Project description:MicroRNA expression in the mouse eye.MicroRNAs (miRNAs) are key regulators of biological processes. To define miRNA function in the eye, it is essential to determine a high-resolution profile of their spatial and temporal distribution. In this report, we present the first comprehensive survey of miRNA expression in ocular tissues, using both microarray and RNA in situ hybridization (ISH) procedures. We initially determined the expression profiles of miRNAs in the retina, lens, cornea and retinal pigment epithelium of the adult mouse eye by microarray. Each tissue exhibited notably distinct miRNA enrichment patterns and cluster analysis identified groups of miRNAs that showed predominant expression in specific ocular tissues or combinations of them. Next, we performed RNA ISH for over 220 miRNAs, including those showing the highest expression levels by microarray, and generated a high-resolution expression atlas of miRNAs in the developing and adult wild-type mouse eye, which is accessible in the form of a publicly available web database. We found that 122 miRNAs displayed restricted expression domains in the eye at different developmental stages, with the majority of them expressed in one or more cell layers of the neural retina . This analysis revealed miRNAs with differential expression in ocular tissues and provided a detailed atlas of their tissue-specific distribution during development of the murine eye. The combination of the two approaches offers a valuable resource to decipher the contributions of specific miRNAs and miRNA clusters to the development of distinct ocular structures. microRNA profiling of ocular tissues from mouse. In particular we analysed the cornea, lens, Retina Pigment Epithelium (RPE) and retina and compared them against RNA extracted from the entire eye. The purpose of this experiment was to understand which microRNAs are present nd/or show differential expression in the various structures of the eye (cornea, lens, RPE, retina). The samples numbered 1 & 2 (i.e. CORNEA1, CORNEA2 etc ) are biological replicates, prepared from tissues dissecyed from different groups of wild-type animals. RNA extracted from the entire eye (EYE) served as the unique reference sample. For each tissue to be analysed we performed the following hybridizations: - 2 slides for lens (LENS1, LENS2) vs entire eye (EYE) - 2 slides for RPE (RPE1, RPE2) vs entire eye (EYE) - 2 slides for retina (RETINA1, RETINA2) vs entire eye (EYE) - 2 slides for cornea (CORNEA1, CORNEA2) vs entire eye (EYE) - 1 slide for entire eye (EYE) vs entire eye (EYE)

Project description:I. Exp Design 1. Type of experiment: Comparison of native versus cultured RPE cells 2. Experimental factors: Native RPE versus ARPE-19 cells grown on different matrices 3. How many hybridizations in exp: 21 4. If a common reference used for all the hybs: no 5. Quality control steps: three independent arrays for each condition 6. Description: The expression profile of ARPE-19 cells grown on different matrices were compared to morphologically normal native macular RPE cells that were laser capture microdissected from 3 donors. II. Samples used, extract prep, and labeling 1. Biosource: Human donor globes from NDRI (63, 71, 74 years old) and ARPE-19 cells. 2. Manipulations: Human donor globes were cryopreserved, and morphologically normal RPE cells from the macula were laser capture micodissected. ARPE-19 cells were grown on different matrices (plastic, Matrigel, collagen I, collagen IV, laminin, and fibronectin). 3. Extract preparation: Total RNA from cells were extracted with the RNeasy kit (Qiagen) using the manufacturer’s instructions. 4. Labeling protocol: Total RNA from cells was reverse transcribed with 33P-dCTP and 33P-dATP, and second strand cDNA was labeled with 33P-dCTP and 33P-dATP. 5. No external controls were added. III. Hybridization procedures and parameters 1. Sample, array type, batch and serial # used 2. Hybridization protocol: Hybridization was carried out using the manufacturer’s recommendations. Arrays were prehybridized with Microhyb solution containing denatured Cot-1 DNA and poly dA at 42oC for two hours. Hybridization was carried out at 42oC overnight using a hybridization oven set at 8-10 rpm. Arrays were washed twice at 50oC for 20 minutes using 2x SSC, 1%SDS and once at room temperature for 15 minutes using 0.5x SSC, 1%SDS. IV. Measurement data and specifications of data processing 1,2. Arrays were exposed to a phosphorimaging screen for 3 days and scanned at 50 mm resolution with a BioRad FX Pro-Plus phosphorimager. TIFF images from the phosphorimager were exported into ResGen Pathways 3 software for analysis. 3. Data processing: A gene was expressed if its background subtracted intensity was greater than 1.4 fold background. The data were normalized using a simple global scaling procedure, and Cluster/Treeview and Statistical Analysis of Microarrays (SAM version 1.12) programs were used for analysis.

