Abstract
Rhodopsin is a G protein-coupled receptor essential for vision and rod photoreceptor viability. Disease-associated rhodopsin mutations, such as P23H rhodopsin, cause rhodopsin protein misfolding and trigger endoplasmic reticulum (ER) stress, activating the unfolded protein response (UPR). The pathophysiologic effects of ER stress and UPR activation on photoreceptors are unclear. Here, by examining P23H rhodopsin knock-in mice, we found that the UPR inositol-requiring enzyme 1 (IRE1) signaling pathway is strongly activated in misfolded rhodopsin-expressing photoreceptors. IRE1 significantly upregulated ER-associated protein degradation (ERAD), triggering pronounced P23H rhodopsin degradation. Rhodopsin protein loss occurred as soon as photoreceptors developed, preceding photoreceptor cell death. By contrast, IRE1 activation did not affect JNK signaling or rhodopsin mRNA levels. Interestingly, pro-apoptotic signaling from the PERK UPR pathway was also not induced. Our findings reveal that an early and significant pathophysiologic effect of ER stress in photoreceptors is the highly efficient elimination of misfolded rhodopsin protein. We propose that early disruption of rhodopsin protein homeostasis in photoreceptors could contribute to retinal degeneration.
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Introduction
The endoplasmic reticulum (ER) is essential for secretory and membrane protein folding and assembly. Impairment of ER protein folding creates ER stress, activating the unfolded protein response (UPR) intracellular signal transduction network [1]. The UPR regulates transcriptional, translational, and post-translational intracellular programs such as ER-associated protein degradation (ERAD) whereby ER chaperones, protein folding enzymes, and lectins identify malformed proteins in the ER and retrotranslocate them into the cytosol for degradation by proteasomes [2]. The ERAD program therefore prevents misfolded protein accumulation, and disruption of ERAD components often leads to early embryonic lethality [3–7].
Inositol-requiring enzyme 1 (IRE1) is a key UPR regulator [1]. IRE1 encodes an ER-resident transmembrane protein with an ER-luminal domain coupled to cytosolic kinase and endoribonuclease (RNase) domains [8–10]. In response to ER stress, IRE1’s RNase removes an inhibitory intron from Xbp-1 mRNA [11, 12] to generate the potent XBP1s transcription factor whose transcriptional targets include numerous ERAD genes [13, 14]. By this mechanism, IRE1 signaling regulates the ERAD program. In addition to ERAD, IRE1 signaling can also activate the c-Jun kinase signaling module and non-specifically degrade mRNAs through regulated IRE1-dependent decay (RIDD) in response to strong ER stress [1]. PKR-like ER kinase (PERK) mediates a separate UPR signaling pathway [1]. In response to ER stress, PERK inhibits the ternary translation initiation complex formation on mRNAs [15] and therefore attenuates protein synthesis in the cell. PERK signal transduction also regulates a cell death program through its upregulation of pro-apoptotic transcriptional activators: ATF4 and CHOP [16, 17].
Rod opsin mutations are common causes of heritable retinitis pigmentosa, a blinding disease arising from photoreceptor cell death [18]. Rod opsin is a G protein-coupled receptor that forms the visual photopigment, rhodopsin, when coupled with 11-cis-retinal [19]. Rhodopsin is essential for photoreceptor function and survival, and rod opsin knockout mice (Rho −/−) develop early retinal degeneration [20, 21]. In cell culture, many rod opsin mutants misfold and aggregate to trigger ER stress and activate the UPR [22–26]. But, the effects and role of UPR activation in photoreceptor cell death remain obscure.
Here, we analyzed UPR signaling in our recently developed P23H rod opsin knock-in mouse model of retinitis pigmentosa [27] that recapitulated patients’ gene dosage and spatiotemporal retinal degeneration [27]. By contrast, transgenic models of retinal degeneration produced retinal degeneration regardless of whether misfolded or wild-type rhodopsin was expressed [28]. Here, we found an unexpected bias in UPR signaling in photoreceptors, with strong IRE1 but little PERK signaling. The pathophysiologic consequence of IRE1 activation was robust ERAD elimination of almost all P23H rhodopsin from photoreceptors early after their formation to create a Rho −/−-like retinal degenerative phenotype.
Materials and Methods
Animals
Homozygous breeding pairs of P23H rod opsin knock-in mice [27] were maintained to produce Rho P23H/P23H homozygotes or crossed with wild-type C57BL/6J (Rho +/+) mice to produce Rho P23H/+ heterozygotes. C57BL/6J mice were used as wild-type controls (Rho +/+). ERAI +/− mice were provided by Takao Iwawaki (RIKEN, Saitama, Japan) and Peter Walter (UCSF). Chop −/− mice were obtained from Jackson Laboratory. Mice were maintained in a barrier animal facility in a 12:12 light cycle at in-cage irradiance of less than 125 lx and provided standard mouse chow (UCSF and UCSD) or in a 12-h light (127–255 lx)/12-h dark (<10 lx) cyclic environment (Case Western Reserve University). Retinal tissues were collected from animals of either sex at indicated ages. Mice were checked daily by the UCSF Animal Care staff. In addition, laboratory personnel checked births in the morning and evening during the light phase of the light cycle to determine exact birthdates because early eye developmental and degenerative events occurred rapidly once they commenced. To define phenotypes of each of the three genotypes from P4 to P15, we examined two litters of mice of either sex with exact birthdates from each line, examining one animal of either sex from each litter on successive dates, beginning on P4 (Table S1). All animal studies followed the guidelines of the institutional animal care committees at UCSF, UCSD, or Case Western Reserve University, and were conducted in accordance with the recommendations of the American Veterinary Medical Association Panel on Euthanasia and the Association of Research for Vision and Ophthalmology.
