Project description:Purpose: The present study compares the transcriptional profiles of human hyalo-cytes, retinal microglia as well as classical, intermediate and non-classical mono-cytes in a pairwise analysis. Methods: Using fluorescence-activated cell sorting, hyalocytes and retinal microglia were isolated from the vitreous or retinal tissue of enucleated eyes due to melano-ma of the iris, ciliary body or choroid. In addition, classical, intermediate and non-classical monocytes were isolated from whole blood. RNA sequencing was per-formed and the transcriptional profiles of all five immune cell populations were ana-lyzed using bioinformatic analysis. Results: Pairwise analysis indicated distinct differences between hyalocytes and all three subsets of monocytes, whereas a high degree of similarity was apparent when compared to retinal microglia, with comparable expression levels of established MG markers such asTREM2, P2RY12 and TMEM119. Cluster analysis based on signa-ture genes of yolk sac-derived cells as well as hematopoietic stem and progenitor cells indicated that in contrast to monocytes, human hyalocytes and retinal microglia share a common origin in the yolk sac. Among the top expressed genes in hyalo-cytes, SPP1, CD74 and C3 were significantly upregulated when compared to mon-ocytes. Despite the high level of similarity, genes such as TNF, CCL3 and CXCL8 were significantly upregulated in hyalocytes when compared to retinal microglia. In addition, ten hyalocyte-specific genes were identified, among them FOS, DUSP1 and EGR2. Conclusions: This study provides detailed insights into the molecular profile of iso-lated human hyalocytes and, for the first time, human retinal microglia. The expres-sion profile of hyalocytes is similar to that of retinal microglia and indicates that hy-alocytes are, contrary to the prevailing notion, yolk sac-derived cells. The hyalocyte-specific markers identified in this study will contribute in the future to deciphering the different roles of this fascinating cell population in health and diseases of the vitre-oretinal interface.

Project description:Age-related macular degeneration (AMD) is a leading cause of vision loss, with its dry form characterized by retinal pigment epithelium (RPE) degeneration and photoreceptor loss. However, the underlying mechanisms driving these pathological changes remain poorly understood. Here, we identify a critical role for microglia-RPE cell interactions mediated by the SPP1-ITGAV signaling axis in dry AMD pathogenesis.

Project description:Neovascular age-related macular degeneration represents the most common cause of blindness in the western world. Alterations of the outer Blood-retina barrier integrity and a localized inflammatory microenvironment lead to sprouting of choroidal neovascularization in intimate contact with surrounding myeloid cells and ultimately lead to visual impairment. The discovery of novel targets interfering with angiogenesis and inflammation is vital for the future treatments in AMD patients. To identify novel potential targets in the local phagocytes of the retina, microglia, we performed a comprehensive RNA-seq analysis in the mouse model of laser-induced choroidal neovascularization (mCNV). Here, we identified the angiogenic factor Osteopontin (Opn), also known as "secreted phosphoprotein 1” (Spp1), to be one of the most highly expressed genes in retinal microglia in the course of CNV formation. We could confirm the presence of SPP1 at the lesion site in recruited retinal microglia of Cx3cr1CreER:Rosa26-Tomato reporter mice using immunohistochemistry and in whole retinal tissue lysates by ELISA compared to controls highlighting a massive local production of SPP1. Inhibition of SPP1 by intravitreal injection of anti-SPP1 antibody significantly increased the lesion size compared to IgG-treated control eyes. In line with the results in rodents, we found an increased SPP1 mRNA expression in surgically extracted human choroidal neovascular (hCNV) membranes by the quantitative RNA-seq approach of massive analysis of cDNA ends (MACE) and found numerous IBA1+SPP1+ myeloid cells in human CNV membranes. Taken together, these results highlight the importance of SPP1 in the formation of CNV and potentially offer new opportunities for therapeutic intervention by inhibiting the SPP1 pathway.

