Différenciation de cellules mésenchymateuses périnatales vers un phénotype musculaire lisse : base de la construction d'un feuillet vasculaire / Differentiation of mesenchymal stel cells into smooth muscle cells for vascular cells sheet construction

Beroud, Jacqueline

28 September 2015

Les pathologies vasculaires représentent aujourd’hui l’une des principales causes de mortalité mondiale et leur nombre ne cesse d’augmenter. Les greffons autologues (disponibilité faible) et les prothèses synthétiques inadaptées pour des vaisseaux de diamètre inférieur à 6 mm ne répondent pas à la demande et il existe aujourd’hui, un réel besoin en substitut vasculaire pour les petits vaisseaux. Ainsi, le concept de l’ingénierie vasculaire semble très prometteur. Cette approche est fondée sur l’utilisation de matrices « scaffold » associées à une composante cellulaire pour construire, dans des conditions environnementales adaptées, un vaisseau qui réponde et réagisse aux contraintes physiologiques. Dans cet objectif, la fonctionnalisation d’une media vasculaire constituée de cellules musculaires lisses (CML) est prérequise. Aux CML matures qui ne sont pas de bons candidats (perte de leur phénotype contractile lors de la culture), nous avons identifié les cellules souches mésenchymateuses (CSM) de la gelée de Wharton (tissu conjonctif du cordon ombilical) comme source cellulaire majeure. Leur facilité de récupération, leur présence en grand nombre, leur faible immunogénicité et leur capacité de prolifération et différenciation en font d’excellents candidats en ingénierie tissulaire. Dans ce travail nous avons déterminé les conditions favorables à l’obtention d’un phénotype CML fonctionnelles et montré l’impact de différents paramètres environnementaux (apport en oxygène, facteurs de croissance, teneur en sérum…) sur le comportement des CSM de la gelée de Wharton. Nous avons pu montrer que 1) ces cellules étaient capables de se différencier en cellules au phénotype contractile comparable à celui des CML matures. 2) L’utilisation des films multicouches de polyéléctrolytes (FMP) en tant que support d’adhérence cellulaire a montré que les CSM de la gelée de Wharton avaient un comportement spécifique selon la charge de surface conduisant vers une cultures tridimensionnelle inadaptée sur (PAH-PSS)3 PAH et en monocouche sur films (PAH-PSS)4, 3) Ces cellules pouvaient être cultivées sur des hydrogels d’alginate fonctionnalisés par les FMP pour fournir un feuillet cellulaire susceptible de recréer une media vasculaire. / Vascular diseases represent today one of the leading causes of global mortality and the number is increasing. Autologous transplants (limited availability) and synthetic prostheses unsuitable for vessels with a diameter less than 6 mm are not sufficient and there is now a real need of vascular substitute for small vessels. Thus, the concept of vascular engineering seems very promising. This approach is based on the use of "scaffold" associated with a cellular component to build in suitable environmental conditions, a vessel that reacts with the physiological constraints. To this aim, the functionalization of an incorporated media vascular smooth muscle cells (SMC) is a prerequisite. Insteag of using Mature CML which are not good candidates (loss of contractile phenotype in culture), we identified mesenchymal stem cells (MSCs) from Wharton's jelly (connective tissue of the umbilical cord) as a major cellular source. Their easiness of recovery, their presence in large numbers, their low immunogenicity, their proliferation and differentiation capacity make them excellent candidates for tissue engineering. In this work we determined the conditions for obtaining a functional CML phenotype and showed the impact of different environmental parameters (oxygen level, growth factors, serum content ...) on the behavior of CSM jelly Wharton. We have shown that: 1) these cells were able to differentiate into cells in contractile phenotype comparable to that of mature SMC. 2) The use of multilayer films of polyelectrolytes as cell adhesion support has shown that MSCs from the Wharton jelly had a specific behavior according to surface charge leading to an inappropriate three-dimensional cultures (PAHPSS)3-PAH and monolayer films on (PAH-PSS)4, 3) These cells could be grown on functionalized alginate hydrogels to provide a cellular sheet which may recreate a vascular media

Cellules souches mésenchymateuses

Gelée de Wharton

Film multicouches de polyélectrolytes

Média vasculaire

Cellules musculaires lisse

Substituts vasculaires

Ingénierie tissulaire

Mesenchymal stem cells

Wharton's jelly

Polyelectrolyte multilayer film

Vascular media

Smooth muscle cells

Vascular substitutes

Tissue engineering

571.835

571.863 6

616.027 74

Rôle de la protéine p53 dans l’hypertension artérielle pulmonaire humaine et expérimentale / Role of p53 protein in human and experimental pulmonary arterial hypertension

