Sustained inflammation after pericyte depletion induces irreversible blood-retina barrier breakdown
Shuntaro Ogura, … , Yuichiro Ogura, Akiyoshi Uemura
Shuntaro Ogura, … , Yuichiro Ogura, Akiyoshi Uemura
Published February 9, 2017
Citation Information: JCI Insight. 2017;2(3):e90905. https://doi.org/10.1172/jci.insight.90905.
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Research Article Ophthalmology Vascular biology

Sustained inflammation after pericyte depletion induces irreversible blood-retina barrier breakdown

Abstract

In the central nervous system, endothelial cells (ECs) and pericytes (PCs) of blood vessel walls cooperatively form a physical and chemical barrier to maintain neural homeostasis. However, in diabetic retinopathy (DR), the loss of PCs from vessel walls is assumed to cause breakdown of the blood-retina barrier (BRB) and subsequent vision-threatening vascular dysfunctions. Nonetheless, the lack of adequate DR animal models has precluded disease understanding and drug discovery. Here, by using an anti-PDGFRβ antibody, we show that transient inhibition of the PC recruitment to developing retinal vessels sustained EC-PC dissociations and BRB breakdown in adult mouse retinas, reproducing characteristic features of DR such as hyperpermeability, hypoperfusion, and neoangiogenesis. Notably, PC depletion directly induced inflammatory responses in ECs and perivascular infiltration of macrophages, whereby macrophage-derived VEGF and placental growth factor (PlGF) activated VEGFR1 in macrophages and VEGFR2 in ECs. Moreover, angiopoietin-2 (Angpt2) upregulation and Tie1 downregulation activated FOXO1 in PC-free ECs locally at the leaky aneurysms. This cycle of vessel damage was shut down by simultaneously blocking VEGF, PlGF, and Angpt2, thus restoring the BRB integrity. Together, our model provides new opportunities for identifying the sequential events triggered by PC deficiency, not only in DR, but also in various neurological disorders.

Authors

Shuntaro Ogura, Kaori Kurata, Yuki Hattori, Hiroshi Takase, Toshina Ishiguro-Oonuma, Yoonha Hwang, Soyeon Ahn, Inwon Park, Wataru Ikeda, Sentaro Kusuhara, Yoko Fukushima, Hiromi Nara, Hideto Sakai, Takashi Fujiwara, Jun Matsushita, Masatsugu Ema, Masanori Hirashima, Takashi Minami, Masabumi Shibuya, Nobuyuki Takakura, Pilhan Kim, Takaki Miyata, Yuichiro Ogura, Akiyoshi Uemura

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Figure 6

Endothelial cell–macrophage interactions via VEGF and placental growth factor (PlGF).

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Endothelial cell–macrophage interactions via VEGF and placental growth f...
(A) Detection of retinal hypoxia and vessel perfusion at P8 and 4 weeks by i.p. pimonidazole and transcardiac Tomato lectin injections, respectively, along with IHC for CD31. Note the hypoxia in the areas of hypoperfused vessels in the APB-treated retinas. (B) Quantitative reverse transcription PCR (qRT-PCR) of P8 (n = 8) and 8-week (n = 6) retinas. (C) ISH for Vegfa (white) and IHC for type IV collagen (Col IV) and Iba1 in P8 retinas. (D) IHC for CD31 and VEGFR2 (white) in retinas from P8 and 4-week Vegfr2-BAC-GFP mice. Note the endothelial VEGFR2 upregulation in APB5-treated retinas, in contrast to the constitutive VEGFR2 expression in neurons and Müller glia. (E) ISH for Pgf (white) and IHC for Col IV and Iba1 in P8 retinas. (F) IHC for Iba1 in retinas from P8 and 4-wk Vegfr1-BAC-DsRed mice. (G) Flow cytometry in P8 retinas. CD45hiCD11b+ and CD45loCD11b+ cells were gated as shown in Figure 5A. The graph shows fold changes of the number of CD45hiCD11b+VEGFR1+ and CD45loCD11b+VEGFR1+ cells per retina (n = 5). (H) Representative retina cups (upper) and IHC for CD31 and Iba1 (lower) at P11 in Flt1-TK mice. The APB5-treated retinas were graded according to Supplemental Figure 1C. The graphs show the number of Iba1+ cells and the vessel density per area (control, n = 12; APB5, n = 20). (I) The trajectory of GFP+ cells in ex vivo retina imaging from P8 Cx3cr1-GFP mice injected with 50 μg of APB5. After 3-hour imaging, retinas were treated with control IgG or VEGF Trap, and further monitored for 3 hours. The graphs show quantification of cell body movement velocity (Pre IgG, n = 68; Post IgG, n = 56; Pre VEGF Trap, n = 52; Post VEGF Trap, n = 47) and total dendrite length per GFP+ cell (Pre IgG, n = 40; Post IgG, n = 34; Pre VEGF Trap, n = 43; Post VEGF Trap, n = 33). See also Supplemental Video 4. *P < 0.05, ***P < 0.001 (2-tailed Student’s t test). Scale bars: 100 μm (A and H); 50 μm (D); 20 μm (C, E, and F).