Your search keyword '"Cruys, Bert"' showing total 9 results

1. Defective endothelial cell migration in the absence of Cdc42 leads to capillary-venous malformations

Author

Laviña, Bàrbara, Castro, Marco, Niaudet, Colin, Cruys, Bert, Álvarez-Aznar, Alberto, Carmeliet, Peter, Bentley, Katie, Brakebusch, Cord, Betsholtz, Christer, Gängel, Konstantin, Laviña, Bàrbara, Castro, Marco, Niaudet, Colin, Cruys, Bert, Álvarez-Aznar, Alberto, Carmeliet, Peter, Bentley, Katie, Brakebusch, Cord, Betsholtz, Christer, and Gängel, Konstantin

Abstract

Formation and homeostasis of the vascular system requires several coordinated cellular functions, but their precise interplay during development and their relative importance for vascular pathologies remain poorly understood. Here, we investigated the endothelial functions regulated by Cdc42 and their in vivo relevance during angiogenic sprouting and vascular morphogenesis in the postnatal mouse retina. We found that Cdc42 is required for endothelial tip cell selection, directed cell migration and filopodia formation, but dispensable for cell proliferation or apoptosis. Although the loss of Cdc42 seems generally compatible with apical-basal polarization and lumen formation in retinal blood vessels, it leads to defective endothelial axial polarization and to the formation of severe vascular malformations in capillaries and veins. Tracking of Cdc42-depleted endothelial cells in mosaic retinas suggests that these capillary-venous malformations arise as a consequence of defective cell migration, when endothelial cells that proliferate at normal rates are unable to re-distribute within the vascular network.

Published

2018

2. Defective endothelial cell migration in the absence of Cdc42 leads to capillary-venous malformations

Author

Laviña, Bàrbara, Castro, Marco, Niaudet, Colin, Cruys, Bert, Álvarez-Aznar, Alberto, Carmeliet, Peter, Bentley, Katie, Brakebusch, Cord, Betsholtz, Christer, Gaengel, Konstantin, Laviña, Bàrbara, Castro, Marco, Niaudet, Colin, Cruys, Bert, Álvarez-Aznar, Alberto, Carmeliet, Peter, Bentley, Katie, Brakebusch, Cord, Betsholtz, Christer, and Gaengel, Konstantin

Abstract

Formation and homeostasis of the vascular system requires several coordinated cellular functions, but their precise interplay during development and their relative importance for vascular pathologies remain poorly understood. Here, we investigated the endothelial functions regulated by Cdc42 and their in vivo relevance during angiogenic sprouting and vascular morphogenesis in the postnatal mouse retina. We found that Cdc42 is required for endothelial tip cell selection, directed cell migration and filopodia formation, but dispensable for cell proliferation or apoptosis. Although the loss of Cdc42 seems generally compatible with apical-basal polarization and lumen formation in retinal blood vessels, it leads to defective endothelial axial polarization and to the formation of severe vascular malformations in capillaries and veins. Tracking of Cdc42-depleted endothelial cells in mosaic retinas suggests that these capillary-venous malformations arise as a consequence of defective cell migration, when endothelial cells that proliferate at normal rates are unable to re-distribute within the vascular network.

Published

2018

3. Glycolytic regulation of cell rearrangement in angiogenesis

Author

Cruys, Bert, Wong, Brian W., Kuchnio, Anna, Verdegem, Dries, Cantelmo, Anna Rita, Conradi, Lena-Christin, Vandekeere, Saar, Bouche, Ann, Cornelissen, Ivo, Vinckier, Stefan, Merks, Roeland M. H., Dejana, Elisabetta, Gerhardt, Holger, Dewerchin, Mieke, Bentley, Katie, Carmeliet, Peter, Cruys, Bert, Wong, Brian W., Kuchnio, Anna, Verdegem, Dries, Cantelmo, Anna Rita, Conradi, Lena-Christin, Vandekeere, Saar, Bouche, Ann, Cornelissen, Ivo, Vinckier, Stefan, Merks, Roeland M. H., Dejana, Elisabetta, Gerhardt, Holger, Dewerchin, Mieke, Bentley, Katie, and Carmeliet, Peter

Abstract

During vessel sprouting, endothelial cells (ECs) dynamically rearrange positions in the sprout to compete for the tip position. We recently identified a key role for the glycolytic activator PFKFB3 in vessel sprouting by regulating cytoskeleton remodelling, migration and tip cell competitiveness. It is, however, unknown how glycolysis regulates EC rearrangement during vessel sprouting. Here we report that computational simulations, validated by experimentation, predict that glycolytic production of ATP drives EC rearrangement by promoting filopodia formation and reducing intercellular adhesion. Notably, the simulations correctly predicted that blocking PFKFB3 normalizes the disturbed EC rearrangement in high VEGF conditions, as occurs during pathological angiogenesis. This interdisciplinary study integrates EC metabolism in vessel sprouting, yielding mechanistic insight in the control of vessel sprouting by glycolysis, and suggesting anti-glycolytic therapy for vessel normalization in cancer and non-malignant diseases.

