Charpentier MS , Tandon P , Trincot CE , Koutleva EK , Conlon FL .

R01 DE018825 NIDCR NIH HHS, R01 HL089641 NHLBI NIH HHS

	Fig 2. Basement membrane proteins are deposited on both the basal and apical surfaces of early vessels in Xenopus.(A-G) Representative confocal images of transverse sections of the dorsal aorta (DA) and posterior cardinal veins (PCV) stained with laminin or fibronectin (red). In A,B,D,E,F staining with GFP to mark cell membranes (MEM-GFP) and DAPI to mark nuclei (blue) is also shown. In C and G, Flk-1:GFP transgenic animals were used to identify endothelial cells (green). All images taken at 63x magnification with scale bars indicating 20 μm. Dotted white lines in all panels delineate the endothelial cells comprising each vessel. As anatomical references, the hypochord in (A-B) and the kidney in (D-F) are indicated by solid white lines. Dotted lines in the magnified images represent vessels. Asterisks denote the vessel lumen. (A). The DA of early tadpole stage (stage 35/36) control embryos display deposition of fibronectin on both apical and basal surfaces (arrowheads point to apical staining). (B). DA of early tadpole stage (stage 35/36) control embryo exhibits the laminin staining on the basal and the apical surfaces of the vessel (arrowheads point to apical staining). (C). By late tadpole stage (stage 46), proper polarity is established in the dorsal aorta with laminin localizing to the basal surface of endothelial cells (arrowheads point to basal staining). (D) PCV of early tadpole stage (stage 35/36) control embryo exhibits apically and basally deposited fibronectin (arrowheads point to apical staining). (E-F). The kidney displays appropriate basal expression of laminin (arrow), however, the PCV of early tadpole stage (stage 35/36) control embryos display aggregates of laminin staining on the apical surface (arrowheads). (G) Laminin becomes distributed on the basal surface of the posterior cardinal vein in late tadpole stage (stage 46) embryos (arrowheads point to basal staining). 3–4 embryos from each condition/stage were assessed from at least three independent injection batches at the same position along the anterior-posterior axis of the embryo.
	Fig 3. Apical polarity is not established in Xenopus vessels.(A-H). Representative confocal images of transverse sections of the dorsal aorta (DA) and posterior cardinal veins (PCV) stained with atypical PKCζ (aPKCζ; red), GFP to mark cell membranes (MEM-GFP; green), and DAPI to mark nuclei (blue; A,B,E,F) or Phalloidin to mark F-actin (green) and DAPI (blue; C,D,G,H). Phase contrast images for the PCVs in (E) and (F) represent the Erg in situ signal. All images taken at 63x magnification with scale bars indicating 20 μm. Dotted white and red lines in all panels delineate the endothelial cells comprising each vessel. As anatomical references, the hypochord in (A-D) and the kidney in (E-H) are indicated by solid white lines. Asterisks denote the vessel lumen. (A-B). aPKCζ enrichment is absent from the cell-cell contact in late tailbud stage (stage 33/34) control embryos and the apical membrane of the DA of early tadpole stage (stage 35/36) control embryos. 3–4 embryos from each condition/stage were assessed from at least three independent injection batches at the same position along the anterior-posterior axis of the embryo. (C-D). F-actin fails to localize to the cell-cell contact or apical surface of the dorsal aorta at late tailbud and early tadpole stages. (E-F). aPKCζ can readily be detected on the apical surface of the kidney (arrow) but not at the cell-cell contact or apical membrane of the PCV at late tailbud (stage 33/34) or early tadpole stages (stage 35/36). (G-H). F-actin is evenly distributed in venous endothelial cells. 3–4 embryos from each condition/stage were assessed from at least two independent injection batches at the same position along the anterior-posterior axis of the embryo.