Jacquin, Sophie

07 November 2014

Le terme d’« hypertension artérielle pulmonaire » (HTAP) décrit une maladie vasculaire pulmonaire caractérisée par une augmentation progressive des pressions artérielles pulmonaires (PAP), définie par une PAP moyenne supérieure ou égale à 25 mmHg au repos et dont le principal symptôme est un essoufflement à l’effort. Un remodelage artériel pulmonaire intense conduisant à une obstruction des petits vaisseaux pulmonaires est responsable de la maladie. C’est une maladie rare mais néanmoins grave car pouvant aboutir à une insuffisance ventriculaire droite et entraîner le décès du patient.Le cadre général de notre étude est l’amélioration de la compréhension des mécanismes physiopathologiques de l’HTAP afin d’identifier de nouvelles cibles thérapeutiques potentielles. Nous nous sommes intéressés plus particulièrement au phénotype « pseudo-tumoral » des cellules musculaires lisses des artères pulmonaires (CML-AP) des patients atteints d’HTAP qui jouent un rôle primordial dans le remodelage vasculaire pulmonaire de l’HTAP et qui présentent des caractéristiques communes avec les cellules cancéreuses, notamment une hyper-prolifération, une résistance à l’apoptose, des désordres métaboliques et une instabilité génomique. Etant donné que la protéine p53, un des plus importants suppresseurs de tumeur, est largement décrite comme inactivée dans la plupart des cancers, nous avons émis l’hypothèse qu’elle pourrait également jouer un rôle important dans le développement de l’HTAP. Les résultats des études in vitro menées sur des CML-AP de patients atteints d'HTAP idiopathiques (HTAPi) versus des sujets contrôles semblent indiquer que la protéine p53 n’est pas altérée dans les CML-AP HTAPi. En effet, la séquence codante du gène TP53 ne présente pas de mutation dans les CML-AP HTAPi, les expressions génique et protéique de p53 (et de certaines de ses protéines cibles) ne semblent pas être différentes entre contrôles et HTAPi, ni à l’état basal ni en réponse à différents stress cellulaires inducteurs de p53 (étoposide et H2O2). Cependant, la régulation de p53 semble altérée puisque nous avons observé une augmentation du taux protéique de MDM2, principal régulateur de p53, dans les CML-AP HTAPi. Ce résultat peut être considéré comme une des caractéristiques « pseudo-tumorales » des CML-AP HTAPi mais également être un élément déterminant du mécanisme d’action de la Nutlin-3a, qui a montré des effets anti-prolifératifs accrus dans les CML-AP HTAPi.Dans des études in vivo menées chez le rat, la protéine p53 semble jouer un rôle dans l’initiation de la pathogénèse d’une HTAP. En effet, les taux protéiques pulmonaires de p53, de sa cible p21 et de son régulateur (mais également cible transcriptionnelle) MDM2 sont diminués lors de la première semaine dans un modèle d’induction d’HTAP par mono-injection de monocrotaline (MCT) chez le rat, au cours duquel la pathologie se développe à partir de la 2ème semaine. De plus, l’administration quotidienne à des rats d’un inhibiteur de l’activité transcriptionnelle de p53, le pifithrin-α (PFT), conduit au développement d’une HTAP en 14 jours, au même titre qu’une mono-injection de MCT, et aggrave l’HTAP induite par la MCT. Des effets pro-prolifératifs et anti-apoptotiques du PFT révélés sur des CML-AP indiquent que l’inhibition de l’activité transcriptionnelle de p53 est à l'origine d'une prolifération exagéree et une résistance à l'apoptose, deux composantes clés dans le remaniement vasculaire pulmonaire et le développement de l'HTAP.En conclusion, ces résultats mettent en évidence l’implication de l’inactivation de la voie de p53 lors de la phase initiatrice du développement de l’HTAP, alors qu’aux stades tardifs et sévères de la maladie, il semble il y avoir une normalisation de p53. En revanche, l’augmentation de l’expression de son principal régulateur MDM2 observée dans les CML-AP de patients HTAP semble être une cible thérapeutique potentiellement intéressante. / Pulmonary artery hypertension (PAH) is a severe pulmonary vascular disease characterized by a progressive increase of the pulmonary arterial pressure (PAP), defined by a mean PAP greater than or equal to 25 mmHg at rest. The main symptom is a shortness of breath. An intense pulmonary arterial remodeling that leads to an obstruction of the small pulmonary vessels is responsible of the disease. PAH is a rare but severe disease that develops into right ventricular cardiac failure leading to the patient's death.The general framework of our study was to improve the understanding of the pathophysiology of PAH in order to identify new potential therapeutic targets and improve the clinical management of patients. In particular, we were interested in the “cancer-like phenotype” of PAH patient pulmonary arterial smooth muscle cells (PA-SMCs). PA-SMCs play a key role in the pulmonary vascular remodeling of PAH. These cells share characteristics with cancerous cells, such as: exaggerated proliferation, apoptosis resistance, metabolic disorders and genomic instability. Owing to the growth-suppressive and pro-apoptotic functions of p53 protein and its inactivation largely described in cancer, we hypothesized that the p53 pathway could also be altered during PAH development in PA-SMCs.The results of in vitro studies on PA-SMCs of late stage patients with idiopathic PAH (iPAH) versus control patients suggest that the p53 protein nor pathway is not altered in iPAH PA-SMCs. Indeed, the coding sequence of the TP53 gene presented no mutations in iPAH PA-SMCs. Analysis of mRNA and protein levels of p53 and its target proteins showed no difference between controls and iPAH PA-SMCs, neither in a basal state or in response to various cellular stresses such as etoposide and H2O2. However, regulation of p53 may be altered in iPAH PA-SMCs as we observed an increase of the MDM2 (the main p53 regulator) protein level compared to control. This last result may be considered as a “cancer-like” characteristic of iPAH PA-SMCs and also be a determining factor in the mechanism of action of Nutlin-3a, which had more important anti-proliferative effects in iPAH PA-SMCs than in control cells.In vivo studies in rats revealed, however, that the p53 pathway may play a role in the initiation stage of PAH pathogenesis. Indeed, kinetics evaluation of p53 lung expression in the PAH model, induced by a single injection of monocrotaline (MCT), revealed a decrease in the p53 protein level during the first week, followed by a normalization by the second week. PAH symptoms are developed in MCT rats after two weeks. Similarly, the protein levels of p21, a p53 target, and MDM2, the major p53 regulator, and also a transcriptional target of p53, decreased during the first week in the MCT-PAH model. In addition, daily treatment in rats with an inhibitor of p53 transcriptional activity, pifithrin-α (PFT), led to the development of PAH in 14 days, similarly to MCT, and worsened the PAH induced by MCT. Pro-apoptotic and anti-proliferative effects of PFT on PA-SMCs indicate that inhibition of p53 transcriptional activity causes an excessive proliferation and an apoptosis resistance, which are two key components of the pulmonary vascular remodeling and development of human and experimental PAH.In conclusion, these results demonstrate the involvement of the p53 pathway inactivation in the initiation stage of PAH development, whereas in late and severe stages of disease, its role seems to be less implicated. In contrast, the increased expression of MDM2 observed in PA-SMCs of PAH patients may be a potential therapeutic target.

