Project description:Chromatin organization and enhancer-promoter contacts are critical for establishing unique spatiotemporal gene expression patterns in distinct cell types. Non-coding genetic variants can influence cellular phenotypes by modifying higher-order transcriptional hubs and consequently gene expression. To elucidate transcriptional regulation by non-coding genome in human retina, we mapped chromatin contacts at high resolution and integrated this data with histone marks and super-enhancers (SEs). Retinal SEs exhibited abundant local interactions and reside in topologically associated domains (TADs) with weak boundary insulation. Notably, intra-TAD positioning of SEs correlated with the biological function of their target genes in the retina. We also identified regulatory landscapes of retinopathy genes and uncovered candidate genes for risk variants associated with age-related macular degeneration and glaucoma. Our studies of high-resolution genomic architecture of the human retina provide new insights into genetic control of tissue-specific functions, suggest paradigms for missing heritability, and enable the dissection of multifactorial disease phenotypes.

Project description:Chromatin organization and enhancer-promoter contacts are critical for establishing unique spatiotemporal gene expression patterns in distinct cell types. Non-coding genetic variants can influence cellular phenotypes by modifying higher-order transcriptional hubs and consequently gene expression. To elucidate transcriptional regulation by non-coding genome in human retina, we mapped chromatin contacts at high resolution and integrated this data with histone marks and super-enhancers (SEs). Retinal SEs exhibited abundant local interactions and reside in topologically associated domains (TADs) with weak boundary insulation. Notably, intra-TAD positioning of SEs correlated with the biological function of their target genes in the retina. We also identified regulatory landscapes of retinopathy genes and uncovered candidate genes for risk variants associated with age-related macular degeneration and glaucoma. Our studies of high-resolution genomic architecture of the human retina provide new insights into genetic control of tissue-specific functions, suggest paradigms for missing heritability, and enable the dissection of multifactorial disease phenotypes.

Project description:This SuperSeries is composed of the SubSeries listed below. We have generated high-resolution Hi-C map of developing human retinal organoids to elucidate spatiotemporal dynamics of genomic architecture and its relationship with gene expression patterns. We demonstrate progressive and developmental stage-specific alterations in DNA topology and correlate these changes with transcription of cell type-restricted gene markers during retinal differentiation. Temporal Hi-C reveals a shift towards A compartment for protein-coding genes and B compartment for non-coding RNAs, displaying high and low expression respectively. Notably, retina-enriched genes are clustered near lost boundaries of topologically associated domains (TADs), and higher-order assemblages of TADs (i.e., TAD cliques) tend to localize in the active chromatin regions with binding sites for eye-field transcription factors. These genes show a gain of chromatin contacts at their transcription start site as organoid differentiation proceeds. Our study provides a global view of chromatin architecture dynamics associated with diversification of cell types during retinal development and serves as a foundational resource for in-depth functional investigations of retinal developmental traits.

Project description:We have generated high-resolution Hi-C map of developing human retinal organoids to elucidate spatiotemporal dynamics of genomic architecture and its relationship with gene expression patterns. We demonstrate progressive and developmental stage-specific alterations in DNA topology and correlate these changes with transcription of cell type-restricted gene markers during retinal differentiation. Temporal Hi-C reveals a shift towards A compartment for protein-coding genes and B compartment for non-coding RNAs, displaying high and low expression respectively. Notably, retina-enriched genes are clustered near lost boundaries of topologically associated domains (TADs), and higher-order assemblages of TADs (i.e., TAD cliques) tend to localize in the active chromatin regions with binding sites for eye-field transcription factors. These genes show a gain of chromatin contacts at their transcription start site as organoid differentiation proceeds. Our study provides a global view of chromatin architecture dynamics associated with diversification of cell types during retinal development and serves as a foundational resource for in-depth functional investigations of retinal developmental traits.

Project description:We have generated high-resolution Hi-C map of developing human retinal organoids to elucidate spatiotemporal dynamics of genomic architecture and its relationship with gene expression patterns. We demonstrate progressive and developmental stage-specific alterations in DNA topology and correlate these changes with transcription of cell type-restricted gene markers during retinal differentiation. Temporal Hi-C reveals a shift towards A compartment for protein-coding genes and B compartment for non-coding RNAs, displaying high and low expression respectively. Notably, retina-enriched genes are clustered near lost boundaries of topologically associated domains (TADs), and higher-order assemblages of TADs (i.e., TAD cliques) tend to localize in the active chromatin regions with binding sites for eye-field transcription factors. These genes show a gain of chromatin contacts at their transcription start site as organoid differentiation proceeds. Our study provides a global view of chromatin architecture dynamics associated with diversification of cell types during retinal development and serves as a foundational resource for in-depth functional investigations of retinal developmental traits.

