Blood-retina barrier failure and vision loss in neuron-specific degeneration
Elena Ivanova, … , Glen T. Prusky, Botir T. Sagdullaev
Elena Ivanova, … , Glen T. Prusky, Botir T. Sagdullaev
Published March 19, 2019
Citation Information: JCI Insight. 2019;4(8):e126747. https://doi.org/10.1172/jci.insight.126747.
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Research Article Ophthalmology Vascular biology

Blood-retina barrier failure and vision loss in neuron-specific degeneration

Abstract

Changes in neuronal activity alter blood flow to match energy demand with the supply of oxygen and nutrients. This functional hyperemia is maintained by interactions among neurons, vascular cells, and glia. However, how changing neuronal activity prevalent at the onset of neurodegenerative disease affects neurovascular elements is unclear. Here, in mice with photoreceptor degeneration, a model of neuron-specific dysfunction, we combined the assessment of visual function, neurovascular unit structure, and blood-retina barrier permeability. We found that the rod loss paralleled remodeling of the neurovascular unit, comprising photoreceptors, retinal pigment epithelium, and Muller glia. When substantial visual function was still present, blood flow became disrupted and the blood-retina barrier began to fail, facilitating cone loss and vision decline. Thus, in contrast to the established view, the vascular deficit in neuronal degeneration is not a late consequence of neuronal dysfunction but is present early in the course of disease. These findings further establish the importance of vascular deficit and blood-retina barrier function in neuron-specific loss and highlight it as a target for early therapeutic intervention.

Authors

Elena Ivanova, Nazia M. Alam, Glen T. Prusky, Botir T. Sagdullaev

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Figure 3

Blood-retina barrier is first disrupted at retinal pigment epithelium and later at retinal vasculature.

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Blood-retina barrier is first disrupted at retinal pigment epithelium an...
(A) Mice were injected with fluorescent probes, and living eyecup preparations were imaged under confocal microscope and then processed for albumin labeling. (B) Representative images of WT and rd10 retinas after infusion of probes. At P20–P21 light fluorescein labeling was detected at the retinal pigment epithelium (RPE) layer in rd10 retina. In WT retina, both lowest weight fluorescein and highest weight accumulated albumin were contained to blood vessels. (C) At P35 in rd10 retina, outer blood-retina barrier (BRB) had increased permeation for both low-weight-molecular probes and large (70-kDa) blood plasma albumin. (D) At P200 in rd10 retina the leak was evident with all probes from both RPE and deep vascular capillaries. Scale bar: 50 μm. (E–G) Quantification of the vascular leak at P20–P21 (E), P35–P40 (F), and P200 (G). Error bars ± SEM. Each measurement was done in 4–5 different mice.