Regulation of VE-cadherin expression and dynamic in endothelial permeability / Régulation de l’expression et la dynamique de la VE-cadhérine dans la perméabilité endothéliale

Hebda, Jagoda

15 October 2014

Les jonctions adhérentes (JA) sont nécessaires à l’élaboration d’une barrière vasculaire sélective dans laquelle la VE-cadhérine joue un rôle crucial. En effet, la VE-cadhérine est une molécule d’adhérence entrant dans la constitution des JA et présente spécifiquement au sein de l’endothélium. Lorsque la VE-cadhérine est exprimée à la surface des cellules endothéliales, l’intégrité de la barrière est préservée. En revanche, des modifications de la VE-cadhérine, comme par exemple sa phosphorylation, provoquent son internalisation, la dissociation des complexes adhésifs ou la désorganisation générale des jonctions endothéliales, défavorisant ainsi la sélectivité de la barrière. De manière générale, une perméabilité vasculaire élevée peut être observée au cours de l’activation de l’endothélium, telle que l’angiogenèse ou la réponse inflammatoire, en conditions physiologiques comme pathologiques. Par exemple, la phosphorylation de la VE-cadhérine provoquée par le facteur VEGF (vascular growth endothelial facteur) entraîne l’augmentation de la perméabilité vasculaire. En outre, une molécule pro-inflammatoire telle que l’interleukine-8 (IL-8) peut également provoquer la phosphorylation de la VE-cadhérine, aboutissant ainsi à l’augmentation de la perméabilité vasculaire. Tandis que les voies de signalisation régissant les effets pro-angiogéniques ou pro-inflammatoires du VEGF et de l’IL-8, respectivement, sont bien caractérisées, les mécanismes moléculaires sous-tendant spécifiquement l’augmentation de perméabilité endothéliale sont moins bien connus. Au cours de mon doctorat, je me suis donc attachée à examiner les interactions moléculaires entre la VE-cadhérine phosphorylée et la molécule d’échafaudage β-arrestine1, dans les cellules endothéliales humaines exposées au VEGF. J’ai également exploré la distribution de la VE-cadhérine dans les cellules endothéliales cérébrales dans un contexte tumoral, récapitulé par le sécrétome de cellules gliomateuses (GB). Mon travail a permis d’identifier la partie C-terminale (C-tail) de la β-arrestine1 qui comporte 43 acides aminés, comme une région interagissant directement avec la VE-cadhérine lorsqu’elle est phosphorylée sur le résidu S665. Cette liaison pourrait conduire alors à l’internalisation de la VE-cadhérine, lors de la stimulation par le VEGF. En outre, nous avons démontré le rôle inattendu du domaine C-tail de la β-arrestine1 dans la régulation négative de l’activité du promoteur de la VE-cadhérine. Ceci se traduit par une réduction des niveaux d’expression de la VE-cadhérine, contribuant ainsi à l’affaiblissement de la barrière endothéliale en réponse au VEGF. En outre, nous avons voulu évaluer l’effet des différents facteurs secrétés par le GB sur la perméabilité vasculaire. L’étude du sécrétome du GB a révélé une production abondante et majoritaire d’IL-8, qui provoque l’internalisation de la VE-cadhérine et la désorganisation des jonctions endothéliales. En plus de son action sur la perméabilité, l’IL-8 favorise la tubulogenèse des cellules endothéliales cérébrales. En conclusion, nous