	Fig 4. EGFL7 is required for lumen formation.(A-D). In situ hybridization with endothelial-specific Erg shows a requirement for EGFL7 in lumen formation of the dorsal aorta (DA) and posterior cardinal veins (PCV). (A). Endothelial cells coalesce at the appropriate positions of the DA and PCVs in late tailbud stage (stage 33/34) control embryos. (B). DA and PCV lumens become evident by early tadpole stage (stage 35/36) in control embryos. (C). Endothelial cells appear as aggregates in late tailbud stage (stage 33/34) EGFL7-depleted vessels similar to controls. (D). Lumens fail to form in early tadpole stage (stage 35/36) EGFL7-depleted embryos. 3–4 embryos from each condition/stage were assessed from at least three independent injection batches at the same position along the anterior-posterior axis of the embryo. Top image of each panel was taken at 20x magnification. Black boxes correspond to enlarged images of each vessel displayed below. Scale bars represent 20 μm. (E). Frequency of lumenized PCVs and DAs in early tadpole stage (stage 35/36) embryos. Lumens are detected in 81% of control embryos vs. 21% of EGFL7-depleted embryos. n = 209 control, n = 216 MO, three independent experiments. Student's t-test was used to calculate the p-value and bars represent ± SEM. (F). Measurement of the luminal area within the PCV in early tadpole stage (stage 35/36) embryos. The size of control lumens = 218 μm. Of EGFL7-depleted vessels that were lumenized, lumens were significantly smaller,75 μm. n = 70 control, n = 29 MO. A Mann-Whitney test was used to determine significance and bars represent ± SEM.
	Fig 5. Cellular morphology of endothelial cells undergoing lumen formation.(A-H). Representative confocal images of transverse sections of the dorsal aorta (DA) and posterior cardinal veins (PCV) stained with GFP to mark cell membranes (MEM-GFP; green) and DAPI to mark nuclei (blue). Phase contrast images for the PCVs represent the Erg in situ signal. All images taken at 63x magnification with scale bars indicating 20 μm. Dotted white and red lines in all panels delineate individual endothelial cells. As anatomical references, the hypochord in (A-D) and the kidney in (E-H) are indicated by solid white lines. (A). Endothelial cells of the DA are oblong-shaped at late tailbud stage (stage 33/34) control embryos. (B). Endothelial cells of late tailbud stage (stage 33/34) EGFL7-depleted DAs display a similar morphology to controls. (C). Endothelial cells elongate during DA lumen formation in early tadpole stage (stage 35/36) control embryos. (D). Endothelial cells of the DA remain oblong-shaped and do not elongate to accommodate the vascular lumen in early tadpole stage (stage 35/36) EGFL7-depleted embryos. (E). Endothelial cells of the PCVs have a polygonal cobblestone-like shape in late tailbud stage (stage 33/34) control embryos. (F). Endothelial cells of late tailbud stage (stage 33/34) EGFL7-depleted PCVs are similarly shaped as controls. (G). Endothelial cells elongate, becoming narrower as PCV lumens form by early tadpole stage (stage 35/36) control embryos. (H). Endothelial cells of the PCVs retain their polygonal morphology in early tadpole stage (stage 35/36) EGFL7-depleted embryos. 3–4 embryos from each condition/stage were assessed from at least three independent injection batches at the same position along the anterior-posterior axis of the embryo.
	Fig 6. EGFL7 is required for proper reorganization of tight junctions.(A-H). Representative confocal images of transverse sections of the dorsal aorta (DA) and posterior cardinal veins (PCV) stained with ZO-1 (red), GFP to mark cell membranes (MEM-GFP; green), and DAPI to mark nuclei (blue). Phase contrast images for the PCVs represent the Erg in situ signal. All images taken at 63x magnification with scale bars indicating 20 μm. Dotted white and red lines in all panels delineate the endothelial cells comprising each vessel. As anatomical references, the hypochord in (A-D) and the kidney in (E-H) are indicated by solid white lines. (A). ZO-1 localizes to tight junctions between endothelial cells of the DA in late tailbud stage (stage 33/34) control embryos. (B). ZO-1 tight junctions between endothelial cells of the DA in late tailbud stage (stage 33/34) EGFL7-depleted embryos appear similar to controls. (C). Tight junctions are redistributed to distinct puncta between endothelial cells at the periphery of the lumen in early tadpole stage (stage 35/36) control embryos. (D). Tight junctions are retained between endothelial cells of the DA in early tadpole stage (stage 35/36) EGFL7-depleted embryos. (E). Tight junctions assemble along the cord center between endothelial cells of the PCV in late tailbud stage (stage 33/34) control embryos. (F). Similar to controls, tight junctions assemble between adjacent endothelial cells of the PCV in late tailbud stage (stage 33/34) EGFL7-depleted embryos. (G). Tight junctions are redistributed to the periphery of the lumenized PCV and appear as distinct points of cell-cell contact in early tadpole stage (stage 35/36) control embryos. (H). Tight junctions are retained along the cord center of the PCV in early tadpole stage (stage 35/36) EGFL7-depleted embryos. 3–4 embryos from each condition/stage were assessed from at least 3–4 independent injection batches at the same position along the anterior-posterior axis of the embryo.