Protéine p53

Phénotype pseudo-tumoral

Pifithrin-alpha

Nutlin-3a

Protéine MDM2

Pulmonary arterial hypertension (PAH)

P53 protein

Cancer-like phenotype

Pifithrin-alpha

Nutlin-3a

MDM2 protein

Estudo comparativo de redes gênicas de expressão de genes associados à diabetes mellitus tipo 2 (DM2) e genótipos de risco da doença / Comparative study of gene networks of genes associated with type 2 diabetes mellitus (DM2) and the risk genotypes for the disease

André Ramos Vaquero

04 April 2013

INTRODUÇÃO: O polimorfismo dentro do gene TCF7L2, rs7903146, é, até o momento, o marcador genético mais significantemente associado ao risco de diabetes mellitus tipo 2, sendo também associado à doença arterial coronariana. Contudo, pouco ainda se conhece sobre o papel funcional desse polimorfismo na patologia dessas doenças. O objetivo desse projeto foi investigar esse papel funcional, no fenótipo de células vasculares de músculo liso de 92 indivíduos, usando abordagens de comparação de níveis de expressão gênica e de comparação de correlações de expressão gênica, de modo que tais comparações fossem representadas visualmente como redes de interação gênica. MÉTODOS: Inicialmente, foram comparados os níveis de expressão de 41 genes (genes que possuem ou estão perto de variantes genéticas associadas ao diabetes mellitus tipo 2 e outros genes relacionados às vias de sinalização de diabetes mellitus tipo 2 ou às vias de proliferação celular) entre indivíduos com o alelo associado ao risco de diabetes mellitus tipo 2 (CT e TT) e indivíduos sem o alelo de risco (CC) do rs7903146. Com a finalidade de se observar se os genes estavam se relacionando de modo diferente entre os grupos genotípicos, foram comparados os padrões de correlação de expressão dos 41 genes. RESULTADOS: Quanto às comparações de níveis de expressão entre os grupos, cinco formas de splicing do gene TCF7L2 e os genes CDKAL1, IGF2BP2, JAZF1, CDKN2B, CAMK1D, JUN, CDK4, ATP2A2, e FKBP1A apresentaram níveis de expressão significativamente diferentes. Quanto às comparações de correlação de expressão entre os grupos, os genes RXR?, CALM1, CALR e IGF2BP2 foram os que mostraram os mais diferentes padrões de correlação com os outros genes. CONCLUSÃO: Deste modo, o alelo de risco analisado é apontado como tendo influência em cis na regulação da expressão de determinadas formas de splicing do gene TCF7L2 em células vasculares de músculo liso; além de parecer influenciar nas expressões e nas interações de genes relacionados à homeostase glicolítica e/ou proliferação celular. Sendo assim, através de nossas análises identificaram-se possíveis candidatos-alvos no tratamento de redução do risco em indivíduos com alto risco de desenvolvimento de diabetes mellitus tipo 2 e de doença arterial coronariana, especialmente os indivíduos que possuem os genótipos de risco analisados do gene TCF7L2 / INTRODUCTION: The SNP within the TCF7L2 gene, rs7903146, is, to date, the most significant genetic marker associated with type 2 diabetes mellitus risk, well as being associated with coronary artery disease. Nonetheless, its functional role in these diseases pathology is poorly understood. The aim of the present study was to investigate this role, in vascular smooth muscle cells from 92 patients undergoing aortocoronary bypass surgery, using expression levels and expression correlation comparison approaches, which were visually represented as gene interaction networks. METHODS: Initially, the expression levels of 41 genes (seven TCF7L2 splice forms and other 40 relevant genes) were compared between rs7903146 wild-type (CC) and type 2 diabetes mellitus risk (CT + TT) genotype groups. Next, the expression correlation patterns of the 41 genes were compared between genotypic groups in order to observe if the relationships between genes were different. RESULTS: Five TCF7L2 splice forms and CDKAL1, IGF2BP2, JAZF1, CDKN2B, CAMK1D, JUN, CDK4, ATP2A2 and FKBP1A genes showed significant expression differences between groups. RXR?, CALM1, CALR and IGF2BP2 genes were pinpointed as showing the most different expression correlation pattern with other genes. CONCLUSION: Therefore, type 2 diabetes mellitus risk alleles appear to be influencing TCF7L2 splice form\'s expression in vascular smooth muscle cells; besides it can be influencing expression and interactions of genes related to glucose homeostasis and/or cellular proliferation. Thereby, through our analysis were identified possible treatment target candidates for risk reduction in individuals with high-risk of developing type 2 diabetes mellitus and coronary artery disease, especially individuals harboring TCF7L2 risk genotypes