Tissue Harvesting and Eye Histology
Immediately after euthanizing mice, an enucleated eye of each mouse was immersed in a fixative of mixed aldehydes for histology [29], The other eye also was removed, and the retina was dissected by the Winkling procedure [30] and rapidly frozen in dry ice for biochemical and molecular analyses. For histological analysis, eyes were bisected, post-fixed with osmium tetroxide, and embedded in an epoxy resin as previously described [29]. One-micrometer-thick sections were cut through the optic nerve head along the vertical meridian and stained with toluidine blue. Beginning at P8, the outer nuclear layer (ONL) thickness, a surrogate for photoreceptor number [31], was quantified by measuring three positions in nine 250-μm adjacent microscopic fields on each side of the optic nerve head that produced 54 measurements of each retina [32]. Means of these measurements allowed quantitative comparisons of multiple animals at different ages and of different genotypes in the two hemispheres of the eye, and the resulting values could then be plotted in a “retinal spidergram” to illustrate hemispheric differences across the retina [33]. All quantitative measurements were from a single retina from five to seven different mice of each experimental cohort.
The young retinas, particularly at P4–P8, changed so rapidly in formation of the ONL from the outer neuroblastic layer in a strong central-to-peripheral gradient (which all features follow in the developing eye) that they were compared based on the following four phenotypic features: (1) length of rod inner + outer segments (if present) measured with an eyepiece micrometer in several regions in the central retina; (2) development of the outer plexiform layer (OPL) based on the percentage of the length in which it was present in each hemisphere (measured from the posterior pole); (3) incidence of ectopic photoreceptor nuclei still in the inner nuclear layer [34] measured as a percentage of the length in each hemisphere in which they still comprised a continuous row (measured from the ora serrata); and (4) incidence of pyknotic nuclei in the ONL, as seen in most rodent retinal degenerations [35, 36], per 430-μm microscopic field.
Immunofluorescence and Confocal Microscopy
Eyes were enucleated and fixed by immersion in 4 % paraformaldehyde in PBS buffer for 1 h at room temperature. After overnight incubation with 30 % sucrose at 4 °C, eyes were frozen in O.C.T. (Tissue-Tek). Eight-micrometer-thick sections were cut through the optic nerve head and stained with indicated antibodies. Primary antibodies used included 1D4 anti-rhodopsin 1:500 dilution (Santa Cruz Biotechnologies, CA), anti-calnexin 1:250 (GeneTex, Irvine, CA), and anti-GFP 1:250 (Invitrogen, Carlsbad, CA). Secondary antibodies included Alexa 546 goat anti-mouse (Molecular Probes, Invitrogen) and Alexa 488 goat anti-rabbit (Molecular Probes, Invitrogen) used at 1:500. Images were collected with an Olympus FluoView-1000 confocal microscope and processed with Olympus FluoView Ver.2.0a Viewer software.
Transmission Electron Microscopy
Four mice from each genotype (Rho +/+, Rho P23H/+, and Rho P23H/P23H) were analyzed by transmission electron microscopy at P14. Fixation, sectioning, and staining were performed according to Sakami et al. 2013 [44] . Low magnification (×2,000) TEM images of photoreceptor cell inner segments were captured by a JEOL 1200 EX EM at 80 kV (JEOL, Musashino, Tokyo, Japan). Eight images from each genotype (two images from each mouse) were analyzed.
Molecular Biology
Retinas were lysed and total RNA was collected with a RNeasy mini kit (Qiagen, Germany). mRNA was reverse-transcribed with the iScript cDNA Synthesis Kit (Bio-Rad, Hercules, CA). For quantitative PCR analyses, primers included the following: mouse rhodopsin mRNA, 5′-TTCACCACCACCCTCTACACATCAC-3′ and 5′- CGGAAGTTGCTCATCGGCTTG-3′; mouse GNAT1 mRNA, 5′-GAGGATGCTGAGAAGGATGC-3′ and 5′-TGAATGTTGAGCGTGGTCAT-3′; mouse Xbp-1s mRNA, 5′-GAGTCCGCAGCAGGTG-3′ and 5′-GTGTCAGAGTCCATGGGA-3′; mouse Derl1 mRNA, 5′-CGCGATTTAAGGCCTGTTAC-3′ and 5′-GGTAGCCAGCGGTACAAAAA-3′; mouse VCP mRNA, 5′-AAGTCCCCAGTTGCCAAGGATG-3′ and 5′- AGCCGATGGATTTGTCTGCCTC-3′; mouse ERdj4, 5′-TAAAAGCCCTGATGCTGAAGC -3′ and 5′- TCCGACTATTGGCATCCGA -3′; mouse Grp78/BiP: 5′-CCTGCGTCGGTGTGTTCAAG-3′ and 5′-AAGGGTCATTCCAAGTGCG-3′; mouse Rpl19: 5′-ATGCCAACTCCCGTCAGCAG- 3′ and 5′-TCATCCTTCTCATCCAGGTCACC-3′; and mouse Chop: 5′-ACGGAAACAGAGTGGTCAGTGC-3′ and 5′-CAGGAGGTGATGCCCACTGTTC-3′. For rhodopsin mRNA levels, GNAT1 mRNA levels, a transcript only expressed in rod cells, served as the normalization control. For all other quantitative real-time PCR (qPCR) analysis, Rpl19 mRNA levels, a transcript with levels unaltered by ER stress, served as internal normalization standards. qPCR conditions were 95 °C for 5 min, 95 °C for 10 s, 60 °C for 10 s, 72 °C for 10 s, with 50 cycles of amplification.
