Project description:Heterogeneous degeneration of retinal pigment epithelium (RPE) leads to irreversible blindness in diseases associated with macular atrophy. However, the underlying mechanisms of regional RPE degeneration remain poorly understood. To address this gap, this study first identifies a novel RPE subpopulation through the spatial, transcriptomic, and functional analyses, thereby contributing to the understanding of the heterogeneity of degenerative RPE cells. Specifically, omics analyses in human and macaque RPE reveal a peripheral RPE cell population with high SERPINE3 expression, while SERPINE3-GFP knock-in mice show comparable expression patterns. In addition, SMART-seq2 analysis further distinguishes transcriptomic profiles between GFP-positive and GFP-negative RPE cells. Under oxidative stress, SERPINE3 expression increases, and GFP-positive cells exhibit improved survival and reentry into the cell cycle. Notably, genetic studies indicate that SERPINE3 is essential for the oxidative stress resistance of GFP-positive cells. Moreover, loss of SERPINE3 results in regional RPE degeneration and increased microglial accumulation in aged mice. Mechanistically, proteinase screening and co-immunoprecipitation indicate that SERPINE3 targets Caspase-1. Importantly, delivery of SERPINE3 via AAV-Serpine3 prevents RPE degeneration in a geographic atrophy disease model. These findings advance the understanding of RPE heterogeneous degeneration and highlight SERPINE3 as a novel protective factor with therapeutic potential for macular atrophy.

Project description:Heterogeneous degeneration of retinal pigment epithelium (RPE) leads to irreversible blindness in diseases associated with macular atrophy. However, the underlying mechanisms of regional RPE degeneration remain poorly understood. To address this gap, this study first identifies a novel RPE subpopulation through the spatial, transcriptomic, and functional analyses, thereby contributing to the understanding of the heterogeneity of degenerative RPE cells. Specifically, omics analyses in human and macaque RPE reveal a peripheral RPE cell population with high SERPINE3 expression, while SERPINE3-GFP knock-in mice show comparable expression patterns. In addition, SMART-seq2 analysis further distinguishes transcriptomic profiles between GFP-positive and GFP-negative RPE cells. Under oxidative stress, SERPINE3 expression increases, and GFP-positive cells exhibit improved survival and reentry into the cell cycle. Notably, genetic studies indicate that SERPINE3 is essential for the oxidative stress resistance of GFP-positive cells. Moreover, loss of SERPINE3 results in regional RPE degeneration and increased microglial accumulation in aged mice. Mechanistically, proteinase screening and co-immunoprecipitation indicate that SERPINE3 targets Caspase-1. Importantly, delivery of SERPINE3 via AAV-Serpine3 prevents RPE degeneration in a geographic atrophy disease model. These findings advance the understanding of RPE heterogeneous degeneration and highlight SERPINE3 as a novel protective factor with therapeutic potential for macular atrophy.

Project description:Oxidative stress (OS) and inflammation play pivotal roles in retinal pigment epithelium (RPE) degeneration and age-related macular degeneration (AMD) pathogenesis. Interleukin 17 (IL17) signaling is a founding pathway regulating inflammatory response, the IL17 ligand has been shown to induce RPE degeneration and is emerging as a potential target for AMD treatment. However, the regulation and function of IL17 receptors are largely unexplored in RPE cells under OS. Here, we identified that IL17RA was significantly upregulated in the presence of OS both in human and mouse RPE cells. We found that OS upregulates expression of reprogramming factor Kruppel-like factor 4 (KLF4), which directly binds to the IL17RA promoter and activates IL17RA transcription, therefore inducing RPE proinflammatory response. Furthermore, our results reveal that KLF4 isoform 2, but not the canonical KLF4 isoform1, is the major isoform in RPE cells that activates IL17RA transcription. Finally, we demonstrate that mRNA level of IL17RA was positively correlated with that of KLF4 isoform2 in AMD patients. Together, our data demonstrates a new regulatory mechanism of IL17RA by KLF4 upon OS exposure, which is likely to play a role in AMD pathogenesis.

Project description:Purpose: PDGF-D is a potent angiogenic and immune-related factor. It has been demonstrated that PDGF-D play roles in the pathological process of ocular angiogenesis and degenerative diseases. In our previous study, we established a retinal pigment epithelial (RPE) cell-specifc AAV-PDGF-D/GFP mouse model to study PDGF-D's role in age-related macular degeneration (AMD). In this study, we utilized the single-cell transcriptiome seqeuncing technique to explore the cell types of immune cells attracted by PDGF-D overepxression using the same animal models, with emphases on the impact of PDGF-D overexpression on individual cell's behaviour.

