TY - JOUR
T1 - Endothelial Cell-Specific FGD5 Involvement in Vascular Pruning Defines Neovessel Fate in Mice
AU - Cheng, Caroline
AU - Haasdijk, Remco
AU - Tempel, Dennie
AU - van de Kamp, Esther H. M.
AU - Herpers, Robert
AU - Bos, Frank
AU - Den Dekker, Wijnand K.
AU - Blonden, Lau A. J.
AU - de Jong, Renate
AU - Burgisser, Petra E.
AU - Chrifi, Ihsan
AU - Biessen, Erik A. L.
AU - Dimmeler, Stefanie
AU - Schulte-Merker, Stefan
AU - Duckers, Henricus J.
PY - 2012/6/26
Y1 - 2012/6/26
N2 - Background-New vessel formation contributes to organ development during embryogenesis and tissue repair in response to mechanical damage, inflammation, and ischemia in adult organisms. Early angiogenesis includes formation of an excessive primitive network that needs to be reorganized into a secondary vascular network with higher hierarchical structure. Vascular pruning, the removal of aberrant neovessels by apoptosis, is a vital step in this process. Although multiple molecular pathways for early angiogenesis have been identified, little is known about the genetic regulators of secondary network development. Methods and Results-Using a transcriptomics approach, we identified a new endothelial specific gene named FYVE, RhoGEF, and PH domain-containing 5 (FGD5) that plays a crucial role in vascular pruning. Loss-and gain-of-function studies demonstrate that FGD5 inhibits neovascularization, indicated by in vitro tube-formation, aortic-ring, and coated-bead assays and by in vivo coated-bead plug assays and studies in the murine retina model. FGD5 promotes apoptosis-induced vaso-obliteration via induction of the hey1-p53 pathway by direct binding and activation of cdc42. Indeed, FGD5 correlates with apoptosis in endothelial cells during vascular remodeling and was linked to rising p21(CIP1) levels in aging mice. Conclusion-We have identified FGD5 as a novel genetic regulator of vascular pruning by activation of endothelial cell-targeted apoptosis. (Circulation. 2012;125:3142-3158.)
AB - Background-New vessel formation contributes to organ development during embryogenesis and tissue repair in response to mechanical damage, inflammation, and ischemia in adult organisms. Early angiogenesis includes formation of an excessive primitive network that needs to be reorganized into a secondary vascular network with higher hierarchical structure. Vascular pruning, the removal of aberrant neovessels by apoptosis, is a vital step in this process. Although multiple molecular pathways for early angiogenesis have been identified, little is known about the genetic regulators of secondary network development. Methods and Results-Using a transcriptomics approach, we identified a new endothelial specific gene named FYVE, RhoGEF, and PH domain-containing 5 (FGD5) that plays a crucial role in vascular pruning. Loss-and gain-of-function studies demonstrate that FGD5 inhibits neovascularization, indicated by in vitro tube-formation, aortic-ring, and coated-bead assays and by in vivo coated-bead plug assays and studies in the murine retina model. FGD5 promotes apoptosis-induced vaso-obliteration via induction of the hey1-p53 pathway by direct binding and activation of cdc42. Indeed, FGD5 correlates with apoptosis in endothelial cells during vascular remodeling and was linked to rising p21(CIP1) levels in aging mice. Conclusion-We have identified FGD5 as a novel genetic regulator of vascular pruning by activation of endothelial cell-targeted apoptosis. (Circulation. 2012;125:3142-3158.)
KW - angiogenesis-inducing agents
KW - apoptosis
KW - endothelium
KW - FGD5
KW - models, animal
U2 - 10.1161/CIRCULATIONAHA.111.064030
DO - 10.1161/CIRCULATIONAHA.111.064030
M3 - Article
C2 - 22661514
SN - 0009-7322
VL - 125
SP - 3142
EP - 3159
JO - Circulation
JF - Circulation
IS - 25
ER -