Endothelial SRF/MRTF ablation causes vascular disease phenotypes in murine retinae
Christine Weinl, … , Ralf H. Adams, Alfred Nordheim
Christine Weinl, … , Ralf H. Adams, Alfred Nordheim
Published April 8, 2013
Citation Information: J Clin Invest. 2013;123(5):2193-2206. https://doi.org/10.1172/JCI64201.
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Research Article Vascular biology

Endothelial SRF/MRTF ablation causes vascular disease phenotypes in murine retinae

Abstract

Retinal vessel homeostasis ensures normal ocular functions. Consequently, retinal hypovascularization and neovascularization, causing a lack and an excess of vessels, respectively, are hallmarks of human retinal pathology. We provide evidence that EC-specific genetic ablation of either the transcription factor SRF or its cofactors MRTF-A and MRTF-B, but not the SRF cofactors ELK1 or ELK4, cause retinal hypovascularization in the postnatal mouse eye. Inducible, EC-specific deficiency of SRF or MRTF-A/MRTF-B during postnatal angiogenesis impaired endothelial tip cell filopodia protrusion, resulting in incomplete formation of the retinal primary vascular plexus, absence of the deep plexi, and persistence of hyaloid vessels. All of these features are typical of human hypovascularization-related vitreoretinopathies, such as familial exudative vitreoretinopathies including Norrie disease. In contrast, conditional EC deletion of Srf in adult murine vessels elicited intraretinal neovascularization that was reminiscent of the age-related human pathologies retinal angiomatous proliferation and macular telangiectasia. These results indicate that angiogenic homeostasis is ensured by differential stage-specific functions of SRF target gene products in the developing versus the mature retinal vasculature and suggest that the actin-directed MRTF-SRF signaling axis could serve as a therapeutic target in the treatment of human vascular retinal diseases.

Authors

Christine Weinl, Heidemarie Riehle, Dongjeong Park, Christine Stritt, Susanne Beck, Gesine Huber, Hartwig Wolburg, Eric N. Olson, Mathias W. Seeliger, Ralf H. Adams, Alfred Nordheim

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Figure 10

VEGF-A activates nuclear translocation of MRTF-A.

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VEGF-A activates nuclear translocation of MRTF-A. (A) mECs were stimulat...
(A) mECs were stimulated with serum, VEGF-A, or VEGF-A in the presence of latrunculin B (LatB) and stained for nuclei (DAPI; blue), MRTF-A (green), and F-actin (phalloidin; red). (B) Scheme of (TSm)2 and (Tmm)2 luciferase reporter constructs, which contain 2 tandem copies of the c-Fos SRE upstream of the thymidine kinase basal promoter sequence (tk120; –120 to +1), able to drive luciferase cDNA expression. (C) Relative luciferase activity in reporter-transfected HRMECs, with or without cotransfection of MRTF-A expression vectors and with or without VEGF-A stimulation. (D) Semiquantitative RT-PCR for genomic candidate mRNA expression in mECs upon VEGF-A treatment, expressed as percent untreated control. n = 4 (Flt1, Srf, and Actb); 3 (Kdr and Fos). (E) VEGF signaling leads to activation of the actin-MRTF-SRF axis. Note that interaction of MRTF and TCF cofactors (ELK1 and ELK4) with SRF is mutually exclusive. Scale bars: 10 μm (A). *P < 0.05, **P < 0.01 vs. respective control.