Abstract
Cone photoreceptors are the primary initiator of visual transduction in the human retina. Dysfunction or death of rod photoreceptors precedes cone loss in many retinal and macular degenerative diseases, suggesting a rod-dependent trophic support for cone survival. Rod differentiation and homeostasis are dependent on the basic motif leucine zipper transcription factor neural retina leucine zipper (NRL). The loss of Nrl (Nrl−/−) in mice results in a retina with predominantly S-opsin-containing cones that exhibit molecular and functional characteristics of wild-type cones. Here, we report that Nrl−/− retina undergoes a rapid but transient period of degeneration in early adulthood, with cone apoptosis, retinal detachment, alterations in retinal vessel structure, and activation and translocation of retinal microglia. However, cone degeneration stabilizes by 4 months of age, resulting in a thinner but intact outer nuclear layer with residual cones expressing S- and M-opsins and a preserved photopic electroretinogram. At this stage, microglia translocate back to the inner retina and reacquire a quiescent morphology. Gene profiling analysis during the period of transient degeneration reveals misregulation of genes related to stress response and inflammation, implying their involvement in cone death. The Nrl−/− mouse illustrates the long-term viability of cones in the absence of rods and retinal pigment epithelium defects in a rodless retina. We propose that Nrl−/− retina may serve as a model for elucidating mechanisms of cone homeostasis and degeneration that would be relevant to understanding diseases of the cone-dominant human macula.
Introduction
Retinal neurodegeneration is a common feature of many blinding diseases in the developed world. Among inherited retinal diseases (http://www.sph.uth.tmc.edu/retnet/), a majority is associated with the dysfunction or death of photoreceptors (Jackson et al., 2002; Bramall et al., 2010; Swaroop et al., 2010; Wright et al., 2010). The rod photoreceptors allow vision under dim light and are capable of catching a single photon, while cone photoreceptors mediate day light vision, color perception, and visual acuity (Luo et al., 2008; Mustafi et al., 2009). Any impediment in the photoreceptor metabolism or function, caused by genetic defects or microenvironment, can lead to cell death.
While rod photoreceptors die first in retinitis pigmentosa (RP) and age-related macular degeneration (AMD), the death of cones follows (Jackson et al., 2002; Punzo et al., 2009; Wright et al., 2010), suggesting a non-cell-autonomous mechanism of cone survival and/or death. The secondary cone death could result from the absence of a neurotrophic factor or a rod-derived survival factor (Faktorovich et al., 1990; Léveillard et al., 2004) or nutritional imbalance including compromised glucose uptake (Punzo et al., 2009). The study of cone photoreceptors has been difficult because of their relatively low proportion in the retina in mice and humans (Curcio et al., 1990; Mustafi et al., 2009) and/or other significant limitations (including the breeding of study models, antibody availability, and genetics) (Kryger et al., 1998; Hendrickson and Hicks, 2002; Bobu et al., 2006).
The neural retina leucine zipper (Nrl) gene encodes a basic motif leucine zipper transcription factor that is necessary for rod cell fate determination during retinal development (Swaroop et al., 2010). The loss of Nrl (Nrl−/−) in mice leads to a cone-only retina with the complete absence of rods and photoreceptors with S-cone like characteristics but shorter outer segments (OSs) (Mears et al., 2001). The photoreceptors in Nrl−/− mice express cone-specific genes (Yoshida et al., 2004; Akimoto et al., 2006), have morphological and physiological features of cones (Daniele et al., 2005; Nikonov et al., 2005), yet seem to establish synaptic connections with rod bipolar cells (Strettoi et al., 2004). The analyses of Rpe65−/− and Grk1−/− mice on Nrl−/− background have revealed novel insights into cone visual cycle (Zhu et al., 2003; Wenzel et al., 2007; Feathers et al., 2008; Kunchithapautham et al., 2009).
Given the relative importance of cones in human vision and the utility of Nrl−/− mice for delineating cone biology, we undertook a comprehensive evaluation of cone-only Nrl−/− retina. Here, we report our unusual findings of rapid yet transient cone cell death between 1 and 4 months of age, with a subsequent stabilization of the remaining cone number and function. This observation is different from progressive photoreceptor degeneration in rodent models of RP, yet highly significant since macular cones are preserved for longer periods in many RP patients. Our studies also show that cones can survive and function for extended periods even in the absence of rod photoreceptors.
Materials and Methods
Animal and tissue collection.
