Angiogenesis depends upon EPHB4-mediated export of collagen IV from vascular endothelial cells
Di Chen, Elizabeth D. Hughes, Thomas L. Saunders, Jiangping Wu, Magda N. Hernandez Vasquez, Taija Makinen, Philip D. King
Di Chen, Elizabeth D. Hughes, Thomas L. Saunders, Jiangping Wu, Magda N. Hernandez Vasquez, Taija Makinen, Philip D. King
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Research Article Angiogenesis Vascular biology

Angiogenesis depends upon EPHB4-mediated export of collagen IV from vascular endothelial cells

Abstract

Capillary malformation-arteriovenous malformation (CM-AVM) is a blood vascular anomaly caused by inherited loss-of-function mutations in RASA1 or EPHB4 genes, which encode p120 Ras GTPase-activating protein (p120 RasGAP/RASA1) and Ephrin receptor B4 (EPHB4). However, whether RASA1 and EPHB4 function in the same molecular signaling pathway to regulate the blood vasculature is uncertain. Here, we show that induced endothelial cell–specific (EC-specific) disruption of Ephb4 in mice resulted in accumulation of collagen IV in the EC ER, leading to EC apoptotic death and defective developmental, neonatal, and pathological angiogenesis, as reported previously in induced EC-specific RASA1-deficient mice. Moreover, defects in angiogenic responses in EPHB4-deficient mice could be rescued by drugs that inhibit signaling through the Ras pathway and drugs that promote collagen IV export from the ER. However, EPHB4-mutant mice that expressed a form of EPHB4 that is unable to physically engage RASA1 but retains protein tyrosine kinase activity showed normal angiogenic responses. These findings provide strong evidence that RASA1 and EPHB4 function in the same signaling pathway to protect against the development of CM-AVM independent of physical interaction and have important implications for possible means of treatment of this disease.

Authors

Di Chen, Elizabeth D. Hughes, Thomas L. Saunders, Jiangping Wu, Magda N. Hernandez Vasquez, Taija Makinen, Philip D. King

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Figure 10

Normal vascular development in homozygous EPHB4 2YP mice.

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Normal vascular development in homozygous EPHB4 2YP mice. (A) At left is...
(A) At left is a schematic representation of EPHB4 showing the ligand-binding domain (LBD), fibronectin domains (FN), JM segment, PTK domain (PTK), and sterile alpha motif domain (SAM). Ext, extracellular; int, intracellular. At right are shown the amino acid sequences of the JM regions of mouse and human EPHB4 and mouse EPHB2 and EPHA4. Numbering of the indicated conserved tyrosine and proline residues (mutated in EPHB4 2YP) is based upon mouse EPHB4 isoform b. Below are shown the secondary structure elements of the JM segment (27). Ex1, extended strand segment; αA’, single turn helix; αB’, 4 turn helix. Asterisks indicate residues that contact the PTK domain. (B and C) Cos-7 cells were transfected with c-myc–tagged wild-type (WT), Y590F/Y596F (2Y), Y590F/P593G/Y596F/P599G (2YP), or P593G/P599G (2P) EPHB4. Cells were stimulated or not with Ephrin B2, and transfected EPHB4 receptors were immunoprecipitated from lysates using an anti–c-myc antibody. (B) Coimmunoprecipitated RASA1 was detected by Western blotting. (C) Phosphotyrosine content of immunoprecipitated EPHB4 was detected by Western blotting. (D) Heterozygous Ephb4fl/2YP mice were intercrossed and embryos were harvested at E10.5. Development of Ephb4fl/2YP and Ephb42YP/2YP was normal at E10.5 (top). Anti-CD31 antibody staining reveals a normal vasculature in the head region of Ephb4fl/2YP and Ephb42YP/2YP embryos (bottom). See complete unedited blots in the supplemental material.