Cell Culture
Cells were maintained at 37 °C, 5 % CO2 in Dulbecco’s modified Eagle medium (Mediatech, Manassas, VA) supplemented with 10 % fetal calf serum (Invitrogen) and 1 % penicillin/streptomycin (Invitrogen). Tetracycline-inducible P23H rhodopsin HEK293 cell line was previously described [25]. To induce the expression of P23H rhodopsin, 1 μg/ml of doxycycline is added to the cell culture media for 20 h.
Immunoprecipitation
Rhodopsin proteins were immunoprecipitated for mass spectrometry (MS) analysis or immunoblotting analysis. Retinas from three to five mice per experiment were collected from Rho +/+, Rho P23H/+, and Rho P23H/P23H mice. MEF in one 10 cm dish were used as controls. To lyse the retinas or MEF cells, 1 ml of PBSD (PBS containing 1.0 % n-dodecyl-β-d-maltoside and protease and phosphatase inhibitor mixture) was added to MEF cells or retinas. After sonication, the suspension was rotated for 1 h at 4 °C. The supernatants were collected, and the protein concentrations were determined with a BCA assay kit (Pierce). Equal amounts of total protein were added to Dynabeads Protein G (Invitrogen) preincubated with 1D4 anti-rhodopsin antibody (Santa Cruz Biotechnologies) and incubated overnight at 4 °C. To elute rhodopsin protein for immunoblotting analysis, beads were heated with SDS sample buffer at 80 °C. For MS analysis, rhodopsin was eluted twice from the beads by heating the beads with elution buffer (PBS containing 8 M urea and 0.5 % n-dodecyl-β-d-maltoside) for 10 min at 80 °C. Total proteins from the two eluates were combined and subjected to methanol chloroform extraction to remove detergent.
Liquid Chromatography–Tandem Mass Spectrometry
Protein pellets were resuspended in 8 M urea. The samples then were reduced by a 20-min incubation with 5 mM tris(2-carboxyethyl)phosphine (TCEP) at room temperature and alkylated in the dark by treatment with 10 mM iodoacetamide for 20 additional min. Proteins were digested overnight at 37 °C with Sequencing Grade Modified Trypsin (Promega, Madison, WI, USA) and the reaction was stopped by acidification. A 100-μm i.d. capillary with a 5-μm pulled tip was packed with 10 cm of 5-μm Aqua C18 material (Phenomenex). This desalting column then was equilibrated for 30 min with buffer A (5 % acetonitrile/0.1 % formic acid), and the protein digest was loaded onto it under pressure. The column was placed in line with an Agilent 1200 quaternary HPLC and analyzed after elution and separation. As peptides eluted from the microcapillary column, they were electrosprayed directly into an LTQ-Orbitrap mass spectrometer from Thermo Finnigan (Waltman, MA) with the application of a distal 2.4-kV spray voltage.
Protein identification and quantification and analyses were done with Integrated Proteomics Pipeline (IP2, Integrated Proteomics Applications, Inc., www.integratedproteomics.com/) using ProLuCID and DTASelect2. Spectrum raw files were extracted into ms1 and ms2 files from raw files with RawExtract 1.9.9 (http://fields.scripps.edu/downloads.php) [37], and the tandem mass spectra were searched against European Bioinformatic Institute protein databases. To estimate peptide probabilities and FDRs accurately, we used a target/decoy database containing the reversed sequences of all the proteins appended to the target database [38]. Tandem mass spectra were matched to sequences by using the ProLuCID [39] algorithm with 50 ppm peptide mass tolerance for precursor ions and 400 ppm for fragment ions.
Immunoblotting Analysis
Mouse retinas were lysed in 300 μl lysis buffer (PBS, 0.5 g/ml n-dodecyl-β-d-maltoside (Calbiochem EMD Bioscience), protease inhibitors (Sigma-Aldrich), and phosphatase inhibitor (Thermo Scientific, Rockford, IL)). MEF cells and HEK293 cells with indicated drug treatments were lysed in SDS lysis buffer (2 % SDS, 62.5 mM Tris-HCl, pH 6.8, containing protease inhibitors and phosphatase inhibitor). The following antibodies and dilutions were used: anti-Gαt1 and 1D4 anti-rod opsin at 1:1,000 dilution (Santa Cruz Biotechnologies); B630N anti-rhodopsin at 1:1,000 (gift of W.C. Smith, Gainesville, FL); anti-calnexin at 1:1,000 at anti-VCP at 1:1,000 at anti-HSP90 at 1:5,000 at and anti-β-tubulin at 1:5,000 (GeneTex); anti-P-JNK at 1:1,000 and anti-JNK at 1:1,000 (Cell Signaling); anti-flag at 1:5,000 (Sigma-Aldrich); and anti-ubiquitin at 1:1,000 (Dako). After overnight incubation with primary antibody, membranes were washed followed by incubation with a horseradish peroxidase-coupled secondary antibody (Cell signaling). Immunoreactivity was detected with the SuperSignal West chemiluminescent substrate (Pierce).
