The paracrine effect of normoxic and hypoxic cancer secretions on blood-brain barrier endothelial cells

Rado, Mariam Abobaker. M.

January 2022

>Magister Scientiae - MSc / Cancer is the most common leading cause of death worldwide. Glioblastoma and breast cancer are the most aggressive solid tumour. The survival rate of these tumours depends on their ability to progress and spread. These cancers use their high proliferative capabilities for survival, increasing their malignancies. Glioblastoma is considered the most aggressive tumour initiated in the brain, whereas breast cancer is the most common metastatic cancer in the brain, both types of cancer are known as high infiltrated cancer and their invasiveness due to their capability to release factors that can alter the neighbouring cells to facilitate their progression.

Glioblastoma

Cancer

Breast cancer

Public health

Brain endothelial cells

Integration of an in vitro blood brain barrier model with organic electrochemical transistors / Intégration d’un model in vitro de barrière hémato-encéphalique avec des transistors organiques électrochimiques.

Bongo, Manuelle

29 September 2014

Dans les systèmes biologiques, les barrières tissulaires permettent le transport sélectif de molécules du sang au tissu approprié. Un exemple de barrière tissulaire est la barrière hémato-encéphalique (BHE). La BHE protège le cerveau du sang et maintient l'homéostasie du microenvironnement du cerveau, ce qui est essentiel à l'activité et à la fonction neuronale. La caractérisation de cette BHE est importante, car un dysfonctionnement de cette barrière est souvent révélateur de toxicité ou de maladie. Bien que le nombre d'articles publiés dans le domaine du développement et de la caractérisation de la BHE ait été multiplié ces dernières années, la validité des modèles utilisés est encore un sujet de débat. L'avènement de l'électronique organique a créé une occasion unique pour coupler les mondes de l'électronique et de la biologie, à l'aide de dispositifs tels que le transistor électrochimique organique (OECT). OECT constitue un outil très sensible et économique pour diagnostiquer l’intégrité d’une barrière tissulaire. Dans cette étude, nous avons tout d’abord développé trois différents modèles de BHE. Nous avons optimisé l’adhésion des cellules endothéliales cérébrales sur la matière active du transistor. Nous avons ainsi pu établir l'intégration des OECTs avec des cellules immortalisées humaines micro vasculaires cérébrales endothéliales (h CMEC/D3) en tant que modèle in vitro de BHE. Nous avons démontré que la fonction de tissu de la BHE peut être détectée en utilisant cette nouvelle technique. En outre, par cette technique, une perturbation de la barrière (par exemple, provoquée par un composé toxique) pourra être détectée électriquement au moyen d'une mesure de courant. / In biological systems many tissue types have evolved a barrier function to selectively allow the transport of matter from the lumen to the tissue beneath; one example is the Blood Brain Barrier (BBB). The BBB protects the brain from the blood and maintains homeostasis of the brain microenvironment, which is crucial for neuronal activity and function. Characterization of the BBB is very important as its disruption or malfunction is often indicative of toxicity/disease. Though the number of published papers in the field of in vitro BBB has multiplied in recent years, the validity of the models used is still a subject of debate.The advent of organic electronics has created a unique opportunity to interface the worlds of electronics and biology, using devices such as the Organic ElectroChemical Transistor (OECT), which provide a very sensitive way to detect minute ionic currents in an electrolyte as the transistor amplifies the gate current.In this study, we test three different type of BBB in order to develop a stable BBB model. We optimize the adhesion of brain endothelial cell on OECT conducting polymer. We show the integration of OECTs with immortalized human cerebral microvascular endothelial cells as a model of human blood brain barrier, and demonstrate that the barrier tissue function can be detected. Moreover, by this technique, a disruption in the barrier (e.g. caused by a toxic compound) is assessed electrically through a measurement of the drain current. Results show the successful development and validation of an in vitro BBB model. Dynamic monitoring of the barrier properties of the BBB barrier tissue was possible using the OECT.