avons mis en évidence un rôle nouveau de la β-arrestine1 dans la régulation de la VE-cadhérine dans les cellules endothéliales humaines. Nous avons également démontré que la sécrétion d’IL-8 par le GB entraîne le remodelage des jonctions de la VE-cadhérine et conduit à une perte de la fonction de barrière des cellules endothéliales cérébrales. L’ensemble de nos résultats a donc permis d’améliorer nos connaissances des mécanismes moléculaires modulant la perméabilité endothéliale. / VE-cadherin is a major adhesion molecule composing endothelial adherens junctions (AJ), which ensure selectivity of the endothelial barrier. Stabilization of the VE-cadherin complex at the surface of endothelial cells plays a pivotal role in the maintenance of vascular homeostasis. Conversely, the disorganization or internalisation of VE-cadherin is a frequent consequence of VE-cadherin modifications (e.g phosphorylation), which promotes in turn vascular permeability. In general, vascular leakage can be observed in both physiological and pathological conditions. Indeed, VE-cadherin phosphorylation caused by pro-angiogenic and pro-permeability factors, among which vascular endothelial growth factor (VEGF) is the prototype, occurs during physiological angiogenesis, as well as tumour-associated angiogenesis. Besides, pro-inflammatory molecules, such as interleukin-8 (IL-8) can also participate in the phosphorylation of VE-cadherin and thereby promote vascular permeability. To best characterise VE-cadherin-mediated increase in vascular permeability under physiological VEGF challenge, we notably investigated the molecular interactions between serine (S665) phosphorylated VE-cadherin and the scaffolding molecule β-arrestin. We also studied the distribution of VE-cadherin in brain endothelial cells under pathological conditions, as provided by the secretome of glioblastoma (GB) brain tumour cells. My work allows the identification of a 43 amino-acid sequence within the C-terminus tail of β-arrestin1 (C-tail) that can directly bind to (S665) phosphorylated VE-cadherin and further triggers its internalisation upon VEGF stimulation. Moreover, we demonstrated the unexpected role of β-arrestin1 C-tail in the down-regulation of the VE-cadherin promoter activity, which results in reduction of VE-cadherin RNA and protein levels, thus contributing to the endothelial barrier properties. Furthermore, in order to evaluate the effects of tumour-secreted factors on the hyper-permeability associated with the tumour microenvironment, we explored the composition and function of the GB secretome on brain endothelial cells. We found that abundant secretion of IL-8 by GB cells causes VE-cadherin-mediated endothelial junction disorganization. Moreover, IL-8 promotes both brain endothelial cell permeability and tubulogenesis. In conclusion, we established a new role for β-arrestin1 in the control of VE-cadherin-based junctions in human endothelial cells. Likewise, we demonstrated that tumour cell-released IL-8 chemokine provokes VE-cadherin-dependent junction remodelling and thereby increases the permeability of human brain endothelial cells. Our results reinforce the central role of VE-cadherin in the modulation of the vascular barrier function in physiological and pathological conditions.