Nrl−/− mice (Mears et al., 2001) were established on C57BL/6J background. Mice of either sex were used in the study and killed by CO2 inhalation. Mouse eyeballs were fixed in 4% paraformaldehyde for 1 h on ice, incubated in an increasing concentration of PBS/sucrose (10, 20, 30%), and embedded in Tissue-Tek CRYO-OCT compound (Thermo Fisher Scientific) for cryosection. For plastic sections, eyeballs were first fixed in 4% glutaraldehyde for 30 min before overnight fixation in 4% paraformaldehyde. After embedding in methacrylate, 5-μm-thick sections were cut and stained with hematoxylin and eosin. For RNA extraction, the retinas were excised rapidly, frozen on dry ice, and stored at −80°C. Experimental procedures involving animals were performed according to animal protocols approved by the Animal Care and Use Committee at the National Eye Institute. Mice of either sex were used for experimental procedures.
Antibodies and dyes.
The following primary antibodies were used: anti-cone arrestin, anti-Sox9, and anti-GFAP polyclonal antibodies (Millipore Bioscience Research Reagents); anti-Brn3a monoclonal antibody (Santa Cruz Biotechnology); acrolein polyclonal antibody (Abcam); peanut agglutinin conjugated to Alexa Fluor 568 (Invitrogen); anti-Neurofilament-L polyclonal antibody (Millipore); AK-Fluor-fluorescein (Akorn), Iba-1 (1:800; Wako Chemicals), Alexa Fluor 633-conjugated phalloidin (1:100; Invitrogen), RPE65 polyclonal antibody (T. M. Redmond, National Eye Institute, Bethesda, MD); anti-S-opsin and anti-M-opsin polyclonal antibodies (C. M. Craft, University of Pennsylvania, Philadelphia, PA). Secondary antibodies included goat anti-rabbit and anti-mouse antibodies conjugated with Alexa Fluor 488 and 568 (Invitrogen).
Immunohistochemistry and terminal deoxynucleotidyl transferase-mediated biotinylated UTP nick end labeling assay.
Cryosections were probed with specific antibodies, as previously described (Roger et al., 2006), and visualized using an Olympus FluoView FV1000 confocal laser-scanning unit and Olympus BX61WI upright microscope (Olympus America). Apoptosis was detected by terminal deoxynucleotidyl transferase-mediated biotinylated UTP nick end labeling (TUNEL) assays using in situ cell death detection kit per the manufacturer's instructions (Roche).
Fundus examination, angiography, and optical coherence tomography imaging.
Experimental mice were anesthetized, subjected to pupillary dilation with topical 0.5% tropicamide and 1% cyclopentolate hydrochloride, and photographed with a customized fundus imaging system (Paques et al., 2007). Briefly, we connected a 5-cm-long tele-otoscope (1218AA; Karl Storz) and digital camera (D80; Nikon) with an additional +5.00 magnifying lens. A xenon lamp (201315-20; Karl Storz) connected through an optic fiber to the tele-otoscope was used as the light source. Fundus angiography was performed following intraperitoneal injection of fluorescein and imaged with Micron II Rodent Fundus Imaging System (Phoenix Research Labs), equipped with a 390–490 nm excitation filter and a 500 nm long-pass emission filter. Still-frame images and video-rate sequences were acquired with Streampix III image acquisition software (NorPix). Ultra-high-resolution spectral-domain optical coherence tomography (SD-OCT) imaging (Bioptigen) was used to obtain cross-sectional views of the retina in vivo (right eye). Four individual B-scan images were averaged to generate a final image for analysis.
Flat-mount analyses of microglia and retinal pigment epithelium cells.
Nrl−/− mice (from 2 weeks to 11 months) were killed by CO2 asphyxiation and enucleated. The globes were fixed in 4% paraformaldehyde overnight, rinsed in PBS, and then incubated in a buffer containing 1× PBS, 0.5% BSA, 0.2% Tween 20, 0.05% sodium azide, at pH 7.3. Retinal and sclerochoroidal tissues were dissected intact from the globe, flat-mounted, and processed for immunohistochemistry. Sclerochoroidal flat mounts [with the retinal pigment epithelium (RPE) layer uppermost] were used for analysis of microglia and RPE cell morphology and distribution. Retinal flat mounts were used to analyze the organization of photoreceptors and ganglion cells. Separately fixed eyecups from Nrl−/− mice were embedded in 7% agarose and 100-μm-thick retinal sections prepared using a vibratome (Leica VT1000S).
Electroretinography.
Electroretinography (ERG) was performed as previously described (Pang et al., 2005). Only photopic ERGs were recorded since Nrl−/− mice have a cone-only retina (Mears et al., 2001).
Malondialdehyde assay.
Thiobarbituric acid reactive substances (TBAR) assay kit (Cayman Chemical) was used to measure the concentration of malondialdehyde (MDA), a product of lipid peroxidation. For each condition, five retinas were used in two independent experiments for TBAR assays and processed according to the manufacturer's instructions.