Barrière hémato-encéphalique

Intégrité

OECT

Blood Brain Barrier

Integrity

OECT

Brain endothelial cell

Chemical micropatterning of hyaluronic acid hydrogels for brain endothelial in vitro cell studies

Porras Hernández, Ana Maria

January 2022

The building blocks of human tissues are cells. The cells interact and respond to the characteristics of their local microenvironment. The cellular microenvironment is formed by three main components, the extracellular matrix, neighbouring cells and signalling molecules. Particularly, the extracellular matrix and neighbouring cells impose boundary conditions that limits the cell volume and cell spreading. However, these characteristics are often not present in traditional in vitro models, where cells experience a stiff and vast environment.   An approach to improve in vitro models is to use hydrogels, soft and highly hydrated polymers. Through chemical modifications, polymers naturally found in the extracellular matrix can be functionalized to form crosslinked hydrogels. Moreover, these functionalities can also be used to prepare micropatterns, micrometre sized cell adhesive areas on the hydrogels. These micropatterns guide the cell shape and permit the study of the cell response to these changes in shape, which has been observed in e.g. endothelial cells from various origins.   Taken all together, the aim of this work was to develop a hydrogel-based cell culture scaffold that permits the control of the spatial adhesion of brain endothelial cells in order to study the morphological effects on these cells and contribute to the understanding of the function of brain endothelial cells in health and disease.   This thesis demonstrates the functionalization of hyaluronic acid, a naturally occurring extracellular matrix polymer, to prepare photocrosslinkable hydrogels. Furthermore, through photolithography, micropatterns of cell adhesive peptides were prepared on these hydrogels. Brain microvascular endothelial cells, a highly specialized type of endothelial cells, adhered to the micropatterns, and the effect on their alignment depending on the micropatterned sized was studied. Furthermore, changes in their alignment were also observed when exposed to different glucose concentration.

Micropatterning

hydrogels

hyaluronic acid

brain endothelial cells

Engineering and Technology

Teknik och teknologier

In Vitro Functional Study of YES-Associated Protein (YAP) in Murine Brain Endothelial Cells under Normal and Ischemic Conditions

Al-Waili, Daniah I.

January 2015

No description available.

Pharmaceuticals

ischemic stroke

blood-brain barrier

YAP

brain endothelial cells

tight junction proteins

cell proliferation

Mechanisms of Hypoxia-Induced Neurovascular Remodeling in PlGF Knockout Mice

Freitas-Andrade, Moises

13 January 2012

Due to the high metabolic demand and low capacity for energy storage of the brain, neurons are vitally reliant on a constant oxygen supply. Under chronic mild hypoxic conditions (10% oxygen), angiogenesis is induced in the brain in an attempt to restore tissue oxygen tension to normal levels. In brain hypoxia, vascular endothelial growth factor (VEGF) plays a critical role in angiogenesis; however, the role of its homolog placental growth factor (PlGF) is unknown. Using PlGF knockout (PlGF-/-) mice exposed to whole body hypoxia (10% oxygen) for 7, 14 and 21-days, we show that PlGF-/- animals exhibit a delay in the angiogenic response of the brain to hypoxia. PlGF-/- microvessels had a significant increase in fibrinogen accumulation and extravasation, which correlated with disruption of the tight-junction protein claudin-5. These vessels displayed large lumens, were surrounded by reactive astrocytes, lacked mural cell coverage and endothelial VEGF expression, and regressed after 21 days of hypoxia. The lack of PlGF, in combination with reduced VEGF expression levels observed in the brain of PlGF-/- animals during the first 5 days of hypoxia, is likely the cause of the delayed angiogenic response and the prothrombotic phenotype of these mice. In vitro studies conducted to analyze mechanisms involved in the impaired angiogenic phenotype and enhanced astrocytic reactivity to hypoxia of PlGF-/- animals indicated that: i) PlGF-/- mouse brain endothelial cells exhibit alterations in intracellular signaling pathways associated with sprouting (ERK1/2) and vessel branching morphogenesis (GSK-3β) and ii) PlGF-/- astrocytes overexpress VEGF receptor-2 (VEGFR-2) which through activation of the ERK1/2 signaling pathway leads to a more proliferative astrocytic phenotype. These astrocytes were more resistant to oxygen and glucose deprivation (OGD) than PlGF+/+ astrocytes, a characteristic that was shown to be independent of the classical antiapoptotic VEGFR-2-dependent PI3K/Akt pathway. The findings presented in this thesis demonstrated a critical role of PlGF in vascular remodeling in the hypoxic brain.