Jonction adhérent de l'endothélium

Barrière endothéliale

Internalisation de la VE-cadhérine

Perméabilité vasculaire

VEGF

IL-8

Beta-arrestine

EN- endothelial adherens junctions

Endothelial barrier

Vascular leakage

Vascular permeability

VE-cadherin internalisation

VEGF

IL-8

Arrestin

571.6

Remodelamento do complexo de glicoproteínas associadas à distrofina, do disco intercalar e das proteínas contráteis no coração de camundongos submetidos à sépsis induzida por ligação e perfuração do ceco / Remodeling of dystrophin-glycoprotein complex, intercalated disk proteins, and contractile proteins in the hearts of mice subjected to sepsis induced by cecal ligation and puncture.

Mara Rubia Nunes Celes

16 April 2008

A sépsis e o choque séptico representam uma síndrome complexa de intensa resposta inflamatória sistêmica, com múltiplas anormalidades fisiológicas e imunológicas, comumente causadas por infecção bacteriana. A principal conseqüência dessa resposta é o comprometimento de muitos órgãos e tecidos. A disfunção cardíaca, decorrente de um prejuízo na contratilidade miocárdica, tem sido reconhecida como um fator importante que contribui para os altos índices de mortalidade observados na sépsis. Dados recentes do nosso laboratório indicam que alterações estruturais no miocárdio podem ser responsáveis pela disfunção cardíaca observada na sépsis. Considerando que a maquinaria contrátil interna das miofibras deve permanecer intimamente conectada com a membrana e a matriz extracelular, o presente estudo foi proposto para avaliar alterações nas comunicações intercelulares e acoplagem mecânica entre os cardiomiócitos vizinhos e avaliar a expressão de proteínas do arcabouço celular e da matriz extracelular (especificamente a laminina-?2) durante a sépsis grave. Nossos resultados mostraram que há uma diminuição na expressão das proteínas envolvidas na formação das gap junctions (conexina43) e junções aderentes (N-caderina), o que resultaria na perda da integridade estrutural dos discos intercalares, alterando o acoplamento mecânico e eletro-químico entre os cardiomiócitos vizinhos. Além disso, demonstramos que há redução na expressão de distrofina e das proteínas que constituem o complexo de glicoproteínas associadas a distrofina (CGD) durante a sépsis experimental. A redução ou perda da expressão de distrofina é o evento primário que ocorre seguido pela degeneração miofilamentar, caracterizada pela lise dos filamentos de actina e miosina. A diminuição na expressão das glicoproteínas associadas à distrofina: -distroglicana e laminina foram considerados eventos secundários. Os resultados sugerem que durante a sépsis induzida por ligação e perfuração do ceco (CLP), há perda de proteínas importantes envolvidas tanto no remodelamento do disco intercalar quanto na expressão de glicoproteínas envolvidas na ligação mecânica entre o citoesqueleto intracelular e a matriz extracelular. Embora estudos funcionais sejam necessários para determinar o efeito direto dessas alterações sobre o miocárdio podemos sugerir que as alterações estruturais são parcialmente responsáveis pela depressão miocárdica observada na sépsis. / Sepsis and septic shock represent a complex syndrome of systemic inflammatory response, with multiple physiological and immunological abnormalities, commonly caused by bacterial infection. The most important consequence of the response is the involvement of many organs and tissues. Cardiac dysfunction, caused by impairment in myocardial contractility, has been recognized as an important factor that contributes to the high mortality observed in sepsis. Evidence from our laboratory indicates that myocardial structural changes could be responsible for sepsis-induced myocardial dysfunction. Taking into account that the contractile machinery inside the myofibers must remain intimately connected with the membrane and extracellular matrix, the present investigation sought to evaluate changes in intercellular communications and mechanical coupling between the neighbor cardiomyocytes and the expression of the cell scaffold protein and extracellular matrix (specifically merosin laminin-2 chain) during the severe sepsis. Our results showed a decrease in the expression of proteins involved in formation of gap junctions (connexin-43) and adherens junctions (N-cadherin). These alterations may result in the loss of intercalated disc structural integrity, changing the mechanical and electrical-chemical coupling between neighboring cardiomyocytes. Additionally, we demonstrated the decrease of dystrophin and dystrophin-glycoprotein complex (DGC) components resulting from severe septic injury. The reduction or loss of dystrophin is the primary event that occurs followed by miofilamentar degeneration characterized by actin and myosin lysis. The decrease of glycoproteins associated with dystrophin: -dystroglican and laminin were considered secondary events. The results suggest that during experimental severe sepsis induced by cecal ligation and puncture (CLP), there is loss of important proteins involved in both the remodeling of the intercalated disc and the glycoproteins expression implicated in the mechanical link between the intracellular cytoskeleton and extracellular matrix. Although the functional studies are needed to determine the direct effect of these alterations on myocardium, we can suggest that myocardial structural changes may be partly responsible for sepsis-induced cardiac depression.

CLP

disco intercalar

miocárdio

proteínas contráteis

sepsis/choque séptico

actin

adherens junctions

dystrophin

dystrophin-glycoprotein complex

gap junctions

intercalated disc

myocardial dysfunction

myosin.

septic shock

severe sepsis

Remodelamento do complexo de glicoproteínas associadas à distrofina, do disco intercalar e das proteínas contráteis no coração de camundongos submetidos à sépsis induzida por ligação e perfuração do ceco / Remodeling of dystrophin-glycoprotein complex, intercalated disk proteins, and contractile proteins in the hearts of mice subjected to sepsis induced by cecal ligation and puncture.