Project description:Eye development and photoreceptor maintenance requires the retinal pigment epithelium (RPE), a thin layer of cells that underlies the neural retina. Despite its importance, RPE development has not been studied by a genomic approach. A microarray expression profiling methodology was established in this study for studying RPE development. The intact retina with RPE attached was dissected from developing embryos, and differentially expressed genes in RPE were inferred by comparing the dissected tissues with retinas without RPE using microarray and statistical analyses. We found 8810 probesets to be significantly expressed in RPE at 52 hours post-fertilization (hpf), of which 1443 might have biologically meaningful expression levels. Further, 78 and 988 probesets were found to be significantly over- or under-expressed in RPE respectively compared to retina. Also, 79.2% (38/48) of the known over-expressed probesets have been independently validated as RPE-related transcripts. The results strongly suggest that this methodology can obtain in vivo RPE specific gene expression from the zebrafish embryos and identify novel RPE markers. Experiment Overall Design: The gene expression levels of three independent replicates of retina with RPE attached consisting of ten samples each at 52hpf (WRR52) were compared with three independent pure retinal samples consisting of ten retinas each at 52hpf (WR52). The yield-adjusted WR52 expression values were assumed to be equivalent to the retinal contribution in WRR52 samples and deducted from WRR52 expression values to obtain estimations of RPE gene expression at 52hpf (RPE52). Differential gene expressions between RPE and retina were inferred by comparing the RPE52 estimates and WR52 expression values.

Project description:I. Exp Design 1. Type of experiment: Comparison of native versus cultured RPE cells 2. Experimental factors: Native RPE versus ARPE-19 cells grown on different matrices 3. How many hybridizations in exp: 21 4. If a common reference used for all the hybs: no 5. Quality control steps: three independent arrays for each condition 6. Description: The expression profile of ARPE-19 cells grown on different matrices were compared to morphologically normal native macular RPE cells that were laser capture microdissected from 3 donors. II. Samples used, extract prep, and labeling 1. Biosource: Human donor globes from NDRI (63, 71, 74 years old) and ARPE-19 cells. 2. Manipulations: Human donor globes were cryopreserved, and morphologically normal RPE cells from the macula were laser capture micodissected. ARPE-19 cells were grown on different matrices (plastic, Matrigel, collagen I, collagen IV, laminin, and fibronectin). 3. Extract preparation: Total RNA from cells were extracted with the RNeasy kit (Qiagen) using the manufacturer’s instructions. 4. Labeling protocol: Total RNA from cells was reverse transcribed with 33P-dCTP and 33P-dATP, and second strand cDNA was labeled with 33P-dCTP and 33P-dATP. 5. No external controls were added. III. Hybridization procedures and parameters 1. Sample, array type, batch and serial # used 2. Hybridization protocol: Hybridization was carried out using the manufacturer’s recommendations. Arrays were prehybridized with Microhyb solution containing denatured Cot-1 DNA and poly dA at 42oC for two hours. Hybridization was carried out at 42oC overnight using a hybridization oven set at 8-10 rpm. Arrays were washed twice at 50oC for 20 minutes using 2x SSC, 1%SDS and once at room temperature for 15 minutes using 0.5x SSC, 1%SDS. IV. Measurement data and specifications of data processing 1,2. Arrays were exposed to a phosphorimaging screen for 3 days and scanned at 50 mm resolution with a BioRad FX Pro-Plus phosphorimager. TIFF images from the phosphorimager were exported into ResGen Pathways 3 software for analysis. 3. Data processing: A gene was expressed if its background subtracted intensity was greater than 1.4 fold background. The data were normalized using a simple global scaling procedure, and Cluster/Treeview and Statistical Analysis of Microarrays (SAM version 1.12) programs were used for analysis. Keywords: other

Project description:The retinal pigment epithelium (RPE) is a monolayer of polarized epithelial cells lying between the retina and the choroid/sclera, with a major function in supporting photoreceptor homeostasis, but the role of RPE in eye size regulation is yet to be further explored. it was recently reported that selective deletion of Low density lipoprotein receptor-related protein 2 (Lrp2) in the mouse RPE resulted in large eyes, similar to the phenotypes of Lrp2 whole eye knockout mice, suggesting that the RPE is the tissue in which LRP2 functions. Here, to investigate which downstream pathways of Srebp2 and Lrp2 are responsible for regulating eye growth, we performed RNA-seq analysis with the mouse RPE tissues. Postnatal day 0 (P0) mice were injected with AAV8-Best1-GFP/nSrebp2/ctrl sh/Lrp2 sh1/Lrp2 sh2 viruses to overexpress the constitutively active form of Srebp2 or to knockdown Lrp2 in the RPE specifically. At P14, RPE cells were carefully dissociated for RNA extraction. Via RNA-seq analysis and functional validation, we identified that Bmp2 is the target and the effector of the Srebp2-Lrp2 pathway. Overall, the present study unveils an essential role of RPE in regulating eye size via the Srebp2-Lrp2-Bmp2 signaling pathway, shedding light on the underlying mechanism of eye size control.