Hypoxia

Astrocytes

Brain endothelial cells

Angiogenesis

Neurovascular

Placental growth factor

PlGF

VEGF

Chronic hypoxia

OGD

Brain angiogenesis

Mechanisms of Hypoxia-Induced Neurovascular Remodeling in PlGF Knockout Mice

Freitas-Andrade, Moises

13 January 2012

Due to the high metabolic demand and low capacity for energy storage of the brain, neurons are vitally reliant on a constant oxygen supply. Under chronic mild hypoxic conditions (10% oxygen), angiogenesis is induced in the brain in an attempt to restore tissue oxygen tension to normal levels. In brain hypoxia, vascular endothelial growth factor (VEGF) plays a critical role in angiogenesis; however, the role of its homolog placental growth factor (PlGF) is unknown. Using PlGF knockout (PlGF-/-) mice exposed to whole body hypoxia (10% oxygen) for 7, 14 and 21-days, we show that PlGF-/- animals exhibit a delay in the angiogenic response of the brain to hypoxia. PlGF-/- microvessels had a significant increase in fibrinogen accumulation and extravasation, which correlated with disruption of the tight-junction protein claudin-5. These vessels displayed large lumens, were surrounded by reactive astrocytes, lacked mural cell coverage and endothelial VEGF expression, and regressed after 21 days of hypoxia. The lack of PlGF, in combination with reduced VEGF expression levels observed in the brain of PlGF-/- animals during the first 5 days of hypoxia, is likely the cause of the delayed angiogenic response and the prothrombotic phenotype of these mice. In vitro studies conducted to analyze mechanisms involved in the impaired angiogenic phenotype and enhanced astrocytic reactivity to hypoxia of PlGF-/- animals indicated that: i) PlGF-/- mouse brain endothelial cells exhibit alterations in intracellular signaling pathways associated with sprouting (ERK1/2) and vessel branching morphogenesis (GSK-3β) and ii) PlGF-/- astrocytes overexpress VEGF receptor-2 (VEGFR-2) which through activation of the ERK1/2 signaling pathway leads to a more proliferative astrocytic phenotype. These astrocytes were more resistant to oxygen and glucose deprivation (OGD) than PlGF+/+ astrocytes, a characteristic that was shown to be independent of the classical antiapoptotic VEGFR-2-dependent PI3K/Akt pathway. The findings presented in this thesis demonstrated a critical role of PlGF in vascular remodeling in the hypoxic brain.

Hypoxia

Astrocytes

Brain endothelial cells

Angiogenesis

Neurovascular

Placental growth factor

PlGF

VEGF

Chronic hypoxia

OGD

Brain angiogenesis

Mechanisms of Hypoxia-Induced Neurovascular Remodeling in PlGF Knockout Mice

Freitas-Andrade, Moises

13 January 2012

Due to the high metabolic demand and low capacity for energy storage of the brain, neurons are vitally reliant on a constant oxygen supply. Under chronic mild hypoxic conditions (10% oxygen), angiogenesis is induced in the brain in an attempt to restore tissue oxygen tension to normal levels. In brain hypoxia, vascular endothelial growth factor (VEGF) plays a critical role in angiogenesis; however, the role of its homolog placental growth factor (PlGF) is unknown. Using PlGF knockout (PlGF-/-) mice exposed to whole body hypoxia (10% oxygen) for 7, 14 and 21-days, we show that PlGF-/- animals exhibit a delay in the angiogenic response of the brain to hypoxia. PlGF-/- microvessels had a significant increase in fibrinogen accumulation and extravasation, which correlated with disruption of the tight-junction protein claudin-5. These vessels displayed large lumens, were surrounded by reactive astrocytes, lacked mural cell coverage and endothelial VEGF expression, and regressed after 21 days of hypoxia. The lack of PlGF, in combination with reduced VEGF expression levels observed in the brain of PlGF-/- animals during the first 5 days of hypoxia, is likely the cause of the delayed angiogenic response and the prothrombotic phenotype of these mice. In vitro studies conducted to analyze mechanisms involved in the impaired angiogenic phenotype and enhanced astrocytic reactivity to hypoxia of PlGF-/- animals indicated that: i) PlGF-/- mouse brain endothelial cells exhibit alterations in intracellular signaling pathways associated with sprouting (ERK1/2) and vessel branching morphogenesis (GSK-3β) and ii) PlGF-/- astrocytes overexpress VEGF receptor-2 (VEGFR-2) which through activation of the ERK1/2 signaling pathway leads to a more proliferative astrocytic phenotype. These astrocytes were more resistant to oxygen and glucose deprivation (OGD) than PlGF+/+ astrocytes, a characteristic that was shown to be independent of the classical antiapoptotic VEGFR-2-dependent PI3K/Akt pathway. The findings presented in this thesis demonstrated a critical role of PlGF in vascular remodeling in the hypoxic brain.