Celes, Mara Rubia Nunes

16 April 2008

A sépsis e o choque séptico representam uma síndrome complexa de intensa resposta inflamatória sistêmica, com múltiplas anormalidades fisiológicas e imunológicas, comumente causadas por infecção bacteriana. A principal conseqüência dessa resposta é o comprometimento de muitos órgãos e tecidos. A disfunção cardíaca, decorrente de um prejuízo na contratilidade miocárdica, tem sido reconhecida como um fator importante que contribui para os altos índices de mortalidade observados na sépsis. Dados recentes do nosso laboratório indicam que alterações estruturais no miocárdio podem ser responsáveis pela disfunção cardíaca observada na sépsis. Considerando que a maquinaria contrátil interna das miofibras deve permanecer intimamente conectada com a membrana e a matriz extracelular, o presente estudo foi proposto para avaliar alterações nas comunicações intercelulares e acoplagem mecânica entre os cardiomiócitos vizinhos e avaliar a expressão de proteínas do arcabouço celular e da matriz extracelular (especificamente a laminina-?2) durante a sépsis grave. Nossos resultados mostraram que há uma diminuição na expressão das proteínas envolvidas na formação das gap junctions (conexina43) e junções aderentes (N-caderina), o que resultaria na perda da integridade estrutural dos discos intercalares, alterando o acoplamento mecânico e eletro-químico entre os cardiomiócitos vizinhos. Além disso, demonstramos que há redução na expressão de distrofina e das proteínas que constituem o complexo de glicoproteínas associadas a distrofina (CGD) durante a sépsis experimental. A redução ou perda da expressão de distrofina é o evento primário que ocorre seguido pela degeneração miofilamentar, caracterizada pela lise dos filamentos de actina e miosina. A diminuição na expressão das glicoproteínas associadas à distrofina: -distroglicana e laminina foram considerados eventos secundários. Os resultados sugerem que durante a sépsis induzida por ligação e perfuração do ceco (CLP), há perda de proteínas importantes envolvidas tanto no remodelamento do disco intercalar quanto na expressão de glicoproteínas envolvidas na ligação mecânica entre o citoesqueleto intracelular e a matriz extracelular. Embora estudos funcionais sejam necessários para determinar o efeito direto dessas alterações sobre o miocárdio podemos sugerir que as alterações estruturais são parcialmente responsáveis pela depressão miocárdica observada na sépsis. / Sepsis and septic shock represent a complex syndrome of systemic inflammatory response, with multiple physiological and immunological abnormalities, commonly caused by bacterial infection. The most important consequence of the response is the involvement of many organs and tissues. Cardiac dysfunction, caused by impairment in myocardial contractility, has been recognized as an important factor that contributes to the high mortality observed in sepsis. Evidence from our laboratory indicates that myocardial structural changes could be responsible for sepsis-induced myocardial dysfunction. Taking into account that the contractile machinery inside the myofibers must remain intimately connected with the membrane and extracellular matrix, the present investigation sought to evaluate changes in intercellular communications and mechanical coupling between the neighbor cardiomyocytes and the expression of the cell scaffold protein and extracellular matrix (specifically merosin laminin-2 chain) during the severe sepsis. Our results showed a decrease in the expression of proteins involved in formation of gap junctions (connexin-43) and adherens junctions (N-cadherin). These alterations may result in the loss of intercalated disc structural integrity, changing the mechanical and electrical-chemical coupling between neighboring cardiomyocytes. Additionally, we demonstrated the decrease of dystrophin and dystrophin-glycoprotein complex (DGC) components resulting from severe septic injury. The reduction or loss of dystrophin is the primary event that occurs followed by miofilamentar degeneration characterized by actin and myosin lysis. The decrease of glycoproteins associated with dystrophin: -dystroglican and laminin were considered secondary events. The results suggest that during experimental severe sepsis induced by cecal ligation and puncture (CLP), there is loss of important proteins involved in both the remodeling of the intercalated disc and the glycoproteins expression implicated in the mechanical link between the intracellular cytoskeleton and extracellular matrix. Although the functional studies are needed to determine the direct effect of these alterations on myocardium, we can suggest that myocardial structural changes may be partly responsible for sepsis-induced cardiac depression.

actin

adherens junctions

CLP

disco intercalar

dystrophin

dystrophin-glycoprotein complex

gap junctions

intercalated disc

miocárdio

myocardial dysfunction

myosin.