Células do músculo liso

Diabetes mellitus tipo 2

Expressão gênica

Locos de características quantitativas

Redes reguladoras de genes

eQTL

Gene expression

Regulatory gene networks

TCF7L2

Type 2 diabetes mellitus

Vascular smooth muscle cells

Influence of Degradable Polar Hydrophobic Ionic Polyurethanes and Cyclic Mechanical Strain on Vascular Smooth Muscle Cell Function and Phenotype

Sharifpoor, Soror

11 January 2012

Vascular tissue engineering (VTE) with the use of polymeric scaffolds offers the potential to generate small-diameter (<6 mm) arteries. In this thesis, a degradable polar hydrophobic ionic (D-PHI) polyurethane porous scaffold was synthesized with the objective of demonstrating its potential application for VTE. D-PHI scaffold synthesis was optimized, maximizing isocyanate and methacrylate monomer conversion. Through the incorporation of a lysine-based crosslinker, scaffold mechanical properties and swelling were manipulated. Furthermore, D-PHI scaffolds demonstrated the ability to support the growth and adhesion of A10 vascular smooth muscle cells (VSMCs) during two weeks of culture. This study also investigated the effect of a double porogen approach on D-PHI scaffold properties, demonstrating an increase in the total scaffold porosity and pore interconnectivity. Specifically, it was found that the use of 10 wt% polyethylene glycol and 65 wt% sodium bicarbonate porogens resulted in a porous (79±3%) D-PHI scaffold with the mechanical properties (elastic modulus=0.16±0.03 MPa, elongation-at-yield=31±5%, and tensile strength=0.04±0.01 MPa) required to withstand the physiologically-relevant cyclic mechanical strain (CMS) that is experienced by VSMCs in vivo. Furthermore, the effects of uniaxial CMS (10% strain, 1 Hz, 4 weeks) on human coronary artery smooth muscle cells (hCASMCs), which were cultured in a porous D-PHI scaffold, were studied using a customized bioreactor. Four weeks of CMS was shown to yield greater DNA mass, more cell area coverage, a better distribution of cells within the scaffold, the maintenance of contractile protein expression and the improvement of tensile mechanical properties. The in vitro and in vivo degradation as well as the in vivo biocompatibility of D-PHI scaffolds were also investigated. Following their subcutaneous implantation in rats (100 days), porous D-PHI scaffolds demonstrated more cell/tissue infiltration within their pores and degraded in a controlled manner and at a faster rate when compared to in vitro studies (120 days), retaining the mechanical integrity required during neo-tissue formation. This thesis provides significant insight into the role of the D-PHI scaffold in combination with physiologically-relevant CMS in modulating VSMC proliferation and phenotype. The findings of this work can be used to tailor vascular tissue regeneration by regulating VSMC function in a directed manner.

Vascular tissue engineering

Polyurethane elastomer

Vascular smooth muscle cells

Scaffold

Soft tissue biomechanics

Cell proliferation

Scaffold porosity

Cell Phenotype

Cyclic mechanical strain

Biodegradation

Crosslinking monomers

Tensile mechanical properties

0541

Influence of Degradable Polar Hydrophobic Ionic Polyurethanes and Cyclic Mechanical Strain on Vascular Smooth Muscle Cell Function and Phenotype