Hypoxia

Astrocytes

Brain endothelial cells

Angiogenesis

Neurovascular

Placental growth factor

PlGF

VEGF

Chronic hypoxia

OGD

Brain angiogenesis

Mechanisms of Hypoxia-Induced Neurovascular Remodeling in PlGF Knockout Mice

Freitas-Andrade, Moises

January 2012

Due to the high metabolic demand and low capacity for energy storage of the brain, neurons are vitally reliant on a constant oxygen supply. Under chronic mild hypoxic conditions (10% oxygen), angiogenesis is induced in the brain in an attempt to restore tissue oxygen tension to normal levels. In brain hypoxia, vascular endothelial growth factor (VEGF) plays a critical role in angiogenesis; however, the role of its homolog placental growth factor (PlGF) is unknown. Using PlGF knockout (PlGF-/-) mice exposed to whole body hypoxia (10% oxygen) for 7, 14 and 21-days, we show that PlGF-/- animals exhibit a delay in the angiogenic response of the brain to hypoxia. PlGF-/- microvessels had a significant increase in fibrinogen accumulation and extravasation, which correlated with disruption of the tight-junction protein claudin-5. These vessels displayed large lumens, were surrounded by reactive astrocytes, lacked mural cell coverage and endothelial VEGF expression, and regressed after 21 days of hypoxia. The lack of PlGF, in combination with reduced VEGF expression levels observed in the brain of PlGF-/- animals during the first 5 days of hypoxia, is likely the cause of the delayed angiogenic response and the prothrombotic phenotype of these mice. In vitro studies conducted to analyze mechanisms involved in the impaired angiogenic phenotype and enhanced astrocytic reactivity to hypoxia of PlGF-/- animals indicated that: i) PlGF-/- mouse brain endothelial cells exhibit alterations in intracellular signaling pathways associated with sprouting (ERK1/2) and vessel branching morphogenesis (GSK-3β) and ii) PlGF-/- astrocytes overexpress VEGF receptor-2 (VEGFR-2) which through activation of the ERK1/2 signaling pathway leads to a more proliferative astrocytic phenotype. These astrocytes were more resistant to oxygen and glucose deprivation (OGD) than PlGF+/+ astrocytes, a characteristic that was shown to be independent of the classical antiapoptotic VEGFR-2-dependent PI3K/Akt pathway. The findings presented in this thesis demonstrated a critical role of PlGF in vascular remodeling in the hypoxic brain.

Hypoxia

Astrocytes

Brain endothelial cells

Angiogenesis

Neurovascular

Placental growth factor

PlGF

VEGF

Chronic hypoxia

OGD

Brain angiogenesis

Impairment in Postnatal Cerebrovascular Remodeling Mediated by Small GTPases in Endothelial Rbpj Deficient Brain Arteriovenous Malformation

Adhicary, Subhodip

16 September 2022

No description available.

Genetics

Molecular Biology

Biochemistry

Cellular Biology

brain arteriovenous malformation

brain endothelial cells

Notch signaling

Rbpj

postnatal vascular remodeling

Implication de la VE-cadhérine dans la plasticité endothéliale des tumeurs / Role of VE-cadherin in tumor endothelial plasticity