proteínas contráteis

sepsis/choque séptico

septic shock

severe sepsis

Étude des mécanismes cellulaires activés par l'Angiopoïétine-1 et le VEGF régulant la perméabilité et la migration endothéliales

Oubaha, Malika

11 1900

L’angiogenèse est la formation de nouveaux vaisseaux sanguins à partir d’un réseau vasculaire existant. C’est un phénomène essentiel pour des processus physiologiques et pathologiques. L’activation des cellules endothéliales est contrôlée par plusieurs facteurs de croissance. Le VEGF et son récepteur le VEGFR-2 ont été prouvés comme étant spécifiques et critiques pour la formation des vaisseaux sanguins alors que Tie2, le récepteur auquel se lie l’Ang-1, est requis aussi bien dans le développement vasculaire que dans l’angiogenèse tumorale. Il est connu que l’activation de Tie2 est nécessaire à la stabilisation finale de la vascularisation en inhibant la perméabilité vasculaire induite par le VEGFR-2. Nous avons premièrement découvert que le facteur de croissance pro-angiogénique, l’Ang-1 contrecarre les effets de perméabilité cellulaire induits par le VEGF en inhibant la production de NO dans les cellules endothéliales. Cet effet inhibiteur de Tie2 intervient directement au niveau de l’activité de l’enzyme eNOS. Suite à l’activation de Tie2 par l’Ang-1, eNOS devient fortement phosphorylé sur la Thr497 après la phosphorylation et l’activation de la PKCζ. Nos résultats suggèrent que l’inhibition, par Tie2, de la perméabilité vasculaire durant l’angiogenèse serait due, en partie, à l’inhibition de la production de NO. Deuxièmement nous avons pu distinguer entre deux modes de migration cellulaire endothéliale induits par l’Ang-1 et le VEGF. À l’opposé du VEGF qui promeut une migration individuelle aléatoire, l’Ang-1 induit une migration collective directionnelle. Dans cette étude, nous avons identifié la β-caténine comme un nouveau partenaire moléculaire de la PKCζ. Cette association de la PKCζ à la β-caténine amène le complexe de polarité Par6-aPKC et le complexe des jonctions d’adhérences cellulaires à interagir ensemble à deux localisations différentes au niveau de la cellule endothéliale. Au niveau des contacts intercellulaires, le complexe PKCζ/β-caténine maintien la cohésion et l’adhésion cellulaire nécessaire pour le processus migratoire collectif. Ce complexe se retrouve aussi au niveau du front migratoire des cellules endothéliales afin d’assurer la directionalité et la persistance de la migration endothéliale en réponse à l’Ang-1. D’une manière intéressante, lors de l’inhibition de la PKCζ ou de la β-caténine on assiste à un changement du mode de migration en réponse à l’Ang-1 qui passe d’une migration directionnelle collective à une migration individuelle aléatoire. Ce dernier mode de migration est similaire à celui observé chez des cellules endothéliales exposées au VEGF. Ces résultats ont été corroborés in vivo par une polarité et une adhésion défectueuses au cours de la vasculogenèse chez le poisson zèbre déficient en PKCζ. En résumé, Ang-1/Tie2 module la signalisation et les réponses biologiques endothéliales déclenchées par le VEGF/VEGFR-2. L’identification des mécanismes moléculaires en aval de ces deux récepteurs, Tie2 et VEGFR-2, et la compréhension des différentes voies de signalisation activées par ces complexes moléculaires nous permettra de mettre la lumière sur des nouvelles cibles thérapeutiques pour le traitement des maladies angiogéniques. / Angiogenesis is the formation of new blood vessels from a pre-existing vascular network. It is an essential mechanism for many physiological and pathological conditions. Also, the general mechanism in both conditions remains the same. VEGF and its receptor VEGFR-2 have been proven to be specific and critical for blood vessel formation. The Angiopoietin-1 receptor, Tie2, is required for vascular development as well as in tumor angiogenesis. It is known that the activation of Tie2 is required for vascular stabilization by inhibiting vascular permeability induced by VEGFR-2. First, we found that the pro-angiogenic growth factor, Ang-1 counteracts the effects of VEGF-induced permeability by inhibiting NO production by endothelial cells. This inhibitory effect of Tie2 acts directly on eNOS activity. Following activation of Tie2 by Ang-1, eNOS becomes highly phosphorylated on the inhibitory site, the Thr497, following PKCζ phosphorylation and activation. Our results suggest that the inhibition by Tie2 of vascular permeability during angiogenesis is due, in part, to the inhibition of NO production. In our second study we distinguished between two types of endothelial cell migration induced by Ang-1 and VEGF. At the opposite of Ang-1 that induced collective and directional cell migration, VEGF promoted individual and random cell motility. We identified β-catenin as a new molecular partner of PKCζ. This association of PKCζ with β-catenin brings the Par6-aPKC polarity complex and the adherens junctions complex to interact with each other at two different locations in endothelial cells. PKCζ/β-catenin complex is located specifically at cell-cell contacts to maintain cohesion and cell adhesion necessary for the collective migration process. This complex was located also at the leading edge of endothelial cells during migration to ensure the directionality and the persistence of migration in response to Ang-1. In addition, inhibition of PKCζ or β-catenin switched the migration mode, in response to Ang-1, from directional and collective to a more random and individual cell migration which resembles the type of migration of endothelial cells exposed to VEGF. These results were confirmed in vivo by aberrant cell polarity and cell adhesion defects of tip cell during vascular sprouting of intersegmental vessels in PKCζ deficient zebrafish embryos. In summary, Ang-1/Tie2 modulates endothelial cell signaling and biological responses induced by VEGF/VEGFR-2. The identification of molecular mechanisms involved in the action of these two receptors, VEGFR-2 and Tie2, and the understanding of the different signaling pathways activated by these molecular complexes will allow us to identify new therapeutic targets for the treatment of angiogenic diseases treatment.

