Project description:We used optic nerve injury as a model to study early signaling events in the neuronal soma following axonal injury. Optic nerve injury results in the selective death of retinal ganglion cells (RGCs). The time course of cell death takes place over a period of days with the earliest detection of RGC death at about 48 hr post injury. We hypothesized that in the period immediately following axonal injury, there are changes in the soma that signal surrounding glia and neurons and that start programmed cell death. In the current study, we investigated early changes in cellular signaling and gene expression that occur within the first 6 hrs post optic nerve injury. We detected differences in phosphoproteins and gene expression within this time period that we used to interpret temporal events. Our studies revealed that the entire retina has been signaled by the RGC soma within 30 min after optic nerve injury and that pathways that modulate cell death are likely to be active in RGCs within 6 hrs following axonal injury Experiment Overall Design: In the treated animals, axons of the optic nerve were crushed with fine forceps for 10 sec, 1 mm posterior to the globe, under direct visualization, within an intact meningeal sheath. Controls were contralateral eyes from the same animals in each group that had not been injured. After 6 hr eyes were enucleated and processed for tissue sectionin

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.

Project description:The lack of neuroprotective treatments for retinal ganglion cells (RGCs) and optic nerve (ON) is a central challenge for glaucoma management. Emerging evidence suggests that redox factor NAD+ decline is a hallmark of aging and neurodegenerative diseases including glaucoma. Supplementation with NAD+ precursors and overexpression of the nicotinamide mononucleotide adenylyltransferase (NMNAT), the key enzyme involved in the NAD+ biosynthetic process, have significant neuroprotection effect on glaucoma. Among the three NMNAT isoforms, only NMNAT2 is enriched in neurons, especially in axons, however, its role in glaucoma is not well studied. Here we present the expression levels of the enzymes that involved in NAD+ metabolism in both naïve and glaucomatous mouse RGCs. Intriguingly, NMNAT2 is the dominant form of NMNATs in RGCs and only its mRNA level, but not NMNAT1 or NMNAT3, is significant decreased in glaucomatous RGCs. We then demonstrated proof-of-principal gene therapy strategy of restoring RGC-specific NMNAT2 and NAD+ levels by AAV2-mediated RGC-specific promoter mSncg-driven long half-life NMNAT2 mutant. This gene therapy strategy is further tested in two optic neuropathy models, traumatic ON crush model and ocular hypertension glaucoma model. RGC-specific NMNAT2 overexpression significantly promotes RGC somata and axons survival and preserves visual function in both models. Our studies suggest that the weaking of NMNAT2 expression in glaucomatous RGCs contributes to detrimental NAD+ decline and that modulating RGC intrinsic NMNAT2 level by AAV2-mSncg vector is a potent gene therapy for glaucomatous neuroprotection.

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:One important facet of the glaucoma pathology is axonal damage, which ultimately disrupts the connection between the retina and its postsynaptic targets. The concurrent loss of retrograde support interferes with the functionality and survival of the retinal ganglion cells (RGCs). Con-versely, previous research has shown that stimulation of neuronal activity in a primary retinal target area—i.e., the superior colliculus— promotes RGC survival in an acute mouse model of glaucoma. To build further on this observation, we applied repeated chemogenetics in the superior colliculus of a more chronic model of glaucoma—i.e., the microbead occlusion model—and per-formed bulk RNA sequencing on collicular lysates and isolated RGCs. Our study revealed that chronic target stimulation upon glaucomatous injury phenocopies the a priori expected molecular response: growth factors were pinpointed as essential transcriptional regulators both in the locally stimulated tissue and in distant, unstimulated RGCs. Strikingly, and although the RGC tran-scriptome revealed an enrichment of pro-survival signaling pathways, functional rescue of injured RGCs was not achieved.

Project description:Glaucoma is a common ocular disorder that is a leading cause of blindness worldwide. It is characterized by the dysfunction and loss of retinal ganglion cells (RGCs). Although many studies have implicated various molecules in glaucoma, no mechanism has been shown to be responsible for the earliest detectable damage to RGCs and their axons in the optic nerve. Here, we show that the leukocyte transendothelial migration pathway is activated in the optic nerve head at the earliest stages of disease in an inherited mouse model of glaucoma. This resulted in proinflammatory monocytes entering the optic nerve prior to detectable neuronal damage. A 1-time x-ray treatment prevented monocyte entry and subsequent glaucomatous damage. A single x-ray treatment of an individual eye in young mice provided that eye with long-term protection from glaucoma but had no effect on the contralateral eye. Localized radiation treatment prevented detectable neuronal damage and dysfunction in treated eyes, despite the continued presence of other glaucomatous stresses and signaling pathways. Injection of endothelin-2, a damaging mediator produced by the monocytes, into irradiated eyes, combined with the other glaucomatous stresses, restored neural damage with a topography characteristic of glaucoma. Together, these data support a model of glaucomatous damage involving monocyte entry into the optic nerve. Genome-wide assessment of gene expression changes was performed in DBA/2J-Gpnmb+, DBA/2J mice and irradiated DBA/2J mice at 8.5 and 10.5 months of age.