RNA isolation.
For microarray analysis, frozen Nrl−/− mouse retinas from four biological replicates at 1, 2, 4, 6, and 10 months of age were lysed with a mortar and pestle in RLT buffer containing DTT (QIAGEN), followed by a QiaShredder column (QIAGEN). RNA was isolated using the RNeasy Mini Kit using an on-column DNase procedure with Rnase-Free DNase (QIAGEN). For whole-transcriptome sequencing, frozen Nrl−/− mouse retinas from 1, 2, and 4 months of age were lysed with a mortar and pestle in Trizol reagent (Invitrogen). RNA quality and quantity were assessed using RNA 6000 Nano Kit (Agilent).
Microarray hybridization.
Ribosomal reduction reactions were performed on total RNA (1 μg) from each sample using the RiboMinus Kit (Invitrogen). rRNA reduced RNA was used for sense target construction using the GeneChip Whole Transcript Sense Target Labeling Assay kit (Affymetrix) per the manufacturer's protocol. Sense targets were hybridized to GeneChip Mouse Exon 1.0 ST arrays (Affymetrix), processed per manufacturer's instructions, and scanned on a GC Scanner 3000 7G running AGCC (Affymetrix) for .CEL file generation.
Microarray data analysis.
The values of individual probes belonging to one probe set (four probes/set in 90% of the cases) were averaged and normalized using Partek Genomics Suite 6.5 (Partek). The average fluorescence intensity was calculated for annotated genes using the RMA (robust multichip average) algorithm. The updated mapping files were downloaded from the web site of Affymetrix and core meta-probe set list having strong annotation support (e.g., from RefSeq and other GenBank alignments of “complete CDS” transcripts) was used for further analysis. One-way ANOVA was performed to identify differentially expressed genes. To correct for false positives, we used the Benjamini–Hochberg false discovery rate (FDR) procedure with a minimum value of p ≤ 0.05. Only genes showing a greater than twofold change with respect to 1 month expression data were considered for further analysis.
Whole-transcriptome sequencing (RNAseq).
Transcriptome libraries were constructed using 1 μg of total RNA with the mRNA-seq sample preparation kit (Illumina), according to the manufacturer's protocols with only minor modifications. Briefly, ligated library DNA were electrophoresed on a 2% agarose gel and stained with SYBR Gold. The 200 bp band was isolated using a 1 mm GeneCatcher (Gel Company), and DNA recovered using QIAquick Gel Extraction kit (QIAGEN). The library DNA was quantitated using DNA-1000 kit (Agilent). Single-read cluster generation of 10 pm libraries was performed using the Single-Read Cluster Generation kit, version 4 (Illumina). Sequence-by-synthesis of 76 base length was performed on a Genetic Analyzer IIx running SCS2.6 (Illumina).
RNAseq data analysis.
Raw sequence reads were mapped onto the University of California, Santa Cruz, mm9 mouse genome using the public domain Efficient Large-Scale Alignment of Nucleotide Database (ELAND). These data were analyzed with Partek software (Partek) and normalized using the method that calculated reads per 1 kb of exon model per million mapped reads (RPKM) (Marioni et al., 2008). RefSeq transcripts database (http://www.ncbi.nlm.nih.gov/RefSeq/) was used to map the sequence reads to the mouse genome. One-way ANOVA analysis was performed to identify differentially expressed genes.
Results
Transient cone photoreceptor cell death in Nrl−/− mouse retina
Fundus examination of the Nrl−/− mice revealed abnormalities with age (Fig. 1A). White spots were observed in 1-month-old Nrl−/− but not in age-matched wild-type (WT) C57BL/6 mouse retina; these white lesions correspond in size and location to whorls and rosettes reported in the outer nuclear layer (ONL) of Nrl−/− retina (Mears et al., 2001; Daniele et al., 2005; Oh et al., 2007). In addition, an accumulation of pigmentary abnormalities and increased attenuation of the retinal vessels were observed in 2-month-old Nrl−/− mice. At 6 months, papillary atrophy was evident, suggesting optic nerve or retinal ganglion cell loss (Fig. 1A).
