Dysregulated claudin-5 cycling in the inner retina causes retinal pigment epithelial cell atrophy
Natalie Hudson, … , Sarah L. Doyle, Matthew Campbell
Natalie Hudson, … , Sarah L. Doyle, Matthew Campbell
Published August 8, 2019
Citation Information: JCI Insight. 2019;4(15):e130273. https://doi.org/10.1172/jci.insight.130273.
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Research Article Ophthalmology Vascular biology

Dysregulated claudin-5 cycling in the inner retina causes retinal pigment epithelial cell atrophy

Abstract

Age-related macular degeneration (AMD) is the leading cause of central retinal vision loss worldwide, with an estimated 1 in 10 people over the age of 55 showing early signs of the condition. There are currently no forms of therapy available for the end stage of dry AMD, geographic atrophy (GA). Here, we show that the inner blood-retina barrier (iBRB) is highly dynamic and may play a contributory role in GA development. We have discovered that the gene CLDN5, which encodes claudin-5, a tight junction protein abundantly expressed at the iBRB, is regulated by BMAL1 and the circadian clock. Persistent suppression of claudin-5 expression in mice exposed to a cholesterol-enriched diet induced striking retinal pigment epithelium (RPE) cell atrophy, and persistent targeted suppression of claudin-5 in the macular region of nonhuman primates induced RPE cell atrophy. Moreover, fundus fluorescein angiography in human and nonhuman primate subjects showed increased retinal vascular permeability in the evening compared with the morning. These findings implicate an inner retina–derived component in the early pathophysiological changes observed in AMD, and we suggest that restoring the integrity of the iBRB may represent a novel therapeutic target for the prevention and treatment of GA secondary to dry AMD.

Authors

Natalie Hudson, Lucia Celkova, Alan Hopkins, Chris Greene, Federica Storti, Ema Ozaki, Erin Fahey, Sofia Theodoropoulou, Paul F. Kenna, Marian M. Humphries, Annie M. Curtis, Eleanor Demmons, Akeem Browne, Shervin Liddie, Matthew S. Lawrence, Christian Grimm, Mark T. Cahill, Pete Humphries, Sarah L. Doyle, Matthew Campbell

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Figure 3

Bmal1 regulates claudin-5 levels at the iBRB.

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Bmal1 regulates claudin-5 levels at the iBRB. (A) Claudin-5 expression a...
(A) Claudin-5 expression at 8 am and 8 pm in Bmal1fl/fl Tie2-Cre+ mice at 8 am compared to 8 pm (n = 5 mice for both time points, P = ns). (B) Claudin-5 transcript levels in WT Cre+, Bmal1WT/fl Tie2-Cre+, and Bmal1fl/fl Tie2-Cre+ mice (n = 7–13 mice per group). (C) Claudin-5 expression in retinas of Bmal1fl/fl Tie2-Cre+ at 8 am (left) compared with 8 pm (right), higher magnification. Original magnification, ×40. (D) FFA in Bmal1fl/fl Tie2-Cre+ at 8 am (top) compared to 8 pm (bottom) showed (E) no significant differences (n = 12 mice for 8 am, and n = 11 mice for 8 pm). (F) Claudin-5 expression in endothelial cells exposed to serum shock (50% serum) for 2 hours. (G) Suppression efficacy of Bmal-1 siRNA on Bmal-1 transcript expression (*P = 0.0026, and n = 3). (H) Claudin-5 expression in bEnd.3 cells with suppressed Bmal1 before serum shock exposure. (I) Transendothelial electrical resistance (TEER) measurement in bEnd.3 cells with Bmal1 suppressed (*P = 0.0339, and n = 5). (J) Claudin-5 staining in bEnd.3 cells after suppression of Bmal1. Red, claudin-5; green, nuclei. Scale bar: 50 μm. Arrows indicate discontinuity of claudin-5 staining. Student’s t test, with significance represented by a P value of less than or equal to 0.05. For multiple comparisons, ANOVA was used with Bonferroni’s post hoc test and significance represented by a P value of less than or equal to 0.05.