Project description:Eye development and photoreceptor maintenance requires the retinal pigment epithelium (RPE), a thin layer of cells that underlies the neural retina. Despite its importance, RPE development has not been studied by a genomic approach. A microarray expression profiling methodology was established in this study for studying RPE development. The intact retina with RPE attached was dissected from developing embryos, and differentially expressed genes in RPE were inferred by comparing the dissected tissues with retinas without RPE using microarray and statistical analyses. We found 8810 probesets to be significantly expressed in RPE at 52 hours post-fertilization (hpf), of which 1443 might have biologically meaningful expression levels. Further, 78 and 988 probesets were found to be significantly over- or under-expressed in RPE respectively compared to retina. Also, 79.2% (38/48) of the known over-expressed probesets have been independently validated as RPE-related transcripts. The results strongly suggest that this methodology can obtain in vivo RPE specific gene expression from the zebrafish embryos and identify novel RPE markers. Keywords: Development, retina, retinal pigment epithelium

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 evaluate whether human induced pluripotent stem cell-derived retinal pigment epithelium (iPSC-RPE) cells can be used to prioritize and functionally characterize causal variants at age-related macular degeneration (AMD) risk loci. We generated iPSC-RPE from six subjects and show that they have morphological and molecular characteristics similar to native RPE. We generated RNA-seq, ATAC-seq, and H3K27ac ChIP-seq data and observe high similarity in gene expression and enriched transcription factor motif profiles between iPSC-RPE and human fetal-RPE. We performed fine-mapping of AMD risk loci by integrating molecular data from the iPSC-RPE, adult retina, and adult RPE, which identified rs943080 as the probable causal variant at VEGFA. We show that rs943080 is associated with altered chromatin accessibility of a distal ATAC-seq peak, decreased overall gene expression of VEGFA, and allele specific expression of a non-coding transcript. These results provide insight into the mechanism underlying the association of the VEGFA locus with AMD. Raw data requires controlled access and is deposited at dbGaP http://www.ncbi.nlm.nih.gov/gap/?term=phs000924

Project description:The iris is a fine structure that controls the amount of light that enters the eye. The ciliary body controls the shape of the lens and produces aqueous humor. The retinal pigment epithelium and choroid (RPE/choroid) are essential in supporting the retina and absorbing light energy that enters the eye. Proteins were extracted from iris, ciliary body, and RPE/choroid tissues of eyes from five individuals and fractionated using SDS-PAGE. After in-gel digestion, peptides were analyzed using LC-MS/MS on an Orbitrap Elite mass spectrometer. In iris, ciliary body, and RPE/choroid, we identified 2,959, 2,867, and 2,755 non-redundant proteins with protein false positive rate <1%. There were 43 unambiguous protein isoforms identified in iris, ciliary body, and RPE/choroid. Four “missing proteins” were found in ciliary body. The MS proteome database of the human iris, ciliary body, and RPE/choroid may serve as a valuable resource for future investigations of the eye in health and disease. The mass spectrometry proteomics data have been deposited to the ProteomeXchange Consortium via the PRIDE partner repository with the dataset identifier PXD001424.

Project description:Retinal pigmented epithelium (RPE) has essential functions to nourish and support the neural retina, and is of vital importance in the pathogenesis of age-related retinal degeneration. However, the exact molecular changes of RPE in aging remain poorly defined. We isolated human primary RPE (hRPE) cells from 18 eye donors distributed over a wide age range (10 - 67 years). A quantitative proteomic analysis was performed to analyze their intracellular and secreted protein changes. Age-stage related subtypes and age-associtated proteins were revealed and potential age-associtated mechanisms were validated by ARPE-19 and hRPE cells. Proteomic data and verifications showed that RNF123 and RNF149 related ubiquitin-mediated proteolysis might be an important clearance mechanism in elimination of oxidative damaged proteins in aged hRPE. In older hRPE cells, apoptotic signaling related pathways were up-regulated and endoplasmic reticulum organization was down-regulated both in intracellular and secreted proteome. Our work paints a detailed molecular picture of human RPE in aging process and provides new insights for molecular characteristics of RPE in aging and related clinical retinal conditions.