As previously described (Mears et al., 2001; Daniele et al., 2005), photopic ERG recordings (corresponding to cone function) in Nrl−/− mice at 1 and 2 months of age showed supranormal amplitudes for both a- and b-wave (Fig. 1B,C). However, repeated recordings at different ages between 1 and 4 months demonstrated a drastic reduction in the mean a-wave amplitude, from 50.6 ± 1.1 μV at 1 month to 16 ± 2.4 μV at 4 months of age (Fig. 1C). The b-wave amplitudes at maximum light stimulation were relatively stable between 1 and 2 months (189 ± 11 and 179 ± 19 μV, respectively) (Fig. 1B,C), but decreased significantly (to 109 ± 9 μV) by 4 months. Histological analysis in methacrylate sections of the Nrl−/− retina demonstrated massive photoreceptor cell loss retina between 2 and 4 months of age (Fig. 1D). During this period, the ONL decreased in thickness from 8 to 10 rows of nuclei to approximately 4 rows. Interestingly, ONL thickness remained relatively stable (two to four rows) at 6 months and later. However, at 10 months, the ganglion cell layer (GCL) showed progressive thinning compared with younger Nrl−/− mice (Fig. 1D), suggesting a cause for optic atrophy observed by fundoscopy at this age (Fig. 1A). Even in 18-month-old mice, the thickness of the ONL was unchanged (two to four rows of nuclei) (data not shown), indicating that the complete absence of rod photoreceptors in Nrl−/− mouse retina did not lead to further loss of cones.
Transmission electron microscopy images of Nrl−/− mouse retina in the dorsal-ventral midline plane and in the dorso-central retina demonstrated the presence of short OSs at 1 month of age (Fig. 1E). While regular stacks of OS discs were present, they did not elongate as in WT mice, and some areas of abnormal membrane vesicle formation were observed (Fig. 1E, asterisks). By 4 months, OSs have progressive shortened such that the distinction between OS and inner segment (IS) could no longer be discerned. In addition, abnormal accumulation of IS material appeared in the ONL at 10 months. Membrane stacks corresponding to RPE apical microvilli (as identified by their position, spacing, and length) were also observed (Fig. 1E).
Optical coherence tomography (OCT) imaging in 1-month-old live animals showed broad areas of shallow retinal detachment from the RPE, distinct from the pseudorosettes located in the ONL (Fig. 1F). These detachments were detected both in the center and the periphery of the retina without a preferential locus of occurrence. However, all areas of retinal detachment had resolved at 4 months of age. By OCT Doppler imaging, large retinal blood vessels of 2- and 10-month-old Nrl−/− mice had increased cross-sectional areas (Fig. 1F) compared with WT mice.
Preservation of S-cones and M-cones following the period of retinal cell death in the Nrl−/− retina
Immunolabeling with peanut agglutinin (PNA), a marker of cone extracellular matrix, in 1-month-old Nrl−/− mice showed prominent colocalization with whorls and rosettes that were previously noted in Nrl−/− and rd7 mice (Fig. 2A) (Akhmedov et al., 2000; Mears et al., 2001). The PNA-stained rosette structures in the retina decreased drastically in number from 968 ± 41 per retina at 1 month to 141 ± 16 per retina at 4 months, and were completely absent at 10 months. However, PNA-positive staining continued to be present in the distal cone segments at all ages, indicating a persistence of the cone extracellular matrix in that location (Fig. 2A,B). S-opsin, M-opsin, and cone arrestin were also uniformly expressed at all ages (Fig. 2C). Interestingly, M-opsin was relocalized in the IS in old mice in contrast with its presence in the ONL observed in younger animals. The counting of TUNEL-positive cells confirmed that most cones underwent apoptosis between 2 and 4 months (Fig. 2D). We did not observe significant differences in the repartition of the TUNEL-positive cells between areas of retinal detachments and rosettes. However, the cell death in the rosettes could be due to the lack of contact of cone outer segments with RPE, as suggested in a previous study (Daniele et al., 2005). Surprisingly, a significant number of apoptotic cells were also detected in the inner nuclear layer (INL) and GCL. Thus, a majority of cell death in Nrl−/− retina is transitory during the first 4 months of life and occurs in all retinal layers.
Alterations in ganglion and Müller cells in Nrl−/− retina
As cell death was detected in all neuronal layers, we examined the markers for different retinal cell types in Nrl−/− mice. We observed the expression of Brn3a and NF-L, two ganglion cell markers, in the INL of 1- and 2-month-old Nrl−/− retina (Fig. 3A), suggesting the abnormal location of displaced retinal ganglion cells. Interestingly, a fraction of the Sox9-positive Müller cell nuclei were also displaced to the ONL at 4 months (Fig. 3B). Notably, Müller cells showed an evidence of gliosis (as revealed by GFAP immunostaining) as early as 1 month (Fig. 3C) when cell death is initiated.