Sharifpoor, Soror

11 January 2012

Vascular tissue engineering (VTE) with the use of polymeric scaffolds offers the potential to generate small-diameter (<6 mm) arteries. In this thesis, a degradable polar hydrophobic ionic (D-PHI) polyurethane porous scaffold was synthesized with the objective of demonstrating its potential application for VTE. D-PHI scaffold synthesis was optimized, maximizing isocyanate and methacrylate monomer conversion. Through the incorporation of a lysine-based crosslinker, scaffold mechanical properties and swelling were manipulated. Furthermore, D-PHI scaffolds demonstrated the ability to support the growth and adhesion of A10 vascular smooth muscle cells (VSMCs) during two weeks of culture. This study also investigated the effect of a double porogen approach on D-PHI scaffold properties, demonstrating an increase in the total scaffold porosity and pore interconnectivity. Specifically, it was found that the use of 10 wt% polyethylene glycol and 65 wt% sodium bicarbonate porogens resulted in a porous (79±3%) D-PHI scaffold with the mechanical properties (elastic modulus=0.16±0.03 MPa, elongation-at-yield=31±5%, and tensile strength=0.04±0.01 MPa) required to withstand the physiologically-relevant cyclic mechanical strain (CMS) that is experienced by VSMCs in vivo. Furthermore, the effects of uniaxial CMS (10% strain, 1 Hz, 4 weeks) on human coronary artery smooth muscle cells (hCASMCs), which were cultured in a porous D-PHI scaffold, were studied using a customized bioreactor. Four weeks of CMS was shown to yield greater DNA mass, more cell area coverage, a better distribution of cells within the scaffold, the maintenance of contractile protein expression and the improvement of tensile mechanical properties. The in vitro and in vivo degradation as well as the in vivo biocompatibility of D-PHI scaffolds were also investigated. Following their subcutaneous implantation in rats (100 days), porous D-PHI scaffolds demonstrated more cell/tissue infiltration within their pores and degraded in a controlled manner and at a faster rate when compared to in vitro studies (120 days), retaining the mechanical integrity required during neo-tissue formation. This thesis provides significant insight into the role of the D-PHI scaffold in combination with physiologically-relevant CMS in modulating VSMC proliferation and phenotype. The findings of this work can be used to tailor vascular tissue regeneration by regulating VSMC function in a directed manner.

Vascular tissue engineering

Polyurethane elastomer

Vascular smooth muscle cells

Scaffold

Soft tissue biomechanics

Cell proliferation

Scaffold porosity

Cell Phenotype

Cyclic mechanical strain

Biodegradation

Crosslinking monomers

Tensile mechanical properties

0541

Contribution différentielle du tissu adipeux mâle et femelle dans l’établissement du diabète de type 2 et des altérations cardiovasculaires : rôle de l’apport lipidique