Published

2016

4. Glycolytic regulation of cell rearrangement in angiogenesis

Author

Cruys, Bert, Wong, Brian W., Kuchnio, Anna, Verdegem, Dries, Cantelmo, Anna Rita, Conradi, Lena-Christin, Vandekeere, Saar, Bouche, Ann, Cornelissen, Ivo, Vinckier, Stefan, Merks, Roeland M. H., Dejana, Elisabetta, Gerhardt, Holger, Dewerchin, Mieke, Bentley, Katie, Carmeliet, Peter, Cruys, Bert, Wong, Brian W., Kuchnio, Anna, Verdegem, Dries, Cantelmo, Anna Rita, Conradi, Lena-Christin, Vandekeere, Saar, Bouche, Ann, Cornelissen, Ivo, Vinckier, Stefan, Merks, Roeland M. H., Dejana, Elisabetta, Gerhardt, Holger, Dewerchin, Mieke, Bentley, Katie, and Carmeliet, Peter

Abstract

During vessel sprouting, endothelial cells (ECs) dynamically rearrange positions in the sprout to compete for the tip position. We recently identified a key role for the glycolytic activator PFKFB3 in vessel sprouting by regulating cytoskeleton remodelling, migration and tip cell competitiveness. It is, however, unknown how glycolysis regulates EC rearrangement during vessel sprouting. Here we report that computational simulations, validated by experimentation, predict that glycolytic production of ATP drives EC rearrangement by promoting filopodia formation and reducing intercellular adhesion. Notably, the simulations correctly predicted that blocking PFKFB3 normalizes the disturbed EC rearrangement in high VEGF conditions, as occurs during pathological angiogenesis. This interdisciplinary study integrates EC metabolism in vessel sprouting, yielding mechanistic insight in the control of vessel sprouting by glycolysis, and suggesting anti-glycolytic therapy for vessel normalization in cancer and non-malignant diseases.

Published

2016

5. Glycolytic regulation of cell rearrangement in angiogenesis

Author

Cruys, Bert, Wong, Brian W., Kuchnio, Anna, Verdegem, Dries, Cantelmo, Anna Rita, Conradi, Lena-Christin, Vandekeere, Saar, Bouche, Ann, Cornelissen, Ivo, Vinckier, Stefan, Merks, Roeland M. H., Dejana, Elisabetta, Gerhardt, Holger, Dewerchin, Mieke, Bentley, Katie, Carmeliet, Peter, Cruys, Bert, Wong, Brian W., Kuchnio, Anna, Verdegem, Dries, Cantelmo, Anna Rita, Conradi, Lena-Christin, Vandekeere, Saar, Bouche, Ann, Cornelissen, Ivo, Vinckier, Stefan, Merks, Roeland M. H., Dejana, Elisabetta, Gerhardt, Holger, Dewerchin, Mieke, Bentley, Katie, and Carmeliet, Peter

Abstract

During vessel sprouting, endothelial cells (ECs) dynamically rearrange positions in the sprout to compete for the tip position. We recently identified a key role for the glycolytic activator PFKFB3 in vessel sprouting by regulating cytoskeleton remodelling, migration and tip cell competitiveness. It is, however, unknown how glycolysis regulates EC rearrangement during vessel sprouting. Here we report that computational simulations, validated by experimentation, predict that glycolytic production of ATP drives EC rearrangement by promoting filopodia formation and reducing intercellular adhesion. Notably, the simulations correctly predicted that blocking PFKFB3 normalizes the disturbed EC rearrangement in high VEGF conditions, as occurs during pathological angiogenesis. This interdisciplinary study integrates EC metabolism in vessel sprouting, yielding mechanistic insight in the control of vessel sprouting by glycolysis, and suggesting anti-glycolytic therapy for vessel normalization in cancer and non-malignant diseases.

Published

2016

6. Deletion or Inhibition of the Oxygen Sensor PHD1 Protects against Ischemic Stroke via Reprogramming of Neuronal Metabolism.