Since microglial cell activation is reported in many neurodegenerative diseases and models of retinal degeneration (Hanisch and Kettenmann, 2007; Langmann, 2007), we assessed changes in microglial morphology and distribution in Nrl−/− mice during the period of transitory cell death and with age (Fig. 4). At 2 weeks of age, retinal microglia (as indicated by labeling with Iba1 immunostaining) demonstrated ramified morphologies and a typical distribution [i.e., in the GCL, inner plexiform layer (IPL), and outer plexiform layer (OPL), and were excluded from the outer retina and subretinal space] in Nrl−/− retina, similar to those in WT mice. By 3 weeks, a few microglial cells in the ventral retina could be seen migrating into the subretinal space coming into contact with RPE, and assuming more rounded and less ramified morphologies, consistent with an activated status (Fig. 4C). The influx of microglia into the outer retina and subretinal space increased with age, peaking at 2 months (Fig. 4K,M), exhibiting close association with cone photoreceptor OS including those located in pseudorosettes (Fig. 4M). Beginning at 4 months of age, a progressive decrease was detected in the number of microglia in the subretinal space (Fig. 4K), with a resumption of microglia distribution to OPL, IPL, and GCL (Fig. 4N). Microglia appeared to be recruited to the areas of cone degeneration early in the process, before extensive cone loss, and returned to a typical inner retinal distribution after the transitory phase of retinal cell death.
Absence of rod photoreceptor affects RPE integrity, retinal vasculature, and ganglion cell survival
As interaction of the RPE with photoreceptors is essential for visual function, we investigated the contact of these two layers on 100-μm-thick vibratome sections (Fig. 5A) and RPE integrity in sclerochoroidal flat mounts (Fig. 5B). In the RPE layer of WT mice, RPE65, a key enzyme of the visual cycle, could be immunolocalized to the cytoplasm of all RPE cells, while ezrin was detected in the apical RPE cell surface. In Nrl−/− retina, despite continuous PNA localization in the cones, expression of RPE65 and ezrin was absent in some regions of the RPE monolayer, suggesting a patchy loss of RPE cell function. As early as 1 month of age, we could identify abnormalities in the RPE mosaic (revealed by phalloidin immunolabeling) of Nrl−/− retina. Some cells did not express RPE65, and others showed internal staining with phalloidin in the focal plane, which likely corresponded to the microvilli. By 10 months of age, the RPE integrity appeared to be disrupted, as shown by the presence of some pyknotic nuclei and loss of junctions between RPE cells (Fig. 5B). Our data are consistent with a recent report demonstrating defective phagocytosis in RPE from Nrl−/− retina (Mustafi et al., 2011).
We also evaluated the structure and permeability of the retinal vasculature using fluorescein angiography. Two-month-old Nrl−/− mice demonstrated dilated retinal vessels and also a denser network of retinal capillaries (Fig. 6B), supporting the observations made by OCT imaging (Fig. 1F). Some abnormal retinal capillary permeability was also found, as evidenced by mild leakage of fluorescein in the retinal periphery (Fig. 6C). A 3D reconstruction from flat mount retina of 2-month-old Nrl−/− mice after dextran-fluorescein injection demonstrated that the leakage observed by angiography came in part from blood vessels present on the internal retinal ganglion cell layer side (Fig. 6D). This observation was confirmed in 5-month-old Nrl−/− retina (data not shown). With increasing age, the retinal vessels showed a converse luminal narrowing and an increasing extent of fluorescein leakage (Fig. 6E,F).
As GFAP-expressing astrocytes in the GCL have a close relationship with the retinal vasculature (Gariano et al., 1996; West et al., 2005), we evaluated the effects of retinal degeneration on vasculature integrity using flat-mount retina (Fig. 7). We observed a profound change in both large arteries and capillaries in 18-month-old Nrl−/− retina that in part explained the massive blood leakage detected by angiography (Fig. 7).
In parallel, we immunolabeled ganglion cells on flat-mount retina with anti-Brn3a, a transcription factor specifically expressed in ganglion cells. Consistently, the expression level of Brn3a was lower in Nrl−/− retina compared with WT (Fig. 7). Thus, if ganglion cells were still present in the central retina of 18-month-old Nrl−/− mice, they would have low Brn3a expression levels. In contrast, only few ganglion cells were detected at the periphery of the retina, confirming the death of ganglion cells as indicated (Figs. 1A,D, 3A). Interestingly, we also observed an increase in small capillaries, as revealed by the secondary anti-mouse IgG that binds to the endogenous IgG in the blood contained in mouse retinal capillaries.
Our findings reveal that transitory cone cell death in Nrl−/− mice appears to cause profound changes in the retina, including RPE cell death, changes in the retinal vasculature, ganglion cell death, and fluid leakage from the superficial blood vessels on the inner retinal ganglion cell side. However, loss of RPE might also disrupt the retinal blood barrier, resulting in fluid leakage from the choroid side.