Statistical Analyses
All results are presented as means ± standard deviations from at least three mice per experimental condition as indicated. Student two-tailed t tests (for paired samples) were performed to determine p values. A p value of ≤0.05 was considered statistically significant.
Results
Disruption of Photoreceptor Compartment Morphogenesis in P23H Rhodopsin Knock-in Mice During Early Retinal Degeneration
In wild-type mice (Rho +/+), photoreceptor development and histogenesis follow well-described, stereotyped, temporal programs [40–42]. Photoreceptor neurogenesis starts in the embryo and lasts through approximately the first week of postnatal life (Fig. 1a). Post-mitotic photoreceptor cell bodies accumulate in the outermost neural lamina of the retina, termed the ONL (Fig. 1a). Newly formed rod photoreceptors cells develop morphologically and functionally distinct cellular compartments including the rod inner segment (RIS) and the more distal rod outer segment (ROS). Biosynthetic organelles, such as the ER, Golgi, and mitochondria, are found in the RIS (Fig. 3a), and the RIS cellular compartment can be readily distinguished in Rho +/+ retinas by postnatal day (P) 8 (Fig. 1a). The ROS is a specialized cilium that houses hundreds of membranous discs, embedded with rhodopsin protein for phototransduction [43]. In Rho +/+ mice, nascent ROS were clearly visible at P10 (Fig. 1d) and scattered ROS disc membranes were also seen as early as P7–P8 by electron microscopy [40]. The ROS elongated to about 2/3 of their adult lengths by P15 (Fig. 2a) and reached their maximum adult lengths shortly afterwards as shown at P30 and P60 (Fig. 2d, g).
In heterozygous Rho P23H/+ mice, the ONL thickness was indistinguishable from that of wild-type Rho +/+ mice from P4 through P12 (Fig. 1b, e, h, Table S1). By P15, scattered pyknotic nuclei could be identified (Fig. 2b, Table S1), accompanied by a slight reduction in the mean ONL layer thickness (p < 0.01), (Fig. 4a), indicating the earliest onset of photoreceptor cell loss and retinal degeneration. The lengths of the photoreceptor RIS and ROS compartments in Rho P23H/+ mice were also indistinguishable from those of wild-type mice until P15 (Fig. 1b, e, h, Table S1), when both RIS and ROS compartments were clearly shorter compared to their wild-type photoreceptor counterparts (compare Fig. 2a, b). Later, at P30 (Fig. 2e) and P60 (Fig. 2h), the retinas from heterozygous in Rho P23H/+ mice showed progressive shortening of ROS, RIS, and loss of photoreceptor nuclei in the ONL (Fig. 2e, h) as previously described [27].
In homozygous Rho P23H/P23H retinas, thicknesses of the ONL and RIS were indistinguishable from those of wild-type mice from birth up to P10 (Fig. 1a, c, Table S1). By P10, rare pyknotic photoreceptor nuclei were evident in the ONL (Fig. 1f, Table S1), and photoreceptor RIS lengths were shorter in homozygous Rho P23H/P23H retinas compared to wild-type (Fig. 1d, f, Table S1). Little ROS was seen in homozygous Rho P23H/P23H retinas compared to wild-type at this age (Fig. 1d, f, Table S1). By P12, the prevalence of pyknotic photoreceptor nuclei increased significantly (Fig. 1i, Table S1), accompanied by a measurable reduction in ONL thickness (p < 0.001) (Fig. 4a). Also, by P12, photoreceptor morphology was further compromised with markedly stunted ROS (Fig. 1i) bearing abnormally formed discs visualized by electron microscopy in ciliary protrusions [44]. By P14–15, vacuolization of IS became pronounced (Fig. 3c). The RIS remained short, and few visible ciliary protrusions were present (Figs. 2c, 3c). Forty to 50 % of the ONL thickness was lost (Fig. 2c, Table S1), and the nuclei of many of the remaining photoreceptors were clearly pyknotic (Fig. 2c). By P30 (Fig. 2f) and P60 (Fig. 2i), less than a full row of photoreceptor nuclei remained in the ONL, and some attenuation of the retinal pigmented epithelium was evident at P60 (Fig. 2i).