Project description:To understand the functional relationship between brain dendritic cells (brain DCs) and other myeloid cells, we compared the gene expression profile of m/chDCs to that of bone marrow monocytes, brain microglia and classical spleen CD8+ and CD8- DCs. In order to obtain enough brain DCs for mRNA extraction, we expanded brain DCs with in vivo Flt3L treatment before purification. This study includes data from FACs Aria-purified brain DCs, bone marrow monocytes, brain microglia and classical spleen CD8+ and CD8- DCs. The genearray was performed to compare expression of cell surface endocytic receptor, cytokine receptors, TLRs, transcription factors, molecules for antigen processing and presentation. Each Series consists of 3 individuall samples

Project description:Dysfunctional humoral and cellular innate immunity are key components in the development and progression of age-related macular degeneration (AMD). Specifically, chronically activated microglia and their disturbed regulatory system contribute to retinal degeneration. Galectin-3, a b-galactose binding protein, is a potent driver of macrophage and microglia activation and has been implicated in neuroinflammation, including neurodegenerative diseases of the brain. Here, we report that galectin-3 is strongly upregulated in reactive retinal microglia of AMD patients and in two related mouse models of retinal degeneration. Specific targeting of galectin-3 by genetic knockout or using the small-molecule inhibitor TD139 blocks microglia reactivity and protects from retinal damage in different models of light-induced retinal degeneration. These data define galectin-3 as potent driver of retinal degeneration and highlight the protein as a drug target for ocular immunomodulatory therapies.

Project description:Background Age-related macular degeneration (AMD) is the leading cause of irreversible blindness in the elderly population worldwide. Recent studies have demonstrated strong genetic associations between AMD and single nucleotide polymorphisms (SNPs) within genes such as CFH and HTRA1. However, we have identified monozygotic twins discordant for AMD phenotypes (one with disease, the other without disease), suggesting that an epigenetic mechanism may also contribute to the pathogenesis of AMD. Methods We identified two twin pairs with phenotypic discordance of AMD. We obtained genomic DNA from their peripheral blood mononuclear cells (PBMCs) and subjected them to DNA methylation-chip analysis (MeDIP-chip) that profiled genome-wide DNA methylation patterns on promoters of all genes and microRNAs. We next utilized the Methyl-Profiler DNA methylation assays to detect the methylation status of selected promoters. Flow cytometry and quantitative real-time PCR were used to detect the expression of the selected gene in peripheral blood cells, as well as in retinal and choroidal tissues of AMD patients and non-AMD controls. Results Our MeDIP-chip analysis identified 256 genes with hypo-methylated promoters only in the twins with AMD and 744 genes with hyper-methylated promoters only in the twins with AMD. Importantly, the promoter region of IL17RC was associated with hypo-methylated CpG sites only in the twins with AMD but not in the twins without AMD. We also found the association of the hypo-methylated IL17RC promoter with AMD in 7 pairs of siblings with discordant AMD pathology (P=0.003), as well as an independent patient cohort (95 neovascular wet and 107 geographic atrophy dry AMD patients as well as 96 non-AMD controls (95% CI, 0.01-0.10, P=9.8x10-8 for wet AMD vs. control; 95% CI, 0.05-0.32, P=2.2x10-5 for dry AMD vs. control)). Interestingly, we did not find an association between the levels of methylation on the IL17RC promoter with the previously identified genetic risk alleles in CFH, HTRA1, and ARMS2. We demonstrated an elevated expression of the IL-17RC protein in CD14+ monocytes in the peripheral blood of AMD patients as compared to non-AMD controls. These IL-17RC+ monocytes have elevated expression of CXCR1, CXCR2, and CXCR4. In addition, IL17RC was expressed only in the retinal and choroidal tissues from AMD patients but not from age-matched controls. Conclusions We show an association of the hypo-methylated IL17RC promoter with AMD, which resulted in the elevated expression of IL-17RC in peripheral blood cells as well as the retinal and choroidal tissues of AMD patients. Our study suggests that the hypo-methylated IL17RC promoter and elevated expression of IL-17RC can potentially serve as biomarkers for the diagnosis of AMD, while IL-17RC can be a new therapeutic target for AMD. In addition, our results strongly suggest an epigenetic control mechanism of AMD pathogenesis. The Affymetrix MOE430 2.0 GeneChip was used to detect gene expression patterns within the whole eye of C57B/6 normal mice.

