Unfolded protein response-induced dysregulation of calcium homeostasis promotes retinal degeneration in rat models of autosomal dominant retinitis pigmentosa.

The molecular mechanism of autosomal dominant retinitis pigmentosa (ADRP) in rats is closely associated with a persistently activated unfolded protein response (UPR). If unchecked, the UPR might trigger apoptosis, leading to photoreceptor death. One of the UPR-activated cellular signaling culminating in apoptotic photoreceptor cell death is linked to an increase in intracellular Ca(2+). Therefore, we validated whether ADRP retinas experience a cytosolic Ca(2+) overload, and whether sustained UPR in the wild-type retina could promote retinal degeneration through Ca(2+)-mediated calpain activation. We performed an ex vivo experiment to measure intracellular Ca(2+) in ADRP retinas as well as to detect the expression levels of proteins that act as Ca(2+) sensors. In separate experiments with the subretinal injection of tunicamycin (UPR inducer) and a mixture of calcium ionophore (A231278) and thapsigargin (SERCA2b inhibitor) we assessed the consequences of a sustained UPR activation and increased intracellular Ca(2+) in the wild-type retina, respectively, by performing scotopic ERG, histological, and western blot analyses. Results of the study revealed that induced UPR in the retina activates calpain-mediated signaling, and increased intracellular Ca(2+) is capable of promoting retinal degeneration. A significant decline in ERG amplitudes at 6 weeks post treatment was associated with photoreceptor cell loss that occurred through calpain-activated CDK5-pJNK-Csp3/7 pathway. Similar calpain activation was found in ADRP rat retinas. A twofold increase in intracellular Ca(2+) and up- and downregulations of ER membrane-associated Ca(2+)-regulated IP3R channels and SERCA2b transporters were detected. Therefore, sustained UPR activation in the ADRP rat retinas could promote retinal degeneration through increased intracellular Ca(2+) and calpain-mediated apoptosis.

An activated unfolded protein response promotes retinal degeneration and triggers an inflammatory response in the mouse retina.

Recent studies on the endoplasmic reticulum stress have shown that the unfolded protein response (UPR) is involved in the pathogenesis of inherited retinal degeneration caused by mutant rhodopsin. However, the main question of whether UPR activation actually triggers retinal degeneration remains to be addressed. Thus, in this study, we created a mouse model for retinal degeneration caused by a persistently activated UPR to assess the physiological and morphological parameters associated with this disease state and to highlight a potential mechanism by which the UPR can promote retinal degeneration. We performed an intraocular injection in C57BL6 mice with a known unfolded protein response (UPR) inducer, tunicamycin (Tn) and examined animals by electroretinography (ERG), spectral domain optical coherence tomography (SD-OCT) and histological analyses. We detected a significant loss of photoreceptor function (over 60%) and retinal structure (35%) 30 days post treatment. Analysis of retinal protein extracts demonstrated a significant upregulation of inflammatory markers including interleukin-1ß (IL-1ß), IL-6, tumor necrosis factor-α (TNF-α), monocyte chemoattractant protein-1 (MCP-1) and IBA1. Similarly, we detected a strong inflammatory response in mice expressing either Ter349Glu or T17M rhodopsin (RHO). These mutant rhodopsin species induce severe retinal degeneration and T17M rhodopsin elicits UPR activation when expressed in mice. RNA and protein analysis revealed a significant upregulation of pro- and anti-inflammatory markers such as IL-1ß, IL-6, p65 nuclear factor kappa B (NF-kB) and MCP-1, as well as activation of F4/80 and IBA1 microglial markers in both the retinas expressing mutant rhodopsins. We then assessed if the Tn-induced inflammatory marker IL-1ß was capable of inducing retinal degeneration by injecting C57BL6 mice with a recombinant IL-1ß. We observed ~19% reduction in ERG a-wave amplitudes and a 29% loss of photoreceptor cells compared with control retinas, suggesting a potential link between pro-inflammatory cytokines and retinal pathophysiological effects. Our work demonstrates that in the context of an established animal model for ocular disease, the persistent activation of the UPR could be responsible for promoting retinal degeneration via the UPR-induced pro-inflammatory cytokine IL-1ß.

Caspase-7 ablation modulates UPR, reprograms TRAF2-JNK apoptosis and protects T17M rhodopsin mice from severe retinal degeneration.