When the mean ONL values across the entire retina were plotted, sharp differences in the kinetics of photoreceptor loss and amount of retinal degeneration were evident between the heterozygous and homozygous P23H genotypes, with an early and rapid loss of ONL thickness in the Rho P23H/P23H retinas significantly preceding the onset of loss seen in the heterozygous Rho P23H/+ retinas (Fig. 4a). The ONL thicknesses at P30 and later in the homozygous Rho P23H/P23H and heterozygous Rho P23H/+ retinas were similar to our prior findings [27], with the loss of most photoreceptors in the Rho P23H/P23H mice by P30. By contrast, the ONL thickness stabilized and retinal degeneration plateaued in Rho P23H/+ retinas by P30 (Fig. 4a). Previously, we reported a greater loss of photoreceptors in the inferior hemisphere of the eye in heterozygous Rho P23H/+ retinas than in the superior hemisphere by P112 [27]. Our retinal “spidergram” measurements of ONL thickness at different ages in the heterozygote Rho P23H/+ retinas (Fig. 4b) revealed that this hemispheric asymmetrical degeneration was not present at P20, but present at all older ages examined (Fig. 4b, P45 and P90 not shown). In the homozygous Rho P23H/P23H retinas, however, the hemispheric asymmetry in retinal degeneration was reversed, with the superior hemisphere more severely affected in all mice from P12 to P60 (Fig. 4c; P30 and P45 not shown), but not at ages older than P60. The difference in the least marked asymmetry at P12 was significant, however (p < 0.005).
Our analyses of early retinal development revealed an unexpected early onset of photoreceptor pathology in P23H mice. Although photoreceptor neurogenesis and retinal patterning appeared histologically normal in both heterozygous and homozygous P23H mice, severe defects in photoreceptor compartment morphogenesis, especially the proper generation and elongation of ROS and to a lesser extent RIS, appeared in Rho P23H/P23H mice as soon as P10, coinciding with the onset and progressive death of nearly all photoreceptors by P30. Defects in photoreceptor ROS and RIS morphogenesis also appeared in heterozygous Rho P23H/+ mice beginning at a slightly later date, ~P15, and these also coincided with the onset of retinal degeneration. However, by contrast to homozygous mice, far fewer photoreceptors were lost in heterozygous Rho P23H/+ retinas such that the ONL thickness stabilized by ~P30 (Fig. 4a). These studies reveal a critical period within the first postnatal month of life when photoreceptors in both heterozygous and homozygous P23H mice undergo degeneration. We next examined UPR activity during this early period of photoreceptor cell death in P23H rhodopsin mice.
The IRE1 Signaling Pathway of the UPR Is Strongly Induced in Photoreceptors Expressing P23H Rhodopsin In Vivo
To investigate the role of the IRE1 signaling UPR pathway in native photoreceptors, we crossed Rho P23H/P23H mice with ERAI reporter mice [45]. ERAI mice carry a modified FLAG-tagged truncated Xbp-1 that lacks the DNA-binding and transcriptional activator domains but retains the native Xbp-1 intron fused upstream of Venus, a green fluorescent protein (GFP) variant. Activated IRE1 splices out the Xbp-1 intron, leading to the production of FLAG-tagged XBP1-Venus fusion protein [45]. Thus, the ERAI reporter mouse provides a highly specific monitor of the status of IRE1 signaling at the cellular, tissue, and organ level. In the eye, the ERAI reporter mouse offers a useful way to distinguish IRE1 signaling status between the different laminar layers of the retina [46, 47].
In Rho P23H/+ ERAI +/− mice, we detected strong expression of XBP1-Venus protein in retinas compared to Rho +/+ ERAI +/− littermates at P30 (Fig. 5a–h). Strong XBP1-Venus expression was localized to rod photoreceptor cells in the outer nuclear layer (Fig. 5d) with strong staining seen in the RIS and perinuclear region of all rod photoreceptors (Fig. 5f, h). XBP1-Venus expression was excluded from photoreceptor nuclei consistent with the deletion of the DNA-binding domain of XBP1 in the reporter construct (Fig. 5f, h and [45]). By contrast, in wild-type retinas, only rare XBP1-Venus staining was observed in photoreceptors in the ONL (Fig. 5c, e, g). At P120, we also observed strong XBP1-Venus staining in the Rho P23H/+ ERAI +/− mice, but not the Rho +/+ ERAI +/− littermates (Fig. 5i–l). In other retinal cells of Rho P23H/+ ERAI +/− mice, XBP1-Venus staining was also rarely seen in cone photoreceptors (indicated by a white arrow in Fig. 5l), the inner nuclear layer, ganglion cell layer, and retinal pigment epithelium (data not shown). Whole retinal lysates also showed significantly increased FLAG-tagged XBP1-Venus protein expression in Rho P23H/+ ERAI +/− mice compared to controls (Fig. 5m), consistent with the increased XBP1-Venus protein by imaging. These findings demonstrate that the ERAI reporter is efficiently and specifically activated in rod photoreceptors expressing P23H rhodopsin.
To confirm the activation status of the endogenous IRE1 signal transduction pathway in retina, we examined the splicing status of native Xbp-1 mRNA in Rho P23H/+ ERAI +/− mice. We found increased levels of spliced Xbp-1 mRNA in animals expressing P23H rhodopsin (Fig. 6a). Spliced Xbp-1 produces a potent transcription factor, XBP1s, with many transcriptional targets that are shared between diverse mammalian cells [14, 13, 48, 49]. In both Rho P23H/+ and Rho P23H/P23H mice, we found significantly elevated mRNA levels of Erdj4, VCP, Derl1, and Grp78 (Fig. 6b–e) at P30. Furthermore, we found a P23H rhodopsin dose-dependent increase in the upregulation of Xbp-1 splicing and XBP1s target genes, with significantly higher levels of spliced Xbp-1, Erdj4, VCP, Derl1, and Grp78 in retinas from Rho P23H/P23H mice expressing two copies of P23H rod opsin gene compared to the Rho P23H/+ mice expressing only one copy (Fig. 6a–e). From these findings, we conclude that P23H rhodopsin induces ER stress and strongly activates the IRE1 pathway in photoreceptors in vivo.