Oxidative stress associated with retinal cell degeneration in Nrl−/− mice
The oxygen stress in Nrl−/− mouse retina is predicted to be higher than in WT as illustrated by the fact that the overall photoreceptor circulating current in the Nrl−/− cones at 1 month (when cones are still healthy) is roughly one-third that of WT (as reflected by the saturated a-wave amplitude), and therefore the outer retina of the Nrl−/− mice will require only approximately one-third as much oxygen supplied by the choroid, leading to elevated oxygen tension (Daniele et al., 2005). We therefore investigated the oxidative stress in Nrl−/− retina by assessing the presence of acrolein, a toxic product formed by lipid peroxidation (Fig. 8A). While staining for acrolein was absent in 1-month-old retina, prominent staining was observed at 2 months, particularly in the GCL and around the whorls and rosettes of the ONL, before decreasing in overall intensity at 10 months. We also measured the concentration of MDA, a marker of oxidative stress, in Nrl−/− and WT retinas at different ages. In Nrl−/− retinas, levels of MDA were low and similar to those found in WT retinas at 1 month, but increased to a peak at 4 months (2.5-fold increase) before decreasing at 10 months (Fig. 8B). However, we noticed that the peak of MDA is delayed with significant cone cell loss occurring between 2 and 4 months of age. The concordance between increased acrolein staining and MDA levels at this age implicates a role of oxidative stress in the cone cell death.
Changes in gene expression profile during cone cell death in Nrl−/− retina
To gain insights into cellular pathways underlying transitory cone death in Nrl−/− retina, we performed microarray analysis of four biological replicates at five different time points (1, 2, 4, 6, and 10 months). We compared 2, 4, 6, and 10 month microarray data to 1 month, when all cones are still present, and selected a minimum twofold change (FC) cutoff for further analysis. The data revealed statistically significant differences (p ≤ 0.05) for 350 mapped genes in at least one of the four comparisons (data not shown). As most cone death occurs between 1 and 4 months of age in Nrl−/− retina, we grouped together genes with FC ≥ 2 at 2 or 4 months and those differentially expressed at 6 or 10 months with respect to 1 month. At 6 or 10 months, 337 genes were significantly differentially expressed compared with 1 month and 88 at 2 or 4 months compared with 1 month. The fact that the vast majority of genes are differentially expressed at 6 or 10 months might reflect the remodeling of the retina after a period of transitory cone cell death. We then focused on 88 genes that are potentially involved in cone cell death and exhibit FC > 2. Statistically significant downregulation was detected for 53 genes with an average fold change (AFC) of −2.4 and −2.6 at 2 and 4 months, respectively (Fig. 9A). Thirty-five genes with statistically significant upregulation demonstrated AFC of 2.2 and 2.5 at 2 and 4 months, respectively (Fig. 9B).
Meta-analysis of biological functions of 88 differentially expressed genes at 2 and 4 months compared with 1 month identified three major categories—immune response, signal transduction, and stress response (Fig. 9C). Among these, crystallins correspond to a large family of chaperones involved in response to stress and inflammation, and their expression is increased in several retinal diseases (Fort and Lampi, 2011) including AMD (Umeda et al., 2005), uveitis (Rao et al., 2008), and diabetic retinopathy (Kumar et al., 2005; Fort et al., 2009). Interestingly, Cryαa, Cryβa1, Cryβb1, Cryγc, and Cryγd were highly expressed at 1, 2, and 4 months of age in Nrl−/− retina (Table 1). We confirmed their downregulation with age by qPCR (Fig. 9D), corresponding to the transitory cell death. However, crystallin expression is almost undetectable thereafter (6 and 10 months). Cryαa, Cryβa1, and Cryγd are among the most highly expressed crystallins between 1 and 4 months, indicating their potential role in cone homeostasis and response to stress.
Only 13 genes were differentially expressed between 1 and 4 months, with no statistically significant expression change between 6 and 10 months compared with 1 month: Cxcl13, Ifit1, Serpina3n, Asf1b, Ctss, Samd7, Ifitm3, Serping1, Cfi, Hnrpdl, Col6a1, Abhdl4a, and Pcbp4. Ingenuity pathways analysis (IPA) revealed that 12 of 13 genes act as hubs with a majority associated with immune response: Cfi, Ctss, Cxcl13, Ifit1, Iftm3, Serpina3n, and Serping1 (Fig. 9E).
We then performed whole-transcriptome analysis by NextGen Sequencing (RNAseq) of 1, 2, and 4 month Nrl−/− retina and identified 39 genes (Table 1) that were also present in 88 differentially expressed genes revealed by microarray analysis. Network reconstruction with these 39 genes (Fig. 9F) identified Tnf (tumor necrosis factor) as a central hub for 12 differentially expressed genes, confirming the importance of immune response in cone death observed in Nrl−/− retina. The presence of Serping1 upregulation is notable as its expression is associated with AMD (Mullins et al., 2009; Lu et al., 2010).
