Project description:RGC differentiation is tightly controlled by extrinsic and intrinsic factors. Growth and differentiation factor 15 (GDF-15) promotes RGC differentiation, opposite to GDF-11 which inhibits RGC differentiation, both in the mouse retina and in human stem cells. To deepen our understanding of how these two closely related molecules confer opposing effects on retinal development, here we assess the transcriptional profiles of mouse retinal progenitors exposed to exogenous GDF-11 or -15. We find a dichotomous effect of GDF-15 on RGC differentiation, decreasing RGCs expressing residual pro-proliferative genes and increasing RGCs expressing non-proliferative genes, suggestive of greater RGC maturation. Furthermore, GDF-11 promoted the differentiation of photoreceptors and amacrine cells. These data enhance our understanding of the mechanisms underlying the differentiation of RGCs and photoreceptors from retinal progenitors and suggest new approaches to the optimization of protocols for the differentiation of these cell types.

Project description:The failure of adult CNS neurons to survive and regenerate their axons after injury or in neurodegenerative disease remains a major target for basic and clinical neuroscience. Recent data demonstrated in the adult mouse that exogenous expression of Sry-related high-mobility-box 11 (Sox11) promotes optic nerve regeneration after optic nerve injury, but exacerbates the death of a subset of retinal ganglion cells, alpha-RGCs. During development, Sox11 is required for RGC differentiation from retinal progenitor cells (RPCs), and we found that mutation of a single residue to prevent sumoylation at K91 increased nuclear localization and RGC differentiation in vitro. Here we explored whether this Sox11 manipulation similarly has stronger effects on RGC survival and optic nerve regeneration. In vitro, we found that non-SUMOylatable Sox11 K91A leads to RGC death and suppresses axon outgrowth in primary neurons. We furthermore found that Sox11 K91A more strongly promotes axon regeneration but also increases RGC death after optic nerve injury in vivo in adult mouse. RNA-seq data showed that Sox11 and Sox11 K91A increase the expression of key signaling pathway genes associated with axon growth and regeneration but downregulated Spp1 and Opn4 expression in RGC cultures, consistent with negatively regulating the survival of α-RGCs and ipRGCs. Thus Sox11 and its sumoylation site at K91 regulate gene expression, survival and axon growth in RGCs and may be explored further as potential regenerative therapies for optic neuropathy.

Project description:Retinal ganglion cells (RGCs) convey the major output of information collected from the eye to the brain. RGCs are irreversibly lost when injured in degenerative diseases such as glaucoma; this failure can be partially reversed by eliminating the retinal mobile zinc (Zn2+) and leads to substantial axon regeneration. ZnT3 conditional knockout in retinal amacrine cells blocks the synaptic transport of Zn2+, which promotes RGC survival and axonal regeneration in optic nerve jinjury (ONC). Here, we conducted an mRNA sequencing of flow cytometry-isolated RGCs 3 days after optic nerve injury with or without ZnT3 expression in retinal amacrine cells.

Project description:At least 30 types of retinal ganglion cell (RGC) send distinct messages through the optic nerve to the brain. Strategies for promoting regeneration of RGC axons following injury act on only some of these types. Here we tested the hypothesis that over-expressing developmentally important transcription factors in adult RGCs could reprogram them to a “youthful” growth-competent state and promote regeneration of other types. From a screen of transcription factors expressed by developing RGCs, we found one, Sox11, that induced substantial axon regeneration. Transcriptome profiling confirmed that Sox11 activates genes involved in cytoskeletal remodeling and axon growth. Remarkably, alpha-RGCs, which preferentially regenerate following treatments such as PTEN deletion, were killed by Sox 11. Thus, Sox 11 promotes regeneration of non-alpha RGCs, which are refractory to PTEN. We conclude that Sox11 can reprogram adult RGCs to a growth-competent state and that different growth-promoting interventions act on distinct neuronal types.

Project description:Since retinal ganglion cells (RGCs) do not regenerate after injury, RGC replacement therapy could provide an approach to vision restoration in glaucoma and other optic neuropathies. Here we developed a rapid protocol for direct induction of RGC (iRGC) differentiation from human iPSCs and ESCs in less than two weeks, by overexpression of NGN2 in RGC survival-promoting medium supplemented with a Notch inhibitor. Neuronal morphology and neurite growth were observed within one week of induction. Immunostaining and qRT-PCR for characteristic RGC-specific genes confirmed identity. Calcium imaging was used to evaluate iRGCs’ electrophysiologic maturation, and demonstrated GABA-induced excitatory calcium influx characteristic of immature RGCs. Using single cell-RNA sequencing (scRNA-seq) we further delineated iRGCs’ differentiation and compared iRGC transcriptomic profiles to fetal human and retinal organoid-derived RGCs. Unbiased clustering showed high similarities of transcriptomic profiles among iRGCs, early-stage fetal human RGCs and early-stage retinal organoid-derived RGCs. However, for some markers, including BRN3a, BRN3b and NEFL, iRGCs demonstrated expression patterns more similar to fetal RGCs than to retinal organoid RGCs. After intravitreal injection into rodent eyes, transplanted iRGCs survived and migrated into host retinas where they were detected one week and one month after transplant. Prior optic nerve trauma to the recipient host did not significantly enhance or detract from iRGC integration, but iRGCs protected host RGCs from neurodegeneration. Taken together, these data demonstrate rapid iRGC generation in vitro into an immature cell with high similarity to human fetal RGCs and capacity for retinal integration after transplant, including after optic nerve injury. The simplicity of this system may benefit translational studies on human RGCs.