Next, we examined the onset and duration of IRE1 signaling in Rho P23H/+ ERAI +/− mice. We detected no expression of FLAG-tagged XBP1-Venus protein by anti-Flag or anti-GFP antibodies at P5 (Fig. 5n). By P14, we saw faint expression of FLAG-tagged XBP1-Venus protein by anti-GFP immunoblotting, indicating that the IRE1 pathway was becoming activated in these retinas. The XBP1-Venus protein levels detected by both anti-GFP and anti-Flag progressively increased by P30, and these levels along with mRNA levels of downstream transcriptional targets of XBP1s, such as ERdj4, remained strongly elevated at older ages (P60 and P90) (Fig. 6f, g). These findings demonstrated that photoreceptors expressing P23H rhodopsin activated the IRE1 signal transduction pathway by ~P14, and IRE1 signaling remained strongly activated thereafter. Interestingly, the onset of IRE1 signaling closely mirrored the onset of photoreceptor degeneration seen in Rho P23H/+ mice (Fig. 2b). Furthermore, IRE1 signaling remained strongly activated in photoreceptors even after retinal degeneration had plateaued in heterozygous Rho P23H/+ mice (Fig. 4a). IRE1 signaling can also activate the JNK pathway independent of its induction of XBP1s in vitro [50]. However, we saw no increases in activated phosphorylated JNK levels in P23H animals compared to controls (Fig. 6h). We subsequently focused our studies on the consequences of IRE1’s induction of XBP1s in the retina.
ERAD Induction Leads to Ubiquitination and Rapid Degradation of P23H Rhodopsin In Vivo
Previously, we found that artificial activation of IRE1 signaling to selectively induce XBP1s targeted P23H rhodopsin for protein degradation in vitro [25]. The genes we found transcriptionally upregulated in retinas expressing P23H rhodopsin all play well-defined roles in ERAD (p97/VCP and Derlin1) and/or ER protein folding (ERdj4 and Grp78/BiP) (Fig. 6b–e, and [51]). To determine if ERAD components and ER chaperones targeted P23H rhodopsin in photoreceptors, we performed mass spectrometry analysis on pure P23H rhodopsin immunoprecipitated from retinas of homozygous Rho P23H/P23H mice and wild-type rhodopsin immunoprecipitated from Rho +/+ mice. We consistently detected increased interaction of P23H rhodopsin with ER chaperones and ERAD components in triplicate experimental mass spectrometry analyses from retinal lysates compared to analogous studies with wild-type rhodopsin (Fig. 7a). We also confirmed some of the P23H rhodopsin interactions identified by mass spectrometry in retinal co-immunoprecipitation studies where we found increased levels of p97/VCP and calnexin after rhodopsin pull-down in photoreceptors from Rho P23H/P23H mice compared to wild-type mice (Fig. 7b). The transcriptional induction of ERAD genes and increased association between ERAD proteins and P23H rhodopsin protein suggested that photoreceptors of Rho P23H/P23H mice target misfolded rhodopsin for ERAD. Consistent with this notion, we found a substantial increase in the amount of ubiquitination on the purified P23H rhodopsin (Fig. 7c). In heterozygous Rho P23H/+ mice that express both WT and mutant P23H rhodopsin protein, we found a significant increase in the amount of ubiquitinated rhodopsin protein after immunoprecipitation with an antibody that recognizes both WT and P23H rhodopsin proteins (Fig. 7c, lower panel). In homozygous Rho P23H/P23H that expresses only mutant P23H rhodopsin protein, we found a massive amount of ubiquitination on the immunoprecipitated P23H rhodopsin protein (Fig. 7c, lower panel). These data demonstrate that induction of ERAD by IRE1 signaling leads to profound ubiquitination of P23H rhodopsin in photoreceptors, indicating P23H rhodopsin is targeted in vivo for degradation. Indeed, when we examined steady-state levels of rhodopsin from wild-type, heterozygous Rho P23H/+, and homozygous Rho P23H/P23H retinas, we found substantial loss of total rhodopsin protein in P23H rhodopsin-expressing mice with almost complete loss of rhodopsin protein from photoreceptors in homozygous Rho P23H/P23H mice (Fig. 8a), despite equivalent levels of rod opsin mRNA gene expression in wild-type and P23H rhodopsin-expressing mice at P14 (Fig. 8b). Immunofluorescence analysis confirmed the pronounced loss of rhodopsin protein in homozygous Rho P23H/P23H photoreceptor cells (Fig. 8c). In stark contrast to the pronounced retention of P23H rhodopsin in the ER when P23H rhodopsin is expressed in heterologous cell types, we detected no ER-retained P23H rhodopsin in native photoreceptors under non-saturating imaging conditions (Fig. 8c, note the absence of rhodopsin staining of the IS and perinuclear regions of the ONL as exhibited by calnexin expression). However, under these imaging conditions, P23H rhodopsin expression in Rho P23H/P23H photoreceptors was found outside of the ER at the base of the stunted OS (Fig. 8c), corresponding to ciliary protrusion and abnormal discs where P23H predominantly localized as we reported previously by immuno-electron microscopy [44].
