Abstract
Retinal ganglion cells (RGCs) are a heterogeneous population of neurons, comprised of numerous subtypes that work synchronously to transmit visual information to the brain. In blinding disorders such as glaucoma, RGCs are the main cell type to degenerate and lead to loss of vision. Previous studies have identified and characterized a variety of RGC subtypes in animal models, although only a handful of studies demonstrate the differential loss of these RGC subtypes in response to disease or injury. Thus, efforts of the current study utilized both chronic (bead occlusion) and acute (optic nerve crush, ONC) rat models to characterize disease response and differential loss of RGC subtypes. Bead occlusion and ONC retinas demonstrated significant RGC loss, glial reactivity and apoptosis compared to control retinas. Importantly, bead occlusion and ONC retinas resulted in differential subtype-specific loss of RGCs, with a high susceptibility for alpha- and direction selective-RGCs and preferential survival of ipRGCs. Results of this study serve as an important foundation for future experiments focused on the mechanisms resulting in the loss of RGCs in optic neuropathies, as well as the development of targeted therapeutics for RGC subtype-specific neuroprotection.
Highlights
Retinal ganglion cells (RGCs) are a heterogeneous population of neurons, comprised of numerous subtypes that work synchronously to transmit visual information to the brain
Retinal ganglion cells (RGCs) are the only projection neurons of the retina, extending axons through the optic nerve to connect with post-synaptic targets in the brain[1]
The degeneration of RGCs is commonly associated with a number of other phenotypes including significant loss of RGCs, glial reactivity, inflammatory responses, and increased apoptosis[3,4,5]
Summary
Retinal ganglion cells (RGCs) are a heterogeneous population of neurons, comprised of numerous subtypes that work synchronously to transmit visual information to the brain. Retinal ganglion cells (RGCs) are the only projection neurons of the retina, extending axons through the optic nerve to connect with post-synaptic targets in the brain[1] Disruptions to this crucial connection due to injury or disease result in the degeneration of RGCs and subsequent loss of vision or blindness[2,3,4,5]. The results of this study are among the first to utilize the chronic elevated-IOP bead occlusion model of glaucoma for studying differential RGC subtype loss and provide additional insights into the loss of RGCs following injury More so, these results will aid in the development of therapeutics targeted at specific subtypes, with important implications for the neuroprotection of those subtypes lost in optic neuropathies
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