Author

Quaegebeur, Annelies, Quaegebeur, Annelies, Segura, Inmaculada, Schmieder, Roberta, Verdegem, Dries, Decimo, Ilaria, Bifari, Francesco, Dresselaers, Tom, Eelen, Guy, Ghosh, Debapriva, Davidson, Shawn M, Schoors, Sandra, Broekaert, Dorien, Cruys, Bert, Govaerts, Kristof, De Legher, Carla, Bouché, Ann, Schoonjans, Luc, Ramer, Matt S, Hung, Gene, Bossaert, Goele, Cleveland, Don W, Himmelreich, Uwe, Voets, Thomas, Lemmens, Robin, Bennett, C Frank, Robberecht, Wim, De Bock, Katrien, Dewerchin, Mieke, Ghesquière, Bart, Fendt, Sarah-Maria, Carmeliet, Peter, Quaegebeur, Annelies, Quaegebeur, Annelies, Segura, Inmaculada, Schmieder, Roberta, Verdegem, Dries, Decimo, Ilaria, Bifari, Francesco, Dresselaers, Tom, Eelen, Guy, Ghosh, Debapriva, Davidson, Shawn M, Schoors, Sandra, Broekaert, Dorien, Cruys, Bert, Govaerts, Kristof, De Legher, Carla, Bouché, Ann, Schoonjans, Luc, Ramer, Matt S, Hung, Gene, Bossaert, Goele, Cleveland, Don W, Himmelreich, Uwe, Voets, Thomas, Lemmens, Robin, Bennett, C Frank, Robberecht, Wim, De Bock, Katrien, Dewerchin, Mieke, Ghesquière, Bart, Fendt, Sarah-Maria, and Carmeliet, Peter

Abstract

The oxygen-sensing prolyl hydroxylase domain proteins (PHDs) regulate cellular metabolism, but their role in neuronal metabolism during stroke is unknown. Here we report that PHD1 deficiency provides neuroprotection in a murine model of permanent brain ischemia. This was not due to an increased collateral vessel network. Instead, PHD1(-/-) neurons were protected against oxygen-nutrient deprivation by reprogramming glucose metabolism. Indeed, PHD1(-/-) neurons enhanced glucose flux through the oxidative pentose phosphate pathway by diverting glucose away from glycolysis. As a result, PHD1(-/-) neurons increased their redox buffering capacity to scavenge oxygen radicals in ischemia. Intracerebroventricular injection of PHD1-antisense oligonucleotides reduced the cerebral infarct size and neurological deficits following stroke. These data identify PHD1 as a regulator of neuronal metabolism and a potential therapeutic target in ischemic stroke.

Published

2016

7. Glycolytic regulation of cell rearrangement in angiogenesis

Author

Cruys, Bert, Wong, Brian W., Kuchnio, Anna, Verdegem, Dries, Cantelmo, Anna Rita, Conradi, Lena-Christin, Vandekeere, Saar, Bouche, Ann, Cornelissen, Ivo, Vinckier, Stefan, Merks, Roeland M. H., Dejana, Elisabetta, Gerhardt, Holger, Dewerchin, Mieke, Bentley, Katie, Carmeliet, Peter, Cruys, Bert, Wong, Brian W., Kuchnio, Anna, Verdegem, Dries, Cantelmo, Anna Rita, Conradi, Lena-Christin, Vandekeere, Saar, Bouche, Ann, Cornelissen, Ivo, Vinckier, Stefan, Merks, Roeland M. H., Dejana, Elisabetta, Gerhardt, Holger, Dewerchin, Mieke, Bentley, Katie, and Carmeliet, Peter

Abstract

During vessel sprouting, endothelial cells (ECs) dynamically rearrange positions in the sprout to compete for the tip position. We recently identified a key role for the glycolytic activator PFKFB3 in vessel sprouting by regulating cytoskeleton remodelling, migration and tip cell competitiveness. It is, however, unknown how glycolysis regulates EC rearrangement during vessel sprouting. Here we report that computational simulations, validated by experimentation, predict that glycolytic production of ATP drives EC rearrangement by promoting filopodia formation and reducing intercellular adhesion. Notably, the simulations correctly predicted that blocking PFKFB3 normalizes the disturbed EC rearrangement in high VEGF conditions, as occurs during pathological angiogenesis. This interdisciplinary study integrates EC metabolism in vessel sprouting, yielding mechanistic insight in the control of vessel sprouting by glycolysis, and suggesting anti-glycolytic therapy for vessel normalization in cancer and non-malignant diseases.