	Fig 7. EGFL7 is required for junctional reorganization but not for the hierarchical assembly of tight junctions.(A-H). Representative confocal images of transverse sections of the dorsal aorta (DA) and posterior cardinal veins (PCV) stained with Claudin-5 (red), GFP to mark cell membranes (MEM-GFP; green), and DAPI to mark nuclei (blue). Phase contrast images for the PCVs represent the Erg in situ signal. All images taken at 63x magnification with scale bars indicating 20 μm. Dotted white and red lines in all panels delineate the endothelial cells comprising each vessel. As anatomical references, the hypochord in (A-D) and the kidney in (E-H) are indicated by solid white lines. (A-B). Claudin-5 expression is absent from endothelial cells of the DA in late tailbud stage (stage 33/34) control and EGFL7-depleted embryos. (C). Claudin-5 localizes to tight junctions between endothelial cells once the DA lumen has formed in early tadpole stage (stage 35/36) control embryos. (D). Claudin-5 expression is apparent in tight junctions between EGFL7-depleted endothelial cells of the DA despite failed lumen formation at early tadpole stage (stage 35/36). (E-F). Claudin-5 expression is absent from endothelial cells of the PCV in late tailbud stage (stage 33/34) control and EGFL7-depleted embryos. (G). Claudin-5 localizes to distinct tight junctions between endothelial cells around the periphery of the PCV lumen in early tadpole stage (stage 35/36) control embryos. (H). Claudin-5 localizes to tight junctions along endothelial cell contacts within the PCV of early tadpole stage (stage 35/36) EGFL7-depleted embryos. 3–4 embryos from each condition/stage were assessed from at least three independent injection batches at the same position along the anterior-posterior axis of the embryo.
	Fig 1. Vascular lumen formation proceeds independently of circulation in Xenopus.(A-B). In situ hybridization with endothelial-specific Erg followed by sectioning was performed to determine the time course of vascular lumen formation of the dorsal aorta (DA) and posterior cardinal veins (PCV) in Xenopus. (A). Endothelial cells are coalesced together at the correct positions of the DA and PCVs in late tailbud stage (stage 33/34) control embryos. (B). Lumenized DA and PCVs become apparent by early tadpole stage (stage 35/36) in control embryos. 3–4 embryos from each condition/stage were assessed from at least three independent injection batches at the same position along the anterior-posterior axis of the embryo. (C-D). In situ hybridization with Erg followed by sectioning. (C). Transverse section of an early tadpole stage (stage 35/36) wildtype embryo depicting lumenized DA and PCVs. (D). Following the removal of the anterior and heart of early tailbud embryos, explants were cultured until early tadpole stage (stage 35/36) and processed as indicated above. PCV and DA lumens readily form in the absence of a functioning heart or circulatory system. 3–4 embryos from each condition were assessed from two independent experiments. Top image of each panel was taken at 20x magnification. Black boxes correspond to enlarged images of each vessel displayed below. Scale bars represent 20 μm.

Argaw, VEGF-mediated disruption of endothelial CLN-5 promotes blood-brain barrier breakdown. 2009, Pubmed

Argaw, VEGF-mediated disruption of endothelial CLN-5 promotes blood-brain barrier breakdown. 2009, Pubmed
Assémat, Polarity complex proteins. 2008, Pubmed
Baluk, Abnormalities of basement membrane on blood vessels and endothelial sprouts in tumors. 2003, Pubmed
Bayless, The Cdc42 and Rac1 GTPases are required for capillary lumen formation in three-dimensional extracellular matrices. 2002, Pubmed
Bazzoni, Endothelial cell-to-cell junctions: molecular organization and role in vascular homeostasis. 2004, Pubmed
Blum, Complex cell rearrangements during intersegmental vessel sprouting and vessel fusion in the zebrafish embryo. 2008, Pubmed
Brown, Tight junction protein expression and barrier properties of immortalized mouse brain microvessel endothelial cells. 2007, Pubmed
Campagnolo, EGFL7 is a chemoattractant for endothelial cells and is up-regulated in angiogenesis and arterial injury. 2005, Pubmed
