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Vasohibin is up-regulated by VEGF in the retina and suppresses VEGF receptor 2 and retinal neovascularization

JiKui Shen^*, XiaoRu Yang, Wei-Hong Xiao^*, Sean F. Hackett^*, Yasufumi Sato and Peter A. Campochiaro^*,1

^* The Departments of Ophthalmology and Neuroscience The Johns Hopkins University School of Medicine Baltimore, Maryland, USA;
Department of Pulmonary Disease and Critical Care, Johns Hopkins University Bayview Medical Center, Baltimore, Maryland, USA; and
Department of Vascular Biology, Institute of Development, Aging, and Cancer, Tohoku University, Sendai, Japan

¹Correspondence: Maumenee 719, The Johns Hopkins University School of Medicine, 600 N. Wolfe St., Baltimore, MD 21287-9277, USA. E-mail: pcampo{at}jhmi.edu

SPECIFIC AIMS

Vasohibin is a recently identified protein that is up-regulated in cultured vascular endothelial cells by vascular endothelial growth factor (VEGF) and fibroblast growth factor 2. It inhibits endothelial cell migration, proliferation, and tube formation, and suppresses angiogenesis in chick chorioallantoic membrane, after subcutaneous implantation of matrigel, and in a tumor xenograft model. In this study, we tested the hypothesis that vasohibin functions as a negative feedback inhibitor of VEGF in a well-characterized model of retinal neovascularization.

PRINCIPAL FINDINGS

1. VEGF stimulates the expression of vasohibin in the retina
Oxygen-induced ischemic retinopathy is a useful model for study of hypoxia-induced regulation of VEGF expression. Placement of postnatal day (P) 7 mice into a high oxygen environment results in decreased expression of VEGF and regression of newly developed retinal blood vessels. When mice are returned to room air at P12, the poorly vascularized retina becomes hypoxic and the vegf mRNA level increases, peaks within 12 h, and remains elevated for 14 days. Measurement of retinal vegf mRNA by quantitative real-time RT-PCR at P13, 24 h after the onset of hypoxia, showed an 4-fold increase compared with the level in P13 control mice. Measurement of vasohibin mRNA in the same samples showed a statistically significant, 2-fold increase in hypoxic retinas compared with control retinas. Compared with intravitreous injection of GFP siRNA at P11, 1 day before mice were moved from 75% oxygen to room air, injection of vegf siRNA resulted in a 3-fold reduction in vegf mRNA in the retinas of P13 mice. It also resulted in nearly a 3-fold reduction in vasohibin mRNA, suggesting that levels of VEGF modulate levels of vasohibin.

Rho/VEGF transgenic mice have increased levels of VEGF in the retina starting at P7. At P16, the level of vegf mRNA was roughly 5-fold higher than that in P16 wild-type mice. Compared with wild-type P16 mice, the level of vasohibin mRNA was 3-fold higher in the retinas of rho/VEGF transgenics. This suggests that increased expression of VEGF in the retina in the absence of hypoxia is sufficient to up-regulate expression of vasohibin.

A polyclonal rabbit antibody that recognizes murine vasohibin was used to localize endogenous vasohibin in mouse retina. At P15, mice that had been reared in room air had normal retinas and no detectable staining for vasohibin (Fig. 1 , middle row, left column), while mice with ischemic retinopathy showed prominent staining that co-localized with CD31, which selectively stains endothelial cells (Fig. 1 , bottom row, right column). This indicates that vasohibin is up-regulated in vascular endothelial cells in ischemic retina.

View larger version (63K): [in this window] [in a new window]   Figure 1. Schematic representation of the proposed negative vasohibin negative feedback loop.

2. Vasohibin suppresses VEGF receptor 2 expression in retina, but has no effect on VEGF or VEGF receptor 1
To determine whether vasohibin modulates the expression of VEGF, siRNA targeting vasohibin mRNA was used. Mice were place in 75% oxygen at P7, received an intravitreous injection of vasohibin siRNA in one eye and GFP siRNA in the other eye on P11, and were returned to room air at P12. At P13, the level of vasohibin mRNA in the retina was reduced by almost 3-fold in mice that had been injected with vasohibin siRNA compared with mice injected with GFP siRNA, but the level of vegf mRNA was not significantly different. The effect on mRNA for VEGF receptors was investigated. Retinas with significant knockdown of vasohibin mRNA, showed a significant increase in vegf receptor 2 mRNA, but no significant change in vegf receptor 1 mRNA. This suggests that expression of vasohibin in the retina does not alter the levels of VEGF or VEGF receptor 1, but substantially reduces the level of VEGF receptor 2.

3. Vasohibin suppresses retinal neovascularization in ischemic retina
Vasohibin has been shown to inhibit neovascularization in cornea, subcutaneous matrigel implants, and chick chorioallantoic membrane; however, the angiogenic effects of proteins can vary among vascular beds. To determine the effect of vasohibin on retinal neovascularization, two strategies were used; one was to express human vasohibin in the retinas of mice with oxygen-induced ischemic retinopathy by intraocular injection of an adenoviral vector that expresses vasohibin (AdVasohibin) and the second was to inject recombinant vasohibin. Immunoblots and immunohistochemistry showed that injection of AdVasohibin caused increased levels of vasohibin in the retina. Mice with ischemic retinopathy had intravitreous injection of 10⁹ or 10¹⁰ particle units (pu) of AdVasohibin or 10⁹ pu of an empty adenoviral vector (AdNull) at P12 and were killed at P17. Retinas from eyes injected with 10⁹ pu of AdNull showed prominent neovascularization along the surface of the retina (Fig. 2 A, D), while those injected with 10⁹ (Fig. 2B, E ) or 10¹⁰ (Fig. 2C, F ) pu of AdVasohibin had little retinal neovascularization. Measurement of the area of retinal neovascularization on the surface of the retina showed that there was significantly less neovascularization in eyes injected with 5 or 10 ng of recombinant human vasohibin compared with eyes injected with PBS (Fig. 2G ) and significantly less neovascularization in eyes injected with 10⁹ or 10¹⁰ pu of AdVasohibin compared with eyes injected with 10⁹ AdNull (Fig. 2H ).