El Akoum, Souhad

09 1900

Au cours des dernières années, il est devenu évident que les sociétés des pays industrialisés sont à haut risque de maladies métaboliques. Une alimentation riche en énergie (lipide/glucide), combinée à une sédentarité accrue, est un facteur environnemental contribuant à l'augmentation de la prévalence de maladies reliées spécifiquement à des troubles endocriniens comme l'obésité et le diabète. Le traitement de ces désordres métaboliques doit donc passer par la connaissance et la compréhension des mécanismes moléculaires qui contrôlent ces désordres et le développement de traitements ciblés vers les facteurs responsables. Le tissu adipeux est une glande endocrine qui sécrète des substances, regroupées sous le terme d'adipokines, qui contrôlent l'homéostasie énergétique. L'augmentation de la masse adipeuse est responsable du développement de dérégulation hormonale qui mène à des dysfonctions physiologiques et métaboliques. Pour contrecarrer le développement démesuré du tissu adipeux, la signalisation insulinique ainsi que l’apport énergétique, responsables de la différenciation adipocytaire, doivent être inhibés. In vivo, la leptine, adipokine dont la concentration est corrélée à la masse adipeuse, présente des actions pro ou anti-insuliniques dans l’organisme pour réguler ce phénomène. Elle favorise l’effet inhibiteur de l’insuline sur la synthèse hépatique de glucose alors qu’elle s’oppose à son action sur l’expression des enzymes glucokinase et phosphoénol-pyruvate carboxykinase. La leptine influence aussi le taux circulant de triglycérides en diminuant sa concentration plasmatique. D'autre part, l'adiponectine, adipokine insulino- sensibilisante, voit sa sécrétion diminuée avec la prise de poids. La sensibilité à l'insuline est ainsi diminuée au fur et à mesure que le débalancement de ces deux adipokines s'accentue. La résistance à l'insuline s'installe alors pour s'opposer au stockage énergétique et à la prise illimitée de poids et la glycémie augmente. L'augmentation du glucose sanguin stimule la sécrétion d'insuline au niveau des cellules pancréatiques. C'est le diabète caractérisé par une hyperglycémie et une résistance à l'insuline. Le diabète, une des premières causes de mortalité dans le monde, est plus répandu sous sa forme non insulinodépendante (diabète de type 2, DT2) liée à l'obésité. Récemment, différents facteurs de transcription ont été identifiés comme régulateurs de l'expression d'une panoplie de gènes impliqués dans le métabolisme glucidique et lipidique. Parmi eux, les récepteurs des inducteurs de la prolifération des peroxysomes (PPAR, Peroxisome Proliferator-Activated Receptor), appartenant à la famille des récepteurs nucléaires. Les PPAR ont été démontrés comme ayant un rôle central dans le contrôle de la transcription des gènes codants pour des protéines impliquées dans le métabolisme : les adipokines. PPARg, en plus de son implication dans le contrôle de l'homéostasie glucidique et lipidique, est reconnu comme étant un facteur de transcription pivot régulant l'adipogenèse du fait de son expression majeure dans le tissu adipeux. D'autre part, il est bien établi maintenant que l'obésité et le diabète sont des facteurs contribuant au développement du processus inflammatoire vasculaire caractéristique de l’athérosclérose. En effet, les cellules endothéliales et musculaires lisses, principales composantes de la média de l’artère, sont très sensibles aux altérations métaboliques. Une diminution de la sensibilité à l’insuline entraine une réduction de la disponibilité du glucose et l’utilisation des acides gras comme alternatif par ces cellules. Ceci induit l’accumulation des acides gras oxydés dans l’intima et leur filtration dans la média pour former un core lipidique. Bien que l’induction de la dysfonction endothéliale soit impliquée très précocement, certaines études pointent l’accumulation lipidique dans les cellules musculaires lisses vasculaires (CML) et leur dysfonction comme déclencheurs de l’athérosclérose. Ce travail visait donc, dans un premier temps, à développer un modèle d'altérations métaboliques liées à la modulation de l'activité du tissu adipeux via une alimentation riche en lipides. Dans un second temps, cette étude tentait d'évaluer l’impact des adipocytes de souris sur les CML vasculaires et sur la modulation de leurs fonctions dans ce modèle d'altérations métaboliques et DT2 liés à l'alimentation et à l'obésité. Ainsi, par le biais de deux diètes pauvres en cholestérol à profil lipidique différent, nous avons développé un modèle murin présentant divers stades d'altérations du métabolisme allant jusqu'au DT2 en lien avec l'obésité chez les mâles et chez les femelles. D’autre part, des signes de cardiomyopathie ainsi qu’une modulation du taux des adipokines sont reliés à ces mêmes diètes. Parallèlement, l’activité de PPAR!2 est modulée chez les souris sous diètes enrichies en gras. Ensuite, nous avons démontré que les adipocytes, provenant de souris alimentées avec une diète enrichie en gras, modulaient la migration et la prolifération des CML comparativement au groupe contrôle. Ces modulations dépendaient en grande partie de la nature de la diète consommée, mais également du sexe de la souris. Par ailleurs, les altérations fonctionnelles des CML, couplées à des modulations géniques, sont associées aux changements du profil de sécrétion des adipokines mesurées chez les adipocytes. L’ensemble de ces travaux suggère une action directe de la nature de la stimulation du tissu adipeux blanc dans la modulation du profil de sécrétion des adipokines et l'induction du DT2 in vivo. Ces altérations de la physiologie adipocytaire se reflètent in vitro où le tissu adipeux contribue aux altérations physiopathologiques des CML liées au DT2. Ainsi, cette étude est l'une des premières à établir un lien direct entre les modulations adipocytaires et les effets de leurs sécrétions sur la physiologie des CML. Ces observations peuvent être exploitées cliniquement dans un développement futur d’outils thérapeutiques visant à prévenir et à traiter les troubles métaboliques et le DT2, en ciblant le tissu adipeux comme entité métabolique et endocrine. / Obesity is recognized as a risk factor to a variety of chronic diseases linked to the metabolic syndrome like atherosclerosis and type 2 diabetes (T2D), and is a major cause of increased risk of morbidity and mortality worldwide. High fat diets (HFD) coupled with sedentarity in the industrialized societies contribute to the raise of metabolic alterations prevalence specifically linked to endocrine troubles. Treatment of these latter should include the comprehension of the molecular mechanisms underlying these disorders in order to appropriately target factors responsible for the disease establishment. Adipose tissue is no longer considered as a passive organ which only stores lipids, but also works as an active gland that secretes several bioactive substances called adipokines. Among them, there are key factors known to play a pivotal role in the regulation of glucose and lipid homeostasis, lipid storage, adipogenesis. They are also recognized for their control of a wide range of cell type like adipocytes, hepatocytes and skeletal myocytes. Accumulation of adipose tissue in obesity, linked with the type as much as the amount of dietary lipids, is due to hyperplasia and hypertrophy of adipocytes. These changes are associated with modification in their secretion and inflammatory profile. To counteract excessive fat tissue development, insulin signalling known for its role in adipogenesis is inhibited. Thus, leptin is secreted by adipocytes to inhibit insulin action and the insulin sensitizer adipokine, adiponectin, is down regulated. The two factors are correlated to weight gain and their respective secretion profile is upregulated for leptin and down regulated for adiponectin. Insulin resistance is developed to prevent energetic storage and unlimited weight gain but glycemic control fails and glycaemia raises. Hyperglycaemia stimulates more insulin secretion, a characteristic of T2D linked to obesity. An estimated 80% of those who develop T2D are obese. Obesity induces important and complex changes, not only in glycemic homeostasis but also in the adipocytes. Following fatty acids (FA) stimulation, the main ligand-activated transcriptional factor that controls adipose tissue metabolism and adipokine secretion, peroxisome proliferator-activated receptor gamma (PPARg), is activated. This nuclear receptor subtype regroups two isoforms: PPARg1, expressed in many tissues (adipose tissue, muscle, heart and liver) where it controls glucose and lipid homeostasis, and PPARg2, the adipocyte’s specific form, which further governs preadipocyte differentiation, up-regulation of genes involved in lipogenesis and the expression of adipokines. Recent advances showed that increased FA and glycaemia trigger vascular alterations that lead to atherosclerosis. In fact, endothelial cells (EC) and smooth muscle cells (SMC), the main arterial components, are sensitive to metabolic alterations. A lack in insulin sensitivity, leading to lower glucose availability, forces arterial cells to use FA as alternative energy source. Thus, in atheroprone regions susceptible to plaque formation, EC and SMC are subjected to metabolic modifications that lead to oxidized low-density lipoprotein (oxLDL) accumulation in the intima and the progression of vascular disease. Many studies confirmed that the presence of SMC in the atherosclerotic plaque originates from the vascular wall but are showing a distinct phenotype. Even if the role of these cells in atherogenesis is not clear, trans-differentiation of SMC into foam cells has been reported in vitro. Thus, the present study aims at studying a HFD-induced obesity mouse model, developed to evaluate the impact of FA nature on the adipokine secretion profile of adipocytes. We also intended to determine gender-specific impact on modulation of metabolic disorders in response to those diets. On the other hand, we aim to determine the role of adipocytes in the development of obesity-linked atherosclerosis. For that, the second part of this study targeted the effect of adipocytes isolated from mice fed with HFD on SMC physiology. We focused our investigation on the effects of adipocytes regardless of the impact of other cell types in the adipose tissue. To reach our goal, we developed a HFD-fed mouse preparation demonstrating different stages of metabolic disorders leading to T2D. This model allowed us to generate adipocytes with different alteration status, reflected by the modulation of their adipokine secretion profile. Modifications in adipokine secretions were associated with PPAR!2 modulation. These results, reported in both genders, were delayed in female who expressed higher levels of estrogen receptor alpha (ER"). Then, the adipocytes were used to produce conditioned cultured media. To decipher the mechanistic contributions of HFD in adipokines modulation, the potential of adipocytes to induce SMC pathophysiologic disorders was evaluated in SMC stimulated by conditioned cultured media. This protocol enables the transposition of diet-induced fat cell modifications into extended alterations in the physiology of vascular SMC. These results strongly support pro-atherogenic effects of abdominal adipocytes on an important vascular component function through paracrine actions. Thus, adipocytes can be recognized as a link between the pathogenic potential of obesity and the impairments of SMC functions. A better understanding of the pathogenic effects of the adipose tissue on other tissues and organ systems might assist to develop better strategies in treating obesity- induced cardiovascular disease and metabolic syndrome.