Project description:Retinal ganglion cells (RGCs) are the sole projection neurons that connect the eye with the brain, and the degeneration of these cells in diseases such as glaucoma results in vision loss or blindness. Similar to other neurons throughout the central nervous system, RGCs are postmitotic and therefore highly dependent upon autophagy to remove damaged proteins or organelles to maintain proper cellular homeostasis. Autophagy deficits have been implicated in multiple neurodegenerative diseases including glaucoma. In addition, a subpopulation of glaucoma patients possesses mutations in the autophagy receptor Optineurin (OPTN) resulting glaucoma within a normal range of intraocular pressure, with the OPTN(E50K) mutation known to induce a severe degeneration. Despite this, our knowledge of how autophagy impairment promotes neurodegeneration within RGCs remains limited. We advanced a human pluripotent stem cell (hPSC) model of RGC neurodegeneration with an underlying OPTN(E50K) mutation to study how autophagy disruption contributes to RGC neurodegeneration. We identified OPTN protein was reduced but accumulated within the somas in RGCs with the OPTN(E50K) mutation, and this accumulation was associated with a decrease in autophagic flux. To rule out the possibilities that the specificity of the antibody incapable to recognize E50K region resulting the reduction of OPTN protein, we performed proteomics analysis at week 2 hPSC-RGCs of post purification and identified 154 downregulated proteins as well as 178 upregulated proteins associated with OPTN(E50K) RGCs compared with isogenic controls. Taken together, we identified proteins that were altered by OPTN(E50K) mutation in RGCs, and which may provide potential mechanisms that contribute to RGC neurodegeneration.

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:Retinal ganglion cells (RGCs) are the projection neurons that transmit visual information from the retina to the brain via the optic nerve. A substantial proportion of RGCs are eliminated by programmed cell death during development to regulate their final number, yet how cell death impacts RGC development in human retinas remains poorly understood. Here, we characterized the timing and cell-type-specificity of cell death in human fetal retinas and retinal organoids. We identified two waves of apoptosis: an early wave targeting retinal neuronal precursors and a late wave affecting RGCs and other neurons. In addition to these two waves of apoptosis, organoids displayed a distinct wave of necrosis in the innermost core region that eliminates nearly all RGCs during long-term culture. To investigate the functions of the apoptotic waves during retinal development, we differentiated BAX/BAK double mutant organoids that are deficient for apoptosis. In these mutant organoids, RGC survival was improved, RGC neurogenesis and maturation were delayed, and RGCs were lost through a compensatory increase in necrosis. Our data suggest that the waves of developmental apoptosis promote human RGC neurogenesis and maturation. Together, our results highlight the roles of cell death in human RGC development and the challenges in retinal organoid design. Overcoming these obstacles would improve the utility of retinal organoids for modeling optic neuropathies like glaucoma

Project description:Retinal ganglion cells (RGCs) are the projection neurons of the retina. Proper development of the axon and dendrite of RGCs is the basis for these cells to function as projection neurons to deliver visual information to the brain. The purpose of this study was to investigate the function of a newly identified RGC-specific gene, Shtn1, in neurite development in RGCs. Using IF, we demonstrated that SHTN1 is distinctively expressed in RGCs during the period in which RGCs actively develop and adjust the connections of their neurites with upstream and downstream neurons. Using the iRGC system, we demonstrated that Shtn1 promotes the growth and complexity of neurites, and thus the electrophysiological maturation, of iRGCs. RNA-Seq analyses showed that Shtn1 may also regulate gene expression and neurogenesis in iRGCs. These findings improve our understanding of the molecular machinery governing RGC neurite development, and may help to optimize future RGC regeneration methods.

Project description:In the early stages of retinal development, a form of correlated activity known as retinal waves causes periodic depolarizations of immature retinal ganglion cells (RGCs). Retinal waves are crucial for refining visual maps in the brain's retinofugal targets and for the development of retinal circuits underlying feature detection, such as direction selectivity. Yet, how waves alter gene expression in immature RGCs is poorly understood, particularly at the level of the many distinct types of RGCs that underlie the retina’s ability to encode diverse visual features. We performed single-cell RNA sequencing on RGCs isolated at the end of the first postnatal week from wild-type (WT) mice and β2KO mice, which lack the β2 subunit of the nicotinic acetylcholine receptor, leading to the disruption of cholinergic retinal waves. Statistical comparisons of RGC transcriptomes between the two conditions reveal a weak impact of retinal waves on RGC diversity, indicating that retinal waves do not influence the molecular programs that instruct RGC differentiation and maturation. Although wave-dependent gene expression changes are modest in the global sense, we identified ~238 genes that are significantly altered in select subsets of RGC types. We focused on one gene, Kcnk9, which encodes the two-pore domain leak channel potassium channel TASK3. Kcnk9, which is highly enriched in αRGCs, was strongly downregulated in β2KO. We validated this result using in situ hybridization and performed whole-cell recording to demonstrate a significant decrease in the leak conductance in β2KO. Our dataset provides a useful resource for identifying potential targets of spontaneous activity-dependent regulation of neurodevelopment in the retina.