Discussion
The studies of cone function are critical for elucidating normal visual process and defining pathogenic mechanisms of retinal diseases. Photoreceptors in Nrl−/− retina share many features with “normal” cones (Daniele et al., 2005), including chromatin clumping, cone matrix sheath, gene expression, mitochondrial length, open discs, and ERG pattern. Here, we report novel aspects of cone biology by comprehensive examination of Nrl−/− retina, which at 1–4 months of age shares fundamental features (e.g., photoreceptor degeneration, RPE changes, Müller cell hypertrophy) with rodent models of retinal degeneration and human RP (Milam et al., 1998). The rapid cone cell death in Nrl−/− retina is similar to what is observed in Pde6b−/− and Pde6 g−/− mouse retina between 1 and 4 months of age (Punzo et al., 2009). However, unlike rodent and human RP, cone photoreceptor death stabilizes in the Nrl−/− retina, with a population of cones for the remainder of life. Notably, macular cones, although not functional, are preserved in many RP and Leber congenital amaurosis patients (John et al., 2000; Cideciyan et al., 2007; Jacobson et al., 2010).
An important question is why the cones in the Nrl−/− retina do not undergo a constant rate of degeneration like their counterparts in the macula of an RP patient? Large areas of retinal detachment, loss of ganglion cells, and altered vasculature in Nrl−/− retina at a young age indicate neuronal degeneration and remodeling (Milam et al., 1998; Marc et al., 2003). Unlike Nrl−/− retina, inner retinal neurons are more preserved and send processes into aberrant regions in human RP retina (Stone et al., 1992; Santos et al., 1997; Humayun et al., 1999). The remodeling of synaptic connections between photoreceptors and bipolar cells is also observed in animals carrying rhodopsin or Pdeb mutation (Peng et al., 2000) or after retinal detachment (Lewis et al., 1998). In Nrl−/− retina, the rod bipolar cells connect to cone terminals in the absence of rods (Strettoi et al., 2004), whereas cone bipolars are connected to rods in the absence of cones in Crxp-Nrl mouse (Oh et al., 2007). The axon and dendritic terminals of horizontal cells are also affected in absence of rod or cone photoreceptors (Raven et al., 2007).
Ablation of cones by cone-DTA transgene in rd7/rd7 mouse retina, caused by the loss of Nr2e3 [a transcriptional target of NRL (Oh et al., 2008)] function, reduces Müller cell activation, indicating a contribution of excess cones to pseudorosette formation (Chen and Nathans, 2007). The cone death between 1 and 4 months in Nrl−/− retina results in complete loss of pseudorosettes without preventing Müller cell activation. We suggest that loss of rosettes in older Nrl−/− retina allows appropriate positioning of surviving cones with RPE, which can explain the arrest of cone cell death. Notably, prompt surgical reattachment after retinal detachment in humans prevents visual acuity loss and allows vision restoration (Fisher and Lewis, 2003). In monkeys that had detachment/reattachment surgery, the cones degenerate while detached but their OS length partially recovers when reattached (Guérin et al., 1989). Retinal detachment in Nrl−/− retina does not significantly alter S- or L/M-opsin expression, as in a cat model of retinal detachment (Rex et al., 2002). Additionally, formation of glial scar and retinal remodeling (Jones and Marc, 2005; Lewis et al., 2010) are undetectable in Nrl−/− retina. Experimental retinal detachment (Lewis et al., 2010) leads to proliferation of Müller cells and migration of their cell bodies to ONL. Thus, retinal detachment early in Nrl−/− retina can partly explain the presence of Müller cell bodies in the ONL and may reflect a consequence of dedifferentiation (Fischer and Reh, 2003; Bernardos et al., 2007; Karl et al., 2008). A few BrdU-positive cells were visible in the ONL of 12-month-old but not 2-month-old Nrl−/− retina (data not shown). Further investigations are required to delineate the identity of these cells.
RPE plays a critical role in the maintenance of photoreceptor integrity (Strauss, 2005; Sparrow et al., 2010). The use of Rpe65−/−;Nrl−/− mice has demonstrated the importance of RPE65 in both rods and cones (Wenzel et al., 2007; Feathers et al., 2008; Kunchithapautham et al., 2009). Surprisingly, we observed early RPE defects, including the loss of RPE65 expression in patches, RPE atrophy, and loss of tight junctions between 1 and 4 months in Nrl−/− retina. We did not observe RPE65 in the whirls and rosettes as reported in one (Feathers et al., 2008) but not the other study (Wenzel et al., 2007). Thus, an absence of rod photoreceptors or secretion of a toxic product by excess cones appears to compromise the integrity of RPE. However, the remaining RPE65-positive RPE cells can renew the pool of 11-cis-retinal and maintain some light sensitivity at high-intensity stimulation. These observations can also be explained by the existence of a distinct visual pigment recycling pathway revealed in cone-rich retina of chicken and ground squirrels (Mata et al., 2002; Trevino et al., 2005). Indeed, Müller cells may contribute to maintenance of cone function in Nrl−/− retina and compensate for RPE defect. We also noticed that the absence of RPE did not lead to lack of PNA staining, suggesting that cones secrete their own extracellular matrix (Mieziewska et al., 1993). The early RPE defect in Nrl−/− retina might also indicate the existence of a rod-derived RPE survival factor.