The UPR is activated in the mouse retina expressing misfolded T17M rhodopsin (RHO) during autosomal dominant retinitis pigmentosa (ADRP) progression. Therefore, the goal of this study is to validate the UPR-induced caspase-7 as a new therapeutic target that modulates the UPR, reduces the level of apoptosis and protects the ADRP retina from retinal degeneration and light-induced damage. Mice were analyzed using ERG, SD-OCT and histology to determine the role of caspase-7 ablation. The results of these experiments demonstrate the significant preservation of photoreceptors and their function in T17M RHO CASP-7 retinas from P30 to P90 compared with control mice. These mice were also protected from the light-induced decline in the ERG responses and apoptosis. The RNA and protein analyses of T17M RHO+Csp7-siRNA, Tn+Csp7-siRNA 661W cells and T17M RHO CASP-7 retinas revealed that caspase-7 ablation reprograms the UPR and reduces JNK-induced apoptosis. This reduction is believed to occur through the downregulation of the mTOR and Hif1a proteins. In addition, decline in activated PARP1 was detected in T17M RHO CASP-7 retina. Altogether, our findings indicate that the targeting of caspase-7 in T17M RHO mice could be a feasible therapeutic strategy for advanced stages of ADRP.

Suppression of mouse rhodopsin expression in vivo by AAV mediated siRNA delivery.

PURPOSE: The purpose of this study is to demonstrate that the expression of rhodopsin can be down regulated in vivo by AAV-delivered siRNA. This is the first step in an RNA replacement strategy for the allele-independent treatment of Autosomal Dominant Retinitis Pigmentosa (ADRP). METHODS: HEK 293 cells were co-transfected with a plasmid carrying mouse RHO cDNA driven by the CMV promoter and a chemically synthesized siRNA duplex of 21 nucleotides. Reduction of RHO mRNA was confirmed by RT-PCR. One active siRNA and a control siRNA were embedded in a small hairpin RNA (shRNA) and cloned in Adeno-associated virus (AAV) vector under regulation of the H1 promoter and containing a GFP reporter. AAV5 expressing either active siRNA or an irrelevant siRNA were subretinaly injected into the right eyes of wild-type or RHO+/- heterozygote mice at post-natal day 16. At 1 and 2 months post-injection, animals were analyzed by electroretinography (ERG). Animals were then sacrificed, and retinas were examined by Western blot, RT-PCR, histology and immunohistochemistry. RESULTS: All of the siRNAs tested in HEK 293 cells caused degradation of RHO mRNA, although the efficiency varied from 25% to 80%. In vivo siRNA delivery to the retina led to more than 40% reduction of scotopic a- and b-wave amplitudes in RHO+/- heterozygotes. Although the reduction of RHO mRNA was estimated at 30% compared to control animals, Western blots revealed 60% decrease in rhodopsin content. Histological analysis showed significant reduction in the thickness of the ONL, ranging between 53% and 86%. CONCLUSIONS: AAV-siRNA delivery into the subretinal space resulted in the reduction of retinal function caused by diminished RHO mRNA and protein content. This level of reduction may permit the replacement of endogenous mRNA with siRNA-resistant mRNA encoding wild-type RHO.

Preservation of photoreceptor morphology and function in P23H rats using an allele independent ribozyme.

To develop an allele independent ribozyme for the treatment of autosomal dominant retinitis pigmentosa (ADRP) associated with mutations in the rhodopsin (RHO) gene, a ribozyme targeting dog, mouse, human but not rat rhodopsin (RHO) mRNA was designed and tested in vitro. Activity of this ribozyme was tested in tissue culture by co-transfection of HEK 293 cells with plasmids expressing opsin mRNA and ribozyme, followed by quantitative RT-PCR to evaluate the level of RHO mRNA. For experiments in vivo, Rz525 driven by the mouse opsin proximal promoter was inserted in plasmids with AAV 2 terminal repeats (TR) and packaged in AAV serotype 5 capsids. AAV-Rz525 was injected subretinally into the right eyes of P23H rat pups. Left eyes were injected with virus expressing GFP from the identical promoter. Animals were analyzed at 4, 8 and 12 weeks post-injection by full field scotopic electroretinography (ERG). After 12 weeks, animals were sacrificed and retinas were dissected, fixed and sectioned. Rz525 had high catalytic activity in vitro and led to a 50% reduction of RHO mRNA in cells. AAV-Rz525 injection into P23H transgenic rats led to significant preservation (about 50%) of scotopic ERG a- and b-wave amplitudes. Histological analysis showed an increased number of ONL nuclei in the central and superior retina of treated eyes relative to control eyes. RT-PCR analysis revealed 46% reduction of transgenic (mouse) RHO mRNA in right eyes relative to left eyes and no change in rat RHO mRNA. AAV5 delivery of Rz525 resulted in a partial rescue of the light response and structural preservation of photoreceptors in transgenic rats. This ribozyme may be a useful component of an RNA replacement gene therapy for ADRP.