Loss of rhodopsin protein in Rho P23H/P23H photoreceptors was apparent as early as P5 (Fig. 8d). Loss of P23H rhodopsin protein was not due to photoreceptor cell death, as we observed no frank degeneration of photoreceptor compartment morphology, pyknotic nuclei, or any ONL thinning at this early age (Fig. 1 and Table S1). Furthermore, we found normal protein levels of rod photoreceptor-specific transducin α-subunit (GNAT1) at P5 [52], indicating that photoreceptors still generated other rod-specific proteins (Fig. 8d). We conclude that loss of rhodopsin protein occurs shortly after photoreceptors are formed. Furthermore, the loss of rhodopsin protein precedes the onset of morphologic defects arising in photoreceptor compartments, obvious photoreceptor cell death, and retinal degeneration. ERAD was directly involved in rhodopsin protein degradation, as we prevented the degradation of P23H rhodopsin upon application of ERAD inhibitors, kifunensine, an inhibitor of ER mannosidase I [53, 54], or eeyarastatin I, an inhibitor of p97/VCP ATPase activity [55, 56], in vitro (Fig. 8e, f).
Chronic ER Stress-Induced Pro-apoptotic Chop Does Not Contribute to P23H Rhodopsin-Induced Retinal Degeneration
Uncorrectable ER stress ultimately triggers cell death, most notably by activating the PERK signaling pathway of the UPR which phosphorylates eIF2α leading to strong induction of ATF4 transcriptional activator and its downstream pro-apoptotic Chop gene [17, 1]. ER stress-inducing toxins, tunicamycin and thapsigargin, strongly induced Chop, and overexpression of P23H rhodopsin in heterologous cell types or atop native wild-type rhodopsin in transgenic mice also upregulated Chop [26, 57]. Furthermore, Chop −/− mice were resistant to cell death and damage induced by ER protein misfolding [58–60]. These findings support a model whereby P23H rhodopsin expression in photoreceptors leads to strong Chop induction that drives photoreceptor cell death in vivo. However, our analysis of Rho P23H/P23H retinas revealed low steady-state levels of P23H rhodopsin in photoreceptors (Fig. 8a, d) and no obvious aggregation or retention of P23H rhodopsin within the ER (the RIS/perinuclear compartment) of photoreceptors (Fig. 8c). Furthermore, ER dilation and fragmentation, ultrastructural abnormalities seen with irreparable ER stress, were not observed in the RIS of Rho P23H/P23H photoreceptors, (Fig. 3c). These findings raise an alternative scenario whereby the robust degradation of P23H rhodopsin by induction of ERAD in photoreceptors effectively eliminated misfolded rhodopsin from the ER. In this model, ER stress is alleviated, and therefore, Chop would not be induced nor causally contribute to photoreceptor cell death.
To address these competing models of Chop’s role in the photoreceptor cell death seen in P23H rhodopsin mice, we measured Chop mRNA levels at time points spanning the entire period of retinal degeneration in heterozygote Rho P23H/+ and homozygous Rho P23H/P23H mice. In both Rho P23H/+ and Rho P23H/P23H mice, we saw no significant increase in Chop mRNA levels compared to age-matched wild-type mice at all ages (Fig. 9a, b). We also found no increase in ATF4 protein in either Rho P23H/+ or Rho P23H/P23H mice and only a mild elevation in phosphorylated eIF2α protein levels (Fig. 9c). By contrast, all of these markers were strongly induced by a strong ER toxin, thapsigargin (Tg), in vitro (Fig. 9c). These findings indicate that PERK signaling is weakly activated in vivo in photoreceptors expressing P23H rhodopsin, and PERK signaling does not rise sufficiently to trigger its downstream pro-apoptotic ATF4-CHOP circuit. Consistent with this interpretation, when we examined retinal degeneration in Rho P23H/+ Chop −/− mice, we found no significant change in ONL thickness, a proxy for photoreceptor cell numbers, compared to Rho P23H/+ Chop +/+ mice (Fig. 9d). We conclude that photoreceptor cell death induced by P23H rhodopsin in vivo occurs independently of CHOP.
Discussion
Our studies reveal an unexpected asymmetry in the use of the UPR by photoreceptor cells expressing P23H rhodopsin where we found strong IRE1 signaling but minimal PERK signaling. How does P23H rhodopsin trigger IRE1 so well with lesser effect on PERK? Direct interaction between IRE1’s ER-luminal domain and misfolded protein is an important step in activation of IRE1 [61]. One possibility could be that misfolded P23H rhodopsin protein preferentially interacts with IRE1 but not PERK in the ER lumen of photoreceptors, and therefore the IRE1 pathway is more activated. This appears unlikely given the strong homology between the luminal domains of IRE1 and PERK [62]. A second possibility is that PERK is actively repressed in photoreceptors through inhibition of its cytosolic kinase by binding of p58IPK or Nck proteins [63, 64]. A third possibility is that photoreceptors eliminate misfolded P23H rhodopsin so efficiently that the ambient levels of ER stress never rise to the threshold needed to trigger strong PERK signaling and its induction of the ATF4-CHOP pro-apoptotic circuit. The ER of photoreceptors is highly specialized toward the production of rhodopsin because rhodopsin is expressed in massive quantities only by rod photoreceptors [65, 43]. To cope with continuous rhodopsin protein production throughout life, the ER of photoreceptor cells must be exquisitely optimized toward folding rhodopsin as well as recognizing and removing any damaged/misfolded rhodopsin. In support of this model, we observed no obvious aggregates or retention of misfolded rhodopsin in the ER of photoreceptors and no ultrastructural alterations in ER morphology in P23H rhodopsin photoreceptors. By contrast, mutant rhodopsin aggregates are consistently found in the ER of heterologous cell types possibly because the ER of these cells is not as well equipped to process rhodopsin as the ER of native photoreceptor cells.