Project description:Neovascular AMD (nAMD) causes vision loss from destructive angiogenesis, termed choroidal neovascularization (CNV). Cx3cr1-/- mice display non-classical monocyte and microglia alterations, and increased CNV size, suggesting that non-classical monocytes may inhibit CNV formation. While Nr4a1-/- mice are deficient in non-classical monocytes, results are confounded by macrophage hyper-activation. Nr4a1se2/se2 mice lack a transcriptional activator, resulting in non-classical monocyte loss, without macrophage hyper-activation. We subjected Nr4a1-/- and Nr4a1se2/se2 mice to the laser-induced CNV model and performed multi-parameter flow cytometry. We found that both models lack non-classical monocytes, but only Nr4a1-/- mice displayed increased CNV area. Additionally, CD11c+ macrophages were increased in Nr4a1-/- mice. Single-cell transcriptomic analysis uncovered that CD11c+ macrophages were enriched from Nr4a1-/- mice and expressed a pro-angiogenic transcriptomic profile that was disparate from prior reports of macrophage hyper-activation. These results suggest that non-classical monocytes are dispensable during laser-induced CNV, and NR4A1 deficiency shifts the transcriptional profile toward a pro-angiogenic phenotype.

Project description:Background Age-related macular degeneration (AMD) is the leading cause of irreversible blindness in the elderly population worldwide. Recent studies have demonstrated strong genetic associations between AMD and single nucleotide polymorphisms (SNPs) within genes such as CFH and HTRA1. However, we have identified monozygotic twins discordant for AMD phenotypes (one with disease, the other without disease), suggesting that an epigenetic mechanism may also contribute to the pathogenesis of AMD. Methods We identified two twin pairs with phenotypic discordance of AMD. We obtained genomic DNA from their peripheral blood mononuclear cells (PBMCs) and subjected them to DNA methylation-chip analysis (MeDIP-chip) that profiled genome-wide DNA methylation patterns on promoters of all genes and microRNAs. We next utilized the Methyl-Profiler DNA methylation assays to detect the methylation status of selected promoters. Flow cytometry and quantitative real-time PCR were used to detect the expression of the selected gene in peripheral blood cells, as well as in retinal and choroidal tissues of AMD patients and non-AMD controls. Results Our MeDIP-chip analysis identified 256 genes with hypo-methylated promoters only in the twins with AMD and 744 genes with hyper-methylated promoters only in the twins with AMD. Importantly, the promoter region of IL17RC was associated with hypo-methylated CpG sites only in the twins with AMD but not in the twins without AMD. We also found the association of the hypo-methylated IL17RC promoter with AMD in 7 pairs of siblings with discordant AMD pathology (P=0.003), as well as an independent patient cohort (95 neovascular wet and 107 geographic atrophy dry AMD patients as well as 96 non-AMD controls (95% CI, 0.01-0.10, P=9.8x10-8 for wet AMD vs. control; 95% CI, 0.05-0.32, P=2.2x10-5 for dry AMD vs. control)). Interestingly, we did not find an association between the levels of methylation on the IL17RC promoter with the previously identified genetic risk alleles in CFH, HTRA1, and ARMS2. We demonstrated an elevated expression of the IL-17RC protein in CD14+ monocytes in the peripheral blood of AMD patients as compared to non-AMD controls. These IL-17RC+ monocytes have elevated expression of CXCR1, CXCR2, and CXCR4. In addition, IL17RC was expressed only in the retinal and choroidal tissues from AMD patients but not from age-matched controls. Conclusions We show an association of the hypo-methylated IL17RC promoter with AMD, which resulted in the elevated expression of IL-17RC in peripheral blood cells as well as the retinal and choroidal tissues of AMD patients. Our study suggests that the hypo-methylated IL17RC promoter and elevated expression of IL-17RC can potentially serve as biomarkers for the diagnosis of AMD, while IL-17RC can be a new therapeutic target for AMD. In addition, our results strongly suggest an epigenetic control mechanism of AMD pathogenesis.

Project description:Microglia-RPE Cell Communication via the SPP1-ITGAV Axis Drives EMT and Retinal Degeneration in Dry AMD

Project description:To understand the functional relationship between brain dendritic cells (brain DCs) and other myeloid cells, we compared the gene expression profile of m/chDCs to that of bone marrow monocytes, brain microglia and classical spleen CD8+ and CD8- DCs. In order to obtain enough brain DCs for mRNA extraction, we expanded brain DCs with in vivo Flt3L treatment before purification.