Diabète de type 2

Type 2 Diabetes

Obésité

Obesity

Tissu adipeux

Adipose tissue

cellules musculaires lisses

smooth muscle cells

Adipokines

Athérosclérose

Atherosclerosis

adipocyte

Étude de l'impact de combinaisons d'acides gras et de l'insuline sur la fonctionnalité des cellules musculaires lisses vasculaires

St-Denis, Corinne

06 1900

L’athérosclérose est étroitement liée au diabète de type 2. De fortes concentrations plasmatiques en acides gras libres (AGL) et en insuline sont des caractéristiques retrouvées chez les patients souffrant de ces deux pathologies. Les AGL, présents dans notre alimentation, font partie de l’environnement auquel les cellules sont exposées. Leurs effets dépendent de leur nature, les acides gras saturés (AGS) étant néfastes et les acides gras monoinsaturés (AGMI) plus protecteurs. Ils ont donc des effets variés sur les cellules musculaires lisses vasculaires (CMLV) impliquées dans la pathogénèse de l’athérosclérose. Ainsi, l’objectif principal de ce projet de maîtrise était d’évaluer l’impact de deux combinaisons d’AGL sur la viabilité des CMLV, en condition hyperinsulinémique ou non. Les deux combinaisons renfermaient les mêmes AGL mais en proportions différentes, l’une étant plus riche en AGS et l’autre en AGMI. Nos résultats ont montré que les combinaisons d’AGL ont un effet pro-apoptotique principalement dû aux AGS. L’acide oléique présent dans les combinaisons atténue cependant cet effet. Il diminue même plus fortement l’apoptose des CMLV lorsqu’associé à un AGS que lorsqu’utilisé seul. Cet impact est significatif uniquement dans certaines proportions de ces AGL et est plus efficace en présence d’insuline. Ces résultats mettent en lumière la présence d’une compétition entre mécanismes anti- et pro-apoptotiques en fonction des proportions d’AGS versus AGMI et de l’insulinémie chez les CMLV. Ils soulignent également l’importance de la présence des AGMI dans les diètes riches en AGS et pourraient être utiles pour l’élaboration de nouvelles diètes adaptées aux patients athérosclérotiques et diabétiques. / Atherosclerosis is closely linked to type 2 diabetes. High plasmatic concentrations of free fatty acids (FFA) and insulin are common features in patients suffering from both diseases. FFA, present in our diet, are part of the environment to which body cells are exposed. Their effects are dependent of their nature, being harmful for saturated fatty acids (SFA) and more protective for monounsaturated fatty acids (MUFA). They can have therefore various effects on vascular smooth muscle cells (VSMC) implicated throughout the development of atherosclerosis. Thus, this study aimed to assess the impact of two FFA combinations on VSMC viability, whether or not in a hyperinsulinemic condition. Both combinations contained the same FFA but in different proportions, one being richer in SFA and the other in MUFA. Our results showed that FFA combinations have a pro-apoptotic impact, mainly due to SFA. However, the presence of oleic acid in the combinations attenuated this effect. Furthermore, oleic acid had the capacity to reduce more strongly VSMC apoptosis when combined with a SFA than when used alone, although only under specific FFA ratios. This impact is even more effective in presence of insulin. These results highlight the presence of a competition between anti- and pro-apoptotic mechanisms dependent of FFA ratios (SFA vs. MUFA) and insulinemia to which are exposed VSMC. They also underline the importance of the presence of MUFA such as oleic acid in diets rich in SFA and could be useful for the development of new diets adapted to atherosclerotic and diabetic patients.