In mouse models with no or short rod OSs, such as Crx−/− (Furukawa et al., 1999) or Rho−/− mice (Humphries et al., 1997), rod photoreceptors die within weeks. In fact, all rods are lost in most mouse retinal degeneration mutants, independent of cell death kinetics (Punzo et al., 2009; Bramall et al., 2010). In Nrl−/− mice, however, although distinct cone OS are not detected by 4 months, many cones survive for an extended period of time. We suggest that cone death in Nrl−/− mice is not intrinsic to photoreceptors but reflects an adaptive homeostatic mechanism. Rapid cell death allows the cone-only Nrl−/− retina to accommodate the steep requirement of oxygen (Perkins et al., 2003; Daniele et al., 2005; Shen et al., 2005) by surviving cones.
Prolonged survival of many cones (two to four layers of nuclei even at 18 months) in Nrl−/− retina, in the absence of rods since birth, demonstrates that rod photoreceptors are not essential for cone survival and may not be the sole source of trophic factors. For instance, Rdcvf, first identified as a rod-derived cone viability factor able to preserve cone function (Léveillard et al., 2004; Yang et al., 2009), is also expressed in the INL (Lambard et al., 2010; Reichman et al., 2010). In Nrl−/− retina, Rdcvf1 expression does not change with age although Rdcvf2 shows decreased expression between 1 and 10 months (data not shown). Even if the numbers of nuclei are preserved at older ages, we observed a slight second decline after 8 months in the ERG b-wave that may be attributed to cone aging, consistent with a small age-associated decline in rod and cone function in 12-month-old C57BL/6 mouse retina (Gresh et al., 2003; Parapuram et al., 2010).
The higher concentration of acrolein and MDA in 4-month-old Nrl−/− retina corroborates the hypothesis that the average circulating current and oxygen demand in Nrl−/− retina should be less compared with WT due to the difference in a-wave amplitude generated by rod and cone photoreceptors (Daniele et al., 2005). Thus, oxygen stress in Nrl−/− mice should be higher, and hyperoxia may be toxic for photoreceptors. Interestingly, we observed attenuated retinal vasculature in older Nrl−/− retina, leading to a decrease in oxygen supply that could be beneficial for cones. This provides further support for the hypothesis that Nrl−/− retina are able to adapt and maintain a certain number of cones for prolonged period. The use of antioxidants in Nrl−/− mice might also reduce photoreceptor cell death, as described in several models of retinitis pigmentosa (Cao and Phillis, 1995; Kowluru and Odenbach, 2004; Komeima et al., 2006).
Retinal detachment, oxidative stress due to retinal hyperoxia (Stone et al., 1999), and activation of microglia cells (Gupta et al., 2003; Glybina et al., 2009) have been associated with RP and are observed in Nrl−/− retina. We suggest that these changes indicate a central role for rods in retinal homeostasis and not a direct impact on cone survival. As rods constitute almost 70% of cells in mouse and human retina, the loss of rods is expected to have a major influence on retinal architecture. Loss of rods compromises the fragile homeostasis in the retina of Nrl−/− mice, leading to RPE atrophy, Müller cell activation, altered retinal vasculature, and loss or dysfunction of other neuronal cell types. While additional investigations are necessary to delineate the underlying molecular pathways of cone survival, we suggest that functionally relevant contacts with RPE and trophic factors from Müller glia and microglia cells contribute in prolonged survival of cone photoreceptors even in the absence of rods. As Nrl−/− mouse exhibits many features of retinal remodeling in other retinal degenerations, our studies may provide new insights into pathogenic mechanisms of retinal neurodegenerative diseases and allow evaluation of alternative therapies.
Footnotes
This work was supported by the intramural program of the National Eye Institute. We thank Harsha Rajasimha for help with RNAseq data and Chun Y. Gao for technical assistance.
- Correspondence should be addressed to Anand Swaroop, Neurobiology-Neurodegeneration and Repair Laboratory, National Eye Institute, National Institutes of Health, 6 Center Drive, Bethesda, MD 20892. swaroopa{at}nei.nih.gov