Heterozygous Rho P23H/+ mice closely model the genetic dosage and slow retinal degeneration seen in patients with the P23H mutation, in whom decades typically pass before vision loss becomes detrimental [27]. In Rho P23H/+ mice, IRE1 and ERAD are also activated in photoreceptors as in Rho P23H/P23H mice. However, after an early wave of photoreceptor cell death during the first postnatal month, photoreceptor numbers stabilize at ~50 % the number of photoreceptors found in wild-type mice (Figs. 2, 4a). Our analysis of Rho P23H/+ ERAI +/− mice (Fig. 5) revealed coincident peak induction of the IRE1 reporter during this period as well. These findings suggest that IRE1 signaling is perpetually activated in Rho P23H/+ photoreceptor cells throughout life and cowal maintain a fine proteostatic balance within the cell whereby P23H rhodopsin (synthesized from the mutant allele) is removed, whereas wild-type rhodopsin (produced by the remaining normal rhodopsin allele) is properly folded, exported to the ROS, and vision is retained. Here, Rho P23H/+ mimics the rhodopsin haplo-insufficiency seen in Rho +/− mice. Mild ROS and RIS photoreceptor compartment disorganization is seen in Rho +/- mice [21]. However, rhodopsin haplo-insufficiency does not cause photoreceptor cell death or vision loss in Rho +/− mice or people [21, 20, 66, 67]. So, why are heterozygous Rho P23H/+ photoreceptors prone to cell death, albeit it at a slow protracted pace?
One possibility is that the small amount of P23H rhodopsin that exits the ER and escapes ERAD exerts a cytotoxic effect in photoreceptor cells, not seen in cell lines. This residual P23H rhodopsin concentrates in misshapen discs within stunted rod outer segments in Rho P23H/P23H mice whereas wild-type rhodopsin is found in normally stacked discs in the rod outer segments of Rho +/+ mice [44]. It is unclear if subcellular mislocalization of P23H rhodopsin is causally linked to the disorganization of discs or dysgenesis of the ROS compartment. However, disruption of rod outer segment structure or function would be deleterious for photoreceptor viability. Another factor affecting why heterozygous Rho P23H/+ photoreceptors are more prone to death as they age is that exogenous insults that trigger ER stress in the retina could exacerbate ER stress already induced by P23H rhodopsin. Numerous environmental factors including phototoxicity, nutrient imbalances, infections, inflammation, and toxins (e.g., tobacco) have been shown to trigger ER stress in the eye [68–71]. Addition of environmentally induced ER stressors on top of P23H rhodopsin-induced ER stress could upset the proteostatic balance maintained by the UPR signaling network leading to photoreceptor cell death.
Our analysis of misfolded rhodopsin reveals how its preferential activation of different programs and modules of the UPR, in particular ERAD and IRE1, may drive the pathophysiology of photoreceptor cell death and retinal degeneration arising from misfolded rhodopsin-induced ER stress. Other neurodegenerative diseases associated with misfolded proteins also cause ER stress, but the UPR signaling pathways and transcriptional, translational, or post-translational UPR programs most relevant to each disease may also vary depending on the specific misfolded protein, morphologies, and functions found in the targeted neuronal cell types.
Abbreviations
- ERAD:
-
ER-associated protein degradation
- IRE1:
-
Inositol-requiring enzyme 1
- ONL:
-
Outer nuclear layer
- PERK:
-
PKR-like endoplasmic reticulum kinase
- qPCR:
-
Quantitative real-time PCR
- RP:
-
Retinitis pigmentosa
- RIS:
-
Rod inner segment
- ROS:
-
Rod outer segment
- UPR:
-
Unfolded protein response
- XBP-1:
-
X-box-binding protein 1
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Acknowledgements
We thank J. Han, N. Hiramatsu, C. Sigurdson, W. C. Smith, S. Tsang, and L. Wiseman for helpful suggestions and reagents. These studies were supported by NIH grants EY001919, P30EY002162, and EY020846, Foundation Fighting Blindness, UCSD Neuroscience Microscopy Shared Facility P30 NS047101, and VA Merit award BX002284. W.-C. Chiang received postdoctoral support from the Fight-for-Sight Foundation.
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Chiang, WC., Kroeger, H., Sakami, S. et al. Robust Endoplasmic Reticulum-Associated Degradation of Rhodopsin Precedes Retinal Degeneration. Mol Neurobiol 52, 679–695 (2015). https://doi.org/10.1007/s12035-014-8881-8
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DOI: https://doi.org/10.1007/s12035-014-8881-8