Le Guelte, Armelle

16 October 2012

La barrière hémato-encéphalique (BHE) régule le transport des molécules et des cellules du compartiment sanguin vers le système nerveux central. Pour assurer cette fonction, l’endothélium microvasculaire cérébral bénéficie d’un système particulier d’enzymes, de pompes d’efflux et de jonctions cellulaires spécialisées, qui ensemble contrôlent scrupuleusement le passage des molécules plasmatiques et des cellules circulantes. La VE-cadhérine est une molécule d’adhérence qui occupe une position unique dans l’organisation des jonctions endothéliales et le maintien de l’intégrité vasculaire. Cependant, même si le rôle de la VE-cadhérine est décrit comme fondamental au cours du développement du réseau vasculaire, sa participation dans l’intégrité de la BHE nécessite d’être explorée plus en détail. Le glioblastome, la tumeur cérébrale la plus agressive et la plus létale, est associée à une vascularisation hautement perméable. En outre, ces tumeurs renferment une sous-population de cellules souches gliomateuses (CSG) dérivant d’une fraction de cellules transformées à caractère souche, qui joueraient un rôle dans l’initiation et la progression tumorales, ainsi que dans la résistance aux thérapies conventionnelles. Plus particulièrement, ces cellules ont été retrouvées in situ en interaction directe avec les cellules endothéliales cérébrales. Néanmoins, l’implication des CSG dans la plasticité des cellules endothéliales cérébrales, et notamment la perméabilité vasculaire, n’a pas été étudiée. Au sein de notre équipe, nous avons démontré que les CSG sécrètent la Sémaphorine 3A (S3A), une molécule de répulsion caractérisée par une activité antiangiogénique et pro-perméabilité. La S3A induit une augmentation de la phosphorylation et de l’internalisation de la VE-cadhérine, conduisant à une perte de la fonction de barrière des cellules endothéliales cérébrales. Au niveau moléculaire, nous avons montré que Src, une tyrosine kinase, et Set, un inhibiteur naturel de PP2A, coopèrent pour inhiber l’activité phosphatase de PP2A en réponse à la S3A. Plus particulièrement, PP2A interagit avec la VE-cadhérine bloquant sa phosphorylation, son internalisation et l’ouverture de la barrière endothéliale. PP2A confère ainsi une stabilité à la VE-cadhérine, qui serait perturbée par la S3A produite localement par les CSG. Ce mécanisme pourrait jouer un rôle clé dans les défauts des vaisseaux irriguant les glioblastomes, et d’une manière générale dans la perméabilité vasculaire tumorale. L’ensemble de ces résultats nous permet de mieux caractériser les mécanismes moléculaires mis en jeu au cours de l’angiogenèse tumorale et d’envisager à long terme des molécules à visée thérapeutique, en ciblant par exemple la voie de signalisation activée par la S3A / The blood brain barrier (BBB) regulates the transport of molecules and cells from blood into the central nervous system. This implies that the cerebral microvascular endothelium has developed a particular system of enzymes, efflux pumps and specialized cell junctions, which together carefully control the passage of plasma molecules and circulating cells. Vascular endothelial (VE)-cadherin is an adhesion molecule that occupies a unique position in the organization of endothelial junctions and the maintenance of vascular integrity. In particular, phosphorylation and internalization of VE-cadherin destabilizes cell-cell contacts and increases permeability. However, though VE-cadherin is fundamental in the development of the vascular network, its participation in the integrity of the BBB needs to be further explored. Glioblastoma is the most aggressive and the most lethal brain tumor, which is characterized by a highly leaky vasculature. Furthermore, these tumors contain a subpopulation of glioma stem cells (GSC), which derive from a fraction of transformed stem cells. GSCs play a role in the tumor initiation, progression and resistance to conventional therapies. Notably, these cells were found in direct interaction with cerebral endothelial cells in situ. However, the involvement of GSCs in the plasticity of cerebral endothelial cells, including vascular permeability, has not been studied. Our team has demonstrated that GSCs secrete semaphorin 3A (S3A), a repulsive molecule characterized by anti-angiogenic and pro-permeability activity. S3A increased phosphorylation and internalization of VE-cadherin in cerebral endothelial cells, leading to a loss of barrier integrity. At the molecular level, Src, a tyrosine kinase, and Set, a natural inhibitor of PP2A, cooperate to inhibit the phosphatase activity of PP2A, in response to S3A. Specifically, we demonstrated that PP2A interacts with VE-cadherin at the basal level. This interaction blocks VE-cadherin phosphorylation and internalization and thereby prevents opening of the endothelial barrier. Thus, PP2A stabilizes VE-cadherin, and we further showed that this complex could be disrupted by S3A produced by GSCs. This mechanism could play a key role in the dysfunctions of the vessels supplying glioblastoma, and in tumor vascular permeability in general

Cellules souches gliomateuses

Cellules endothéliales cérébrales

Perméabilité

VE-cadhérine

Sémaphorine 3A

Glioma stem cells

Brain endothelial cells

Permeability

VE-cadherin

Semaphorin 3A