Knockdown of wild-type mouse rhodopsin using an AAV vectored ribozyme as part of an RNA replacement approach.

PURPOSE: To develop a hammerhead ribozymes (Rz) that might be exploited in a "digest and replace" gene therapy strategy for autosomal dominant retinitis pigmentosa (ADRP) caused by mutations in the gene for rhodopsin (RHO). METHODS: A ribozyme (Rz397) was designed to hybridize with an accessible region in rhodopsin mRNA. It was tested in vitro to determine the kinetics of cleavage of a target oligonucleotide. Following transfection of cultured cells, reduction of rhodopsin mRNA in response to Rz397 was measured RT-PCR. The gene for the ribozyme (Rz397) was inserted in an adeno-associated virus (AAV2) vector and packaged in AAV2 capsids. The virus was injected subretinally in the eyes of C57BL/6J (RHO+/+) and rhodopsin knockout hemizygous (RHO+/-) mice at postnatal days 6 (P6) and 30 (P30). Mice were analyzed by full-field electroretinography (ERG). The reduction of opsin protein was measured by western blot analysis and visualized by immunocytochemistry. Reduction of rhodopsin mRNA was assessed using in situ hybridization. Morphometric microscopy of fluorescent antibody-antigen complexes and autoradiography of retinas were used to quantify levels of rhodopsin protein and mRNA, respectively. RESULTS: Transient co-transfection of HEK 293 cells with a wild-type rhodopsin cDNA and Rz397 resulted in an approximately 60% reduction of RHO mRNA one day after transfection. RHO+/- -mice injected with AAV2-Rz397 at P6 showed a 50% reduction in b-wave amplitudes in injected eyes relative to saline injected contralateral eyes. However, injection of RHO+/- -animals at one month and of RHO+/+-animals at either age had no impact on ERG. Nevertheless, we detected an 80% reduction of opsin protein in ribozyme-injected eyes of hemizygous mice (by western blot) and a 50% reduction in opsin content in RHO+/+ mice (by morphometry). These reductions were confirmed by in situ hybridization. CONCLUSIONS: AAV2-Rz397 led to significant (greater than or equal to 50%) reduction of rhodopsin mRNA and protein in mice. It affected ERG amplitudes only when injected in hemizygous RHO knockout pups. This RNA inhibitor may prove useful in treating animal models of ADRP as part of an RNA replacement approach.

A mutant mitochondrial respiratory chain assembly protein causes complex III deficiency in patients with tubulopathy, encephalopathy and liver failure.

Complex III (CIII; ubiquinol cytochrome c reductase of the mitochondrial respiratory chain) catalyzes electron transfer from succinate and nicotinamide adenine dinucleotide-linked dehydrogenases to cytochrome c. CIII is made up of 11 subunits, of which all but one (cytochrome b) are encoded by nuclear DNA. CIII deficiencies are rare and manifest heterogeneous clinical presentations. Although pathogenic mutations in the gene encoding mitochondrial cytochrome b have been described, mutations in the nuclear-DNA-encoded subunits have not been reported. Involvement of various genes has been indicated in assembly of yeast CIII (refs. 8-11). So far only one such gene, BCS1L, has been identified in human. BCS1L represents, therefore, an obvious candidate gene in CIII deficiency. Here, we report BCS1L mutations in six patients, from four unrelated families and presenting neonatal proximal tubulopathy, hepatic involvement and encephalopathy. Complementation study in yeast confirmed the deleterious effect of these mutations. Mutation of BCS1L would seem to be a frequent cause of CIII deficiency, as one-third of our patients have BCS1L mutations.

A mutation in the human heme A:farnesyltransferase gene (COX10 ) causes cytochrome c oxidase deficiency.

Cytochrome c oxidase (COX) defects are found in a clinically and genetically heterogeneous group of mitochondrial disorders. To date, mutations in only two nuclear genes causing COX deficiency have been described. We report here a genetic linkage study of a consanguineous family with an isolated COX defect and subsequent identification of a mutation in a third nuclear gene causing a deficiency of the enzyme. A genome-wide search for homozygosity allowed us to map the disease gene to chromosome 17p13.1-q11.1 (Z (max)= 2.46; theta = 0.00 at the locus D17S799). This region encompasses two genes, SCO1 and COX10, encoding proteins involved in COX assembly. Mutation analysis followed by a complementation study in yeast permitted us to ascribe the COX deficiency to a homozygous missense mutation in the COX10 gene. This gene encodes heme A:farnesyltransferase, which catalyzes the first step in the conversion of protoheme to the heme A prosthetic groups of the enzyme. All three nuclear genes now linked to isolated COX deficiency are involved in the maturation and assembly of COX, emphasizing the major role of such genes in COX pathology.