Cellules endothéliales

VEGF

Angiopoïétine-1

Jonctions d’adhérence

Perméabilité

Migration

Polarité

eNOS

PKCζ

Endothelial cells

VEGF

Angiopoietin-1

Permeability

Migration

Polarity

eNOS

PKCζ

Adherens junctions

Investigation on Cell-Cell Junctions by Inhibition of Na,K-ATPase Activity / Studie av cell till cell kontakter genom inhibering av Na,K-ATPas aktivitet

Boström, Caroline

January 2021

This thesis report investigates the effect on cellcell junction proteins when the Na,K-ATPase (NKA) is inhibited. The main goal is to develop an understanding of how the NKA activity regulates the cell junction proteins. The investigated proteins are the adherens junction protein ECadherin, and the tight junction proteins Occludin and Claudin7.The NKA is inhibited by introducing the cardiotonic steroid Ouabain to the cells. The treatment is tested for different time lapse and different concentrations. The results show that all proteins are down regulated when treated with high concentrations (500 nM) of Ouabain. ECadherin is up regulated when treated with lower concentrations (10 nM) of Ouabain while Claudin7 is down regulated at low levels. / Detta examensarbete undersöker effekten på cell-cell junctions när Na,K-ATPas (NKA) inhiberas. Målet med rapporten är att få en förståelse för hur NKA aktiviteten reglerar cell-cell junction proteinerna. Proteinerna som undersöks är adherens junction proteinet ECadherin, och tight junction proteinerna Claudin7 och Occludin. NKA inhiberas genom att cellerna behandlas med den kardiotoniska steroiden Ouabain. Behandlingen testas under olika tidsperioder och för olika koncentrationer. Resultaten visar att alla proteiner är nedreglerade när de behandlas med höga koncentrationer (500 nM) av Ouabain. ECadherin blir uppreglerad när det behandlas med lägre koncentrationer (10 nM) av Ouabain medan Claudin7 nedregleras vid låga nivåer.

NaK-ATPase

Ouabain

Cell junctions

ECadherin

Occludin

Claudin7

Western Blot

Fluorescent Imaging

Tight junctions

Adherens Junctions

Immunocytochemistry

Ouabain

NaK-ATPase

ECadherin

Occludin

Claudin7

Western Blot

Immunocytokemi

Cellkontakter

Fluorescernsmikroskopi

Physical Sciences

Fysik