Project description:Retinal ganglion cell (RGC) degeneration is a primary characteristic of glaucoma, although non-cell autonomous mechanisms have been implicated in RGC dysfunction. Astrocytes closely associate with RGCs in the nerve fiber layer of the retina and optic nerve, where they can contribute to RGC neurodegeneration. However, the mechanisms by which astrocytes promote neurotoxicity and contribute to glaucoma remain unclear. Here we present data describing disease phenotypes in astrocytes and their ability to modulate RGC health.

Project description:Goals of the study: 1. Assess the gene expression profile in rat RGC after experimental IOP elevation to elucidate the molecular mechanisms of RGC death. 2. Identify potentially novel genes and pathways that may contribute to RGC death in glaucoma. Background: Glaucoma is a neurodegenerative disease characterized by the slow, progressive degeneration of RGC. Elevated IOP is the biggest risk factor for developing glaucoma, loss of RGC and optic nerve atrophy. The pathophysiology of glaucomatous neurodegeneration is not fully understood. It is now clear that RGC die by apoptosis in glaucoma. However, what triggers the apoptosis is still unknown. So far, several gene expression studies have been performed on the retina as a whole. These studies revealed up and downregulation of many genes in response to elevated IOP and optic nerve transection. However, the retina is a complex tissue composed of neuronal, glial and vascular cell types. The RGCs only comprise 5% or less of retinal cells. The gene expression profiles from whole retina can not represent of RGC gene expression. In the current study, we sought to investigate the whole genome regulation of the RGCs in glaucoma. The study was carried out in 3 adult male Brown Norway rats with experimental glaucoma. An equal number of RGCs were captured from normal eyes and eyes with elevated IOP. Gene expression in the glaucomatous RGC was compared with that in the fellow RGC by using Affymetrix Gene chip.

Project description:For a eukaryotic genome to properly function, its chromatin must be precisely organized, as genome topology impacts transcriptional regulation, cell division, DNA replication, and DNA repair, among other essential processes. Disruption of human genome topology can lead to disease states, such as cancer. The advent of chromosome conformation capture with high-throughput sequencing (Hi-C) technologies to assess genome organization has revolutionized our understanding of the arrangement of chromosomes within the nuclear genome. Critical developments include chromosomal territories, active/silent chromatin compartments, Topologically Associated Domains (TADs), and chromatin loops. However, to fully elucidate folding principles at the gene level, Hi-C datasets at an extremely high resolution are required: while low resolution (e.g., 40 kb bin) heatmaps can provide important insights into chromosomal level contacts, lower resolution datasets cannot provide information about individual gene or promoter contacts. Thus, high-resolution Hi-C datasets can elucidate principles of folding, including those of model organisms whose chromosome conformation can elucidate the folding of the human genome. Here, we have examined the high-resolution genome topology of the model fungal organism Neurospora crassa: our composite Hi-C dataset, generated using two restriction enzymes to monitor euchromatin (DpnII) and heterochromatin (MseI), provides exquisite detail for both larger chromosomal structures and individual gene contacts, including how repressed euchromatic genes associate with constitutive heterochromatic regions. Our high-resolution Neurospora Hi-C datasets should be an outstanding resource to the fungal community and provide valuable insights to the folding of higher organism genomes.

Project description:Dogs frequently develop glaucoma, a disease that leads to vision loss due to loss of retinal ganglion cells and degeneration of axons within the optic nerve. We used Affymetrix Gene chips to characterize transcriptional changes between healthy and glaucomatous retinas. These data describe gene expression changes in the canine retina with glaucoma. RNA was isolated from the retinas of 5 dogs with advanced glaucoma and from 5 normal individuals.

Project description:The mammalian central nervous system (CNS) and its retina are susceptible to age-related patholgoies, resulting in progressive, irreversible diseases like glaucoma and age-related macular degeneration (AMD), which are increasingly prevalent with rising life expectancy. Currently, there are no targeted long-term therapies to prevent vision loss. The short lived African turquoise killifsh (Nothobranchius furzeri, GRZ-AD) is a valuable genetic model for ageing studies, displaying rapid ageing phenotypes within its four to six-month lifespan. Our investigation on the molecular consequences of ageing in the retina, employing scRNA-sequencing, shows a a comprehensive overview of the cellular heterogeneity of the killifish retina, uncovering age-related gene expression changes specific to certain retinal cell populations.