Published

2016

8. Glycolytic regulation of cell rearrangement in angiogenesis

Author

Cruys, Bert, Wong, Brian W., Kuchnio, Anna, Verdegem, Dries, Cantelmo, Anna Rita, Conradi, Lena-Christin, Vandekeere, Saar, Bouche, Ann, Cornelissen, Ivo, Vinckier, Stefan, Merks, Roeland M. H., Dejana, Elisabetta, Gerhardt, Holger, Dewerchin, Mieke, Bentley, Katie, Carmeliet, Peter, Cruys, Bert, Wong, Brian W., Kuchnio, Anna, Verdegem, Dries, Cantelmo, Anna Rita, Conradi, Lena-Christin, Vandekeere, Saar, Bouche, Ann, Cornelissen, Ivo, Vinckier, Stefan, Merks, Roeland M. H., Dejana, Elisabetta, Gerhardt, Holger, Dewerchin, Mieke, Bentley, Katie, and Carmeliet, Peter

Abstract

During vessel sprouting, endothelial cells (ECs) dynamically rearrange positions in the sprout to compete for the tip position. We recently identified a key role for the glycolytic activator PFKFB3 in vessel sprouting by regulating cytoskeleton remodelling, migration and tip cell competitiveness. It is, however, unknown how glycolysis regulates EC rearrangement during vessel sprouting. Here we report that computational simulations, validated by experimentation, predict that glycolytic production of ATP drives EC rearrangement by promoting filopodia formation and reducing intercellular adhesion. Notably, the simulations correctly predicted that blocking PFKFB3 normalizes the disturbed EC rearrangement in high VEGF conditions, as occurs during pathological angiogenesis. This interdisciplinary study integrates EC metabolism in vessel sprouting, yielding mechanistic insight in the control of vessel sprouting by glycolysis, and suggesting anti-glycolytic therapy for vessel normalization in cancer and non-malignant diseases.

Published

2016

9. Role of PFKFB3-driven glycolysis in vessel sprouting.

Author

UCL - SSS/DDUV - Institut de Duve, De Bock, Katrien, Georgiadou, Maria, Schoors, Sandra, Kuchnio, Anna, Wong, Brian W, Cantelmo, Anna Rita, Quaegebeur, Annelies, Ghesquière, Bart, Cauwenberghs, Sandra, Eelen, Guy, Phng, Li-Kun, Betz, Inge, Tembuyser, Bieke, Brepoels, Katleen, Welti, Jonathan, Geudens, Ilse, Segura, Inmaculada, Cruys, Bert, Bifari, Franscesco, Decimo, Ilaria, Blanco, Raquel, Wyns, Sabine, Vangindertael, Jeroen, Rocha, Susana, Collins, Russel T, Munck, Sebastian, Daelemans, Dirk, Imamura, Hiromi, Devlieger, Roland, Rider, Mark, Van Veldhoven, Paul P, Schuit, Frans, Bartrons, Ramon, Hofkens, Johan, Fraisl, Peter, Telang, Sucheta, Deberardinis, Ralph J, Schoonjans, Luc, Vinckier, Stefan, Chesney, Jason, Gerhardt, Holger, Dewerchin, Mieke, Carmeliet, Peter, UCL - SSS/DDUV - Institut de Duve, De Bock, Katrien, Georgiadou, Maria, Schoors, Sandra, Kuchnio, Anna, Wong, Brian W, Cantelmo, Anna Rita, Quaegebeur, Annelies, Ghesquière, Bart, Cauwenberghs, Sandra, Eelen, Guy, Phng, Li-Kun, Betz, Inge, Tembuyser, Bieke, Brepoels, Katleen, Welti, Jonathan, Geudens, Ilse, Segura, Inmaculada, Cruys, Bert, Bifari, Franscesco, Decimo, Ilaria, Blanco, Raquel, Wyns, Sabine, Vangindertael, Jeroen, Rocha, Susana, Collins, Russel T, Munck, Sebastian, Daelemans, Dirk, Imamura, Hiromi, Devlieger, Roland, Rider, Mark, Van Veldhoven, Paul P, Schuit, Frans, Bartrons, Ramon, Hofkens, Johan, Fraisl, Peter, Telang, Sucheta, Deberardinis, Ralph J, Schoonjans, Luc, Vinckier, Stefan, Chesney, Jason, Gerhardt, Holger, Dewerchin, Mieke, and Carmeliet, Peter

Abstract

Vessel sprouting by migrating tip and proliferating stalk endothelial cells (ECs) is controlled by genetic signals (such as Notch), but it is unknown whether metabolism also regulates this process. Here, we show that ECs relied on glycolysis rather than on oxidative phosphorylation for ATP production and that loss of the glycolytic activator PFKFB3 in ECs impaired vessel formation. Mechanistically, PFKFB3 not only regulated EC proliferation but also controlled the formation of filopodia/lamellipodia and directional migration, in part by compartmentalizing with F-actin in motile protrusions. Mosaic in vitro and in vivo sprouting assays further revealed that PFKFB3 overexpression overruled the pro-stalk activity of Notch, whereas PFKFB3 deficiency impaired tip cell formation upon Notch blockade, implying that glycolysis regulates vessel branching.

Published

2013