Antioxidant or neurotrophic factor treatment preserves function in a mouse model of neovascularization-associated oxidative stress
Michael I. Dorrell, Edith Aguilar, Ruth Jacobson, Oscar Yanes, Ray Gariano, John Heckenlively, Eyal Banin, G. Anthony Ramirez, Mehdi Gasmi, Alan Bird, Gary Siuzdak, Martin Friedlander
Michael I. Dorrell, Edith Aguilar, Ruth Jacobson, Oscar Yanes, Ray Gariano, John Heckenlively, Eyal Banin, G. Anthony Ramirez, Mehdi Gasmi, Alan Bird, Gary Siuzdak, Martin Friedlander
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Research Article Ophthalmology

Antioxidant or neurotrophic factor treatment preserves function in a mouse model of neovascularization-associated oxidative stress

Abstract

In several disease states, abnormal growth of blood vessels is associated with local neuronal degeneration. This is particularly true in ocular diseases such as retinal angiomatous proliferation (RAP) and macular telangiectasia (MacTel), in which, despite the absence of large-scale leakage or hemorrhage, abnormal neovascularization (NV) is associated with local neuronal dysfunction. We describe here a retinal phenotype in mice with dysfunctional receptors for VLDL (Vldlr–/– mice) that closely resembles human retinal diseases in which abnormal intra- and subretinal NV is associated with photoreceptor cell death. Such cell death was evidenced by decreased cone and, to a lesser extent, rod opsin expression and abnormal electroretinograms. Cell death in the region of intraretinal vascular abnormalities was associated with an increased presence of markers associated with oxidative stress. Oral antioxidant supplementation protected against photoreceptor degeneration and preserved retinal function, despite the continued presence of abnormal intra- and subretinal vessels. What we believe to be novel, Müller cell–based, virally mediated delivery of neurotrophic compounds specifically to sites of NV was also neuroprotective. These observations demonstrate that neuronal loss secondary to NV can be prevented by the use of simple antioxidant dietary measures or cell-based delivery of neurotrophic factors, even when the underlying vascular phenotype is not altered.

Authors

Michael I. Dorrell, Edith Aguilar, Ruth Jacobson, Oscar Yanes, Ray Gariano, John Heckenlively, Eyal Banin, G. Anthony Ramirez, Mehdi Gasmi, Alan Bird, Gary Siuzdak, Martin Friedlander

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Figure 6

Evidence of oxidative stress associated with subretinal NV in Vldlr–/– mouse retinas.

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Evidence of oxidative stress associated with subretinal NV in Vldlr–/– m...
(A) Acrolein staining increased in Vldlr–/– retinas compared with age-matched WT controls. Acrolein staining in Vldlr–/– retinas was largely within the central retina, where intraretinal NV is most prominent. Panels are composite montages of multiple serial micrographs. (B) Higher-magnification images demonstrating that acrolein staining localized to the photoreceptor layer and INL. (C) Acrolein staining significantly increased in 2-mo-old Vldlr–/– compared with WT retinas. At 6 mo of age, acrolein staining was similar in the peripheral retinas of WT and Vldlr–/– mice (P = 0.245), but was significantly stronger in the central regions of Vldlr–/– retinas, where subretinal NV occurs, compared with retinas of WT mice. Error bars denote SEM. (D) Expression of genes involved in oxidative stress defense mechanisms was similar between P21 Vldlr–/– and WT retinas. Solid line indicates equivalent expression levels; dotted lines represent 95% confidence level ranges. Scale bars: 500 μm (A); 50 μm (B).