Carmeliet, Principles and mechanisms of vessel normalization for cancer and other angiogenic diseases. 2011, Pubmed
Charpentier, CASZ1 promotes vascular assembly and morphogenesis through the direct regulation of an EGFL7/RhoA-mediated pathway. 2013, Pubmed , Xenbase
Charpentier, Cellular and molecular mechanisms underlying blood vessel lumen formation. 2014, Pubmed
Chen, The Par3/Par6/aPKC complex and epithelial cell polarity. 2013, Pubmed
Cherry, Codon usage table for Xenopus laevis. 1992, Pubmed , Xenbase
Chrzanowska-Wodnicka, Rho-stimulated contractility drives the formation of stress fibers and focal adhesions. 1996, Pubmed
Ciau-Uitz, VEGFA-dependent and -independent pathways synergise to drive Scl expression and initiate programming of the blood stem cell lineage in Xenopus. 2013, Pubmed , Xenbase
Ciau-Uitz, Distinct origins of adult and embryonic blood in Xenopus. 2000, Pubmed , Xenbase
Cleaver, Endoderm patterning by the notochord: development of the hypochord in Xenopus. 2000, Pubmed , Xenbase
Cleaver, Neovascularization of the Xenopus embryo. 1997, Pubmed , Xenbase
Cleaver, VEGF mediates angioblast migration during development of the dorsal aorta in Xenopus. 1998, Pubmed , Xenbase
Davis, Endothelial extracellular matrix: biosynthesis, remodeling, and functions during vascular morphogenesis and neovessel stabilization. 2005, Pubmed
Davis, An alpha 2 beta 1 integrin-dependent pinocytic mechanism involving intracellular vacuole formation and coalescence regulates capillary lumen and tube formation in three-dimensional collagen matrix. 1996, Pubmed
Dejana, The control of vascular integrity by endothelial cell junctions: molecular basis and pathological implications. 2009, Pubmed
Doherty, A flk-1 promoter/enhancer reporter transgenic Xenopus laevis generated using the Sleeping Beauty transposon system: an in vivo model for vascular studies. 2007, Pubmed , Xenbase
Eilken, Dynamics of endothelial cell behavior in sprouting angiogenesis. 2010, Pubmed
Fan, The expression of Egfl7 in human normal tissues and epithelial tumors. 2013, Pubmed
Fehon, Organizing the cell cortex: the role of ERM proteins. 2010, Pubmed
Fitch, Egfl7, a novel epidermal growth factor-domain gene expressed in endothelial cells. 2004, Pubmed
Flamme, Molecular mechanisms of vasculogenesis and embryonic angiogenesis. 1997, Pubmed
Goel, Vascular normalization as a therapeutic strategy for malignant and nonmalignant disease. 2012, Pubmed
Harland, In situ hybridization: an improved whole-mount method for Xenopus embryos. 1991, Pubmed , Xenbase
Hartsock, Adherens and tight junctions: structure, function and connections to the actin cytoskeleton. 2008, Pubmed
Helker, The zebrafish common cardinal veins develop by a novel mechanism: lumen ensheathment. 2013, Pubmed
Herbert, Molecular control of endothelial cell behaviour during blood vessel morphogenesis. 2011, Pubmed
Herwig, Distinct cellular mechanisms of blood vessel fusion in the zebrafish embryo. 2011, Pubmed
Iden, A distinct PAR complex associates physically with VE-cadherin in vertebrate endothelial cells. 2006, Pubmed
Imamura, Functional domains of alpha-catenin required for the strong state of cadherin-based cell adhesion. 1999, Pubmed
Itoh, Involvement of ZO-1 in cadherin-based cell adhesion through its direct binding to alpha catenin and actin filaments. 1997, Pubmed
Jin, Cellular and molecular analyses of vascular tube and lumen formation in zebrafish. 2005, Pubmed , Xenbase
Johnson, Anti-EGFL7 antibodies enhance stress-induced endothelial cell death and anti-VEGF efficacy. 2013, Pubmed
Kamei, Endothelial tubes assemble from intracellular vacuoles in vivo. 2006, Pubmed
Kau, Dual contribution of embryonic ventral blood island and dorsal lateral plate mesoderm during ontogeny of hemopoietic cells in Xenopus laevis. 1983, Pubmed , Xenbase
Kucera, Ancestral vascular lumen formation via basal cell surfaces. 2009, Pubmed
Lammert, Vascular lumen formation. 2012, Pubmed
Lampugnani, CCM1 regulates vascular-lumen organization by inducing endothelial polarity. 2010, Pubmed
Lelièvre, VE-statin/egfl7 regulates vascular elastogenesis by interacting with lysyl oxidases. 2008, Pubmed