View larger version (77K): [in this window] [in a new window]   Figure 2. Vasohibin suppresses retinal neovascularization in mice with ischemic retinopathy. C57BL/6 mice were placed in 75% oxygen at P7 and returned to room air at P12 when they were also given an intravitreous injection of 109 (n=8) or 1010 (n=8) pu of AdVasohibin, 109 pu of AdNull (n=8), 5 ng (n=8) or 10 ng (n= 8) of recombinant vasohibin, or PBS. At P17, mice were killed and eyes were frozen in OCT. Frozen sections were histochemically stained with Griffonia simplicifolia lectin (brown reaction product), which selectively stains vascular cells, and counterstained with hematoxylin (purple), which stains retinal neurons. Eyes injected with AdNull showed many large areas of neovascularization (arrows) on the surface of the retina (A, D). Mice injected with 109 (B, E) or 1010 (C, F) pu of AdVasohibin showed only a few small sprouts of neovascularization (arrows). Measurement of the area of neovascularization on the surface of the retina by image analysis (mm2), showed that eyes injected with 5 or 10 ng of recombinant human vasohibin had significantly less neovascularization than eyes injected with PBS (G). Eyes injected with 109 or 1010 pu of AdVasohibin had significantly less neovascularization than eyes injected with 109 pu of AdNull (H).

CONCLUSIONS AND SIGNIFICANCE

In this study, we have demonstrated that increased expression of VEGF in the retina, whether it is due to hypoxia or a vegf transgene, is accompanied by increased levels of vasohibin mRNA. In ischemic retina, there is up-regulation of vasohibin in vascular endothelial cells. Knockdown of vegf mRNA by specific siRNAs results in significant reduction of vasohibin mRNA and knockdown of vasohibin mRNA increases ischemia-induced retinal neovascularization. Conversely, increasing levels of vasohibin in the retina by injection of recombinant vasohibin or by gene transfer strongly suppresses ischemia-induced retinal neovascularization. These data support the hypothesis that vasohibin acts as an inhibitor of retinal neovascularization that is up-regulated by VEGF; therefore, vasohibin may act in a negative feedback loop to help suppress neovascularization in the retina (Fig. 3 ) as has been postulated for tumors.

View larger version (24K): [in this window] [in a new window]   Figure 3. Vasohibin is up-regulated in vascular endothelial cells in ischemic retina. At P15, mice reared in room air (first column) or mice with oxygen-induced ischemic retinopathy (second column) were killed and ocular frozen sections were stained with a rat antibody directed against CD31 (PECAM, top row), which selectively stains vascular endothelial cells or a rabbit polyclonal antibody directed against murine vasohibin (second row). Secondary antibodies were a goat anti-rabbit IgG conjugated with FITC and a donkey anti-rat IgG conjugated with Cy3, so that staining for vasohibin appears green and staining for CD31 appears red. Small cross sections of retinal vessels are seen in the CD31-stained retina from a normal mouse, while dilated vessels and new vessels are seen in the CD31-stained retina from a mouse with ischemic retinopathy. There is no detectable staining for vasohibin in the retina of the mouse reared in room air, but there is prominent staining in the retina of the mouse with ischemic retinopathy. Merging of the images for the retina of the mouse with ischemic retinopathy (bottom row, second column) by simultaneously viewing with the red and green channels, demonstrates co-localization of CD31 and vasohibin, indicating that vasohibin is expressed in vascular endothelial cells.

Blunting of the vasohibin rise in ischemic retina by injection of vasohibin siRNA had no significant effect on vegf mRNA levels suggesting that the antiangiogenic effects of vasohibin are not mediated by suppression of VEGF production. However, vasohibin knockdown was accompanied by a significant increase in vegf receptor 2 mRNA, suggesting that the vasohibin negative feedback loop that modulates VEGF activity involves reduction of mRNA for VEGF receptor 2. This could be achieved by inhibiting expression or enhancing degradation of vegf receptor 2 mRNA. There was no effect on vegf receptor 1 mRNA. Interestingly, in cultured endothelial cells, blockade of VEGFR2, but not VEGFR1, suppressed the ability of VEGF to induce vasohibin.

Retinal and choroidal neovascularization are extremely prevalent causes of blindness and are the focus of an intense effort to find selective molecular treatments. This effort has received an important boost from demonstrations that VEGF is an important stimulator for both retinal and choroidal neovascularization. Recently, pegaptanib, an aptamer that binds VEGF, given every 6 wk by intraocular injection, has been demonstrated to slow the rate of vision loss in patients with neovascular AMD. Although the benefits were modest, they confirm that VEGF is an important target. Additional treatments that provide inhibition by different mechanisms are needed. Although the mechanism of the antiangiogenic effect of vasohibin is not completely established, it does not appear to directly antagonize VEGF; therefore, it may have synergistic activity when used in combination with agents that bind VEGF. Additional studies are needed to elucidate the mechanism by which vasohibin works and find ways to exploit its antiangiogenic activity in development of treatments.

FOOTNOTES

To read the full text of this article, go to http://www.fasebj.org/cgi/doi/10.1096/fj.05-5046fje;

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