobola N, Briata P, Ilengo C, Rosatto N, Craft C, et al. (1999) OTX2 homeodomain protein binds a DNA element necessary for interphotoreceptor retinoid binding protein gene expression. Mech Dev 82: 165–169.
View Article
Google Scholar

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[150] Google Scholar

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View Article
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[153] Google Scholar

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View Article
Google Scholar

[155] View Article

[156] Google Scholar

[ref53] 53. Liu Q, Tan G, Levenkova N, Li T, Pugh EN Jr, et al. (2007) The proteome of the mouse photoreceptor sensory cilium complex. Mol Cell Proteomics 6: 1299–1317.
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Figures

Abstract

Introduction

Results

Identification of differentially expressed genes in the Otx2 CKO retina

Otx2 regulates expression of transcription factors involved in retinal development

Identification of retinal disease candidate genes

Discussion

Otx2 regulates the transcriptional network in photoreceptor development

Identification of retinal disease candidate genes from Otx2 downstream genes

Materials and Methods

Animals

Microarray profiling

Q-PCR

Supporting Information

Table S1.

Text S1.

Acknowledgments

Author Contributions

References