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 death of retinal ganglion cells(RGC) after the damage on optic nerve as a result of high intraocular pressure is the main reason of the irreversible blindness in glaucoma patients ,and mammals have very limited ability of maintaining the RGCs after optic nerve injury.Zebrafish,however,possess the ability of keep most RGCs from death after optic nerve injury. The purpose of this study is to determine which gene or pathway mediate the RGC survival mechanism underlying.It is observed JAK/STAT signaling pathway as well as the innate immune response is activated after optic nerve injury(in this study,optic nerve transection).Pharmacological inhibition of JAK/STAT by intravitreal(IV) injection of JAK inhibitor,P6,induced the reduction of RGC survival while both local and systemic immune suppressor application result in the rescue of RGC survival.Moreover,phospho-STAT3(pSTAT3),which is an evidence of STAT3 activation,demonstrated elevation of expression level after ONT,and the trend of pSTAT3 expression change is consistent with the RGC survival rate change .JAK inhibition reduced pSTAT3 expression level and immune suppressor application elevated the pSTAT3 expression level on RGCs. In summary,these data suggested JAK/STAT signaling pathway crosstalk with innate immune response create a dynamic balance in the mechanism of RGC survival.Interestingly,innate immune response which was used to be considered promoting tissue repair in other studies,proved to be suppressing RGC survival in this study.These data could be used as reference for future direction of neuroprotection in glaucoma treatment.

Project description:Retinal ganglion cells (RGCs) serve as the essential connection between the eye and the brain, with this connection disrupted in blinding disorders such as glaucoma. Numerous cellular mechanisms have been associated with glaucomatous neurodegeneration, and useful models for the study of glaucoma allow for the precise analysis of these degenerative phenotypes. Human pluripotent stem cells (hPSCs) serve as powerful tools for the in vitro analysis of human neurodegenerative diseases, particularly those cellular mechanisms underlying degeneration. Thus, efforts of the current study were initially focused upon the use of hPSCs with an E50K mutation in the Optineurin (OPTN) gene underlying glaucomatous neurodegeneration. CRISPR/Cas9 gene editing approaches were used to introduce the OPTN(E50K) mutation into existing lines of hPSCs, as well as the generation of isogenic control lines from existing OPTN(E50K) patient-derived hPSC lines. When grown from glaucomatous sources, hPSC-derived RGCs developed similarly to isogenic controls. Conversely, at later stages of maturation, OPTN(E50K) RGCs exhibited numerous deficits associated with a neurodegenerative phenotype, including neurite retraction, autophagy pathway disruption, apoptosis, and increased excitability. The results of this study provide an extensive analysis of the OPTN(E50K) mutation in hPSC-derived RGCs, with a number of biochemical and molecular alterations associated with functional changes to these RGCs. The opportunity now exists to further explore the precise cellular pathways leading to RGC death in glaucoma, as well as develop novel translational approaches for glaucoma including pharmacological screening and cell replacement therapies.

Project description:CNS neurons lose their ability to grow and regenerate axons during development. This is the case for Retinal Ganglion Cells (RGCs) in the retina, which transmit visual information to the brain via axons projecting into the optic nerve. RGCs are unable to regenerate their axon after injury, and start a degeneration process that leads to cell death and loss of vision. To identifying molecular mechanisms that increase regeneration of RGC and may offer new treatment strategies for patients with glaucoma or other types of optic neuropathies, we focused on the identification of transcription factors and chromatin accessible sites that are enriched in RGC during developmental stages, in which axon growth capacity is robust. We find that stage-specific gene expression changes are correlated with temporal changes in promoter chromatin accessibility. We also find that Creb binding motifs are enriched in the differentially opened regions of the chromatin at embryonic developmental stage. Overexpression of active Creb promotes axon regeneration after optic nerve injury. Our results provide a map of the chromatin accessibility during RGC development and highlights that manipulating TF associated with developmental stages can stimulate axon growth in adulthood.