Lenard, In vivo analysis reveals a highly stereotypic morphogenetic pathway of vascular anastomosis. 2013, Pubmed
Levine, Fluorescent labeling of endothelial cells allows in vivo, continuous characterization of the vascular development of Xenopus laevis. 2003, Pubmed , Xenbase
Lizama, Polarizing pathways: balancing endothelial polarity, permeability, and lumen formation. 2013, Pubmed
Lucitti, Vascular remodeling of the mouse yolk sac requires hemodynamic force. 2007, Pubmed
Maddox, RhoA is required for cortical retraction and rigidity during mitotic cell rounding. 2003, Pubmed
Mandel, The BMP pathway acts to directly regulate Tbx20 in the developing heart. 2010, Pubmed , Xenbase
Marcelo, Regulation of endothelial cell differentiation and specification. 2013, Pubmed
Meadows, Anti-VEGF therapies in the clinic. 2012, Pubmed
Morita, Endothelial claudin: claudin-5/TMVCF constitutes tight junction strands in endothelial cells. 1999, Pubmed
Nakagawa, A new blood-brain barrier model using primary rat brain endothelial cells, pericytes and astrocytes. 2009, Pubmed
Nichol, Impaired angiogenesis and altered Notch signaling in mice overexpressing endothelial Egfl7. 2010, Pubmed
Nichol, EGFL7: a unique angiogenic signaling factor in vascular development and disease. 2012, Pubmed
Nielsen, Novel functions of the CD34 family. 2008, Pubmed
Nikolic, EGFL7 meets miRNA-126: an angiogenesis alliance. 2010, Pubmed
Nitta, Size-selective loosening of the blood-brain barrier in claudin-5-deficient mice. 2003, Pubmed
Pardanaud, Two distinct endothelial lineages in ontogeny, one of them related to hemopoiesis. 1996, Pubmed
Park, Subcellular localization and signaling properties of dishevelled in developing vertebrate embryos. 2005, Pubmed , Xenbase
Parker, The endothelial-cell-derived secreted factor Egfl7 regulates vascular tube formation. 2004, Pubmed
Potente, Basic and therapeutic aspects of angiogenesis. 2011, Pubmed
Risau, Mechanisms of angiogenesis. 1997, Pubmed
Sato, Notch mediates the segmental specification of angioblasts in somites and their directed migration toward the dorsal aorta in avian embryos. 2008, Pubmed
Showell, Developmental expression patterns of Tbx1, Tbx2, Tbx5, and Tbx20 in Xenopus tropicalis. 2006, Pubmed , Xenbase
Soncin, VE-statin, an endothelial repressor of smooth muscle cell migration. 2003, Pubmed
Stratman, Pericyte recruitment during vasculogenic tube assembly stimulates endothelial basement membrane matrix formation. 2009, Pubmed
Strilić, The molecular basis of vascular lumen formation in the developing mouse aorta. 2009, Pubmed
Strilić, Electrostatic cell-surface repulsion initiates lumen formation in developing blood vessels. 2010, Pubmed
Swift, Arterial-venous specification during development. 2009, Pubmed
Tandon, Morpholino injection in Xenopus. 2012, Pubmed , Xenbase
Tandon, Tcf21 regulates the specification and maturation of proepicardial cells. 2013, Pubmed , Xenbase
Trindade, Overexpression of delta-like 4 induces arterialization and attenuates vessel formation in developing mouse embryos. 2008, Pubmed
Udan, Dynamic responses of endothelial cells to changes in blood flow during vascular remodeling of the mouse yolk sac. 2013, Pubmed
Udan, Understanding vascular development. 2013, Pubmed
Vokes, Endoderm is required for vascular endothelial tube formation, but not for angioblast specification. 2002, Pubmed , Xenbase
Walmsley, Adult and embryonic blood and endothelium derive from distinct precursor populations which are differentially programmed by BMP in Xenopus. 2002, Pubmed , Xenbase
Wang, Moesin1 and Ve-cadherin are required in endothelial cells during in vivo tubulogenesis. 2010, Pubmed
Welti, Recent molecular discoveries in angiogenesis and antiangiogenic therapies in cancer. 2013, Pubmed
Xie, A novel transgenic zebrafish model for blood-brain and blood-retinal barrier development. 2010, Pubmed
Xu, Tubulogenesis during blood vessel formation. 2011, Pubmed , Xenbase
Xu, Blood vessel tubulogenesis requires Rasip1 regulation of GTPase signaling. 2011, Pubmed , Xenbase
Yousif, Laminin isoforms in endothelial and perivascular basement membranes. 2013, Pubmed
Zhong, Combinatory action of VEGFR2 and MAP kinase pathways maintains endothelial-cell integrity. 2011, Pubmed