Project description:Age-related Macular Degeneration (AMD), a blinding eye disease, is characterized by pathological protein- and lipid-rich drusen deposits underneath the retinal pigment epithelium (RPE) and atrophy of the RPE monolayer in advanced disease stages - leading to photoreceptor cell death and vision loss. Currently, there are no drugs to stop drusen formation or RPE atrophy in AMD. We developed an iPSC-RPE AMD model that recapitulates drusen and RPE atrophy. Drusen deposition is dependent on AMD-risk-allele CFH(H/H) and anaphylatoxin triggered alternate complement signaling via the activation of NF-B and downregulation of autophagy pathways. High-throughput screen identified two drugs, L-745,870, a dopamine receptor antagonist, and aminocaproic acid, a protease inhibitor that reduce drusen deposits and restore RPE epithelial phenotype in anaphylatoxin challenged iPSC-RPE with or without the CFH(H/H) genotype. This comprehensive iPSC-RPE model replicates key AMD phenotypes, provides molecular insight into the role of CFH(H/H) risk-allele in AMD, and discovers two candidate drugs to treat AMD.

Project description:The retinal pigment epithelium (RPE) provides vital support to photoreceptor cells and its dysfunction is associated with the onset and progression of age-related macular degeneration (AMD). Surgical provision of RPE cells may ameliorate AMD and thus it would be valuable to develop sources of patient-matched RPE cells for this application of regenerative medicine. We describe here the generation of functional RPE-like cells from fibroblasts that represent an important step toward that goal. We identified candidate master transcriptional regulators of RPEs using a novel computational method and then used these regulators to guide exploration of the transcriptional regulatory circuitry of RPE cells and to reprogram human fibroblasts into RPE-like cells. The RPE-like cells share key features with RPEs derived from healthy individuals, including morphology, gene expression and function, and thus represent a step toward the goal of generating patient-matched RPE cells for treatment of macular degeneration. Expression analysis was performed on induced retinal pigment epithelium-like cells.

Project description:Human retina and RPE/choroid from healthy and age-related macular degeneration donors

Project description:Background: Age-related macular degeneration (AMD) is caused by the degeneration of the macular photoreceptors. This is preceded by development of subretinal protein aggregates (drusen) and degeneration of the macular retinal pigment epithelium (RPE). The underlying pathogenesis remains unknown, but the immune system is suspected to play a key role in it. Aging of the immune system, immunosenescence, includes changes in T cell sub-populations and results in low-level chronic inflammation. Because AMD exclusively occurs in patients over 55 years of age, we hypothesize that aging of the T cell compartment may be implicated in AMD pathogenesis. Methodology and principal findings: Using an in vitro co-culture system, we investigated the effects of activated T cells on a human RPE cell line (ARPE-19). Differential gene expression in the RPE cells of complement factor genes was identified using microarrays, and selected gene transcripts from the alternative complement pathway were validated by q-RT-PCR. Protein expression was determined by ELISA and immunoblotting. Co-culture with activated T cells increased RPE mRNA and protein expression of complement component C3, factors B, H, H-like 1, CD46, CD59, and clusterin, in a dose-dependent manner. Conclusions: RPE cells responded to inflammatory assault caused by exposure to T cell-derived cytokines by upregulating expression of many complement factors from the alternative pathway. This may have implications for RPE ability to deal with complement attack, and opsonization and removal of debris from the RPE-choroidal interface. We speculate that regulation of the complement system in response to inflammatory assault may play a vital role in RPE pathology and drusen biogenesis. Experiment Overall Design: 10 samples investigating variations of co-cultures of RPE cells and T-cells. Variable parameters include the cell type, the co-culturing of the counter-part cell type and the orientation of the system (apical vs basolateral).

Project description:We assessed the feasibility of transplanting a sheet of retinal pigment epithelial (RPE) cells differentiated from induced pluripotent stem cells (iPSCs) in a patient with neovascular age-related macular degeneration. The iPSCs were generated from skin fibroblasts obtained from two patients with advanced neovascular age-related macular degeneration and were differentiated into RPE cells. The RPE cells and the iPSCs from which they were derived were subject to extensive testing. A surgery that included the removal of the neovascular membrane and transplantation of the autologous iPSC-derived RPE cell sheet under the retina was performed in one of the patients.

Project description:We assessed the feasibility of transplanting a sheet of retinal pigment epithelial (RPE) cells differentiated from induced pluripotent stem cells (iPSCs) in a patient with neovascular age-related macular degeneration. The iPSCs were generated from skin fibroblasts obtained from two patients with advanced neovascular age-related macular degeneration and were differentiated into RPE cells. The RPE cells and the iPSCs from which they were derived were subject to extensive testing. A surgery that included the removal of the neovascular membrane and transplantation of the autologous iPSC-derived RPE cell sheet under the retina was performed in one of the patients. At 1 year after surgery, the transplanted sheet remained intact, best corrected visual acuity had not improved or worsened, and cystoid macular edema was present.