Acides gras libres

Cellules musculaires lisses vasculaires

Insuline

Apoptose

Viabilité cellulaire

Athérosclérose

Diabète de type 2

Free fatty acids

Vascular smooth muscle cells

Insulin

Apoptosis

Cell viability

Atherosclerosis

Type 2 diabetes

CXCL16 and CD137 in atherosclerosis

Wågsäter, Dick

January 2005

Atherosclerosis is a progressive inflammatory disease that is characterized by the accumulation of lipids, infiltrated cells and fibrous elements in large arteries. This thesis focuses on the molecular mechanisms behind foam cell formation and inflammation, two central processes in the development of atherosclerosis. More specific, we studied the effects of proinflammatory cytokines on CXCL16 expression and its role as scavenger receptor on macrophages and smooth muscle cells in atherogenesis. CXCL16 is defined as a chemokine and a scavenger receptor, regulating adhesion and chemoattraction of CXCR6 expressing cells and uptake of oxLDL. We show that the expression of CXCL16 and its receptor CXCR6 are more pronounced in human atherosclerotic lesions compared with non-atherosclerotic vessels. Increased expression of CXCL16 was also seen in atherosclerotic aortas of apoE-/- mice compared with aortas of non-atherosclerotic, age-matched C57BL/6 mice. In vitro, IFN gamma induced CXCL16 expression in primary human monocytes and smooth muscle cells which resulted in an increased uptake of oxLDL. Treatment of mice with IFN gamma also induced CXCL16 expression in atherosclerotic lesions. Thus, we have demonstrated a role for IFN gamma in foam cell formation through upregulation of CXCL16. The expression of CXCR6 was defined to the same regions as for CXCL16 in the lesion, indicating the presence of cells able to respond to CXCL16. Consequently, CXCL16 could serve as a molecular link between lipid metabolism and immune activity in atherosclerotic lesion. CD137 belongs to the TNF family and mediates several important processes in inflammation. CD137 is involved in the activation of T cells, NK cells, B cells and monocytes and regulate cytokine production, proliferation and apoptosis in these cells. A limited number of studies have demonstrated CD137 expression on smooth muscle cells and endothelial cells. Our results show that CD137 mRNA is higher expressed in human atherosclerotic lesions compared with unaffected vessels. We found that endothelial cells express CD137 in atherosclerotic lesions and that cultured endothelial cells and smooth muscle cells express CD137 and CD137 ligand in vitro. CD137 was regulated differentially by proinflammatory cytokines (i.e. IFN gamma, TNF alpha, IL-1 beta) and bacterial lipopolysaccharide depending on cell type. Furthermore, we investigated the effects of CD137 signalling, demonstrating that binding of the CD137 ligand to its receptor increases proliferation and migration of smooth muscle cells. In summary, this thesis has focused on the expression, regulation and role of CXCL16 and CD137, two genes that have not been described earlier in the concept of atherosclerosis. The findings demonstrate some of the molecular mechanisms involved in vascular inflammation and may increase our knowledge about the development of atherosclerosis.

Medicine

atherosclerosis

chemokine

cytokine

endothelial cells

inflammation

low-density lipoprotein

macrophages

scavenger receptor

smooth muscle cells

Medicin

MEDICINE

MEDICIN

Endothelial TRPV4 dysfunction in a streptozotocin-diabetic Rat Model

Shamsaldeen, Yousif

January 2016

Diabetes mellitus is a complex disease characterised by chronic hyperglycaemia due to compromised insulin synthesis and secretion, or decreased tissue sensitivity to insulin, if not all three conditions. Endothelial dysfunction is a common complication in diabetes in which endothelium-dependent vasodilation is impaired. The aim of this study was to examine the involvement of TRPV4 in diabetes endothelial dysfunction. Male Charles River Wistar rats (350-450 g) were injected with 65mg/kg streptozotocin (STZ) intraperitoneally. STZ-injected rats were compared with naïve rats (not injected with STZ) or control rats (injected with 10ml/kg of 20mM citrate buffer, pH 4.0-4.5), if not both. Rats with blood glucose concentrations greater than 16mmol/L were considered to be diabetic. As the results revealed, STZ-diabetic rats showed significant endothelial dysfunction characterised by impaired muscarinic-induced vasodilation, as well as significant impairment in TRPV4-induced vasodilation in aortic rings and mesenteric arteries. Furthermore, STZ-diabetic primary aortic endothelial cells (ECs) showed a significant reduction in TRPV4-induced intracellular calcium ([Ca2+]i) elevation. TRPV4, endothelial nitric oxide synthase (eNOS), and caveolin-1 (CAV-1) were also significantly downregulated in STZ-diabetic primary aortic ECs and were later significantly restored by in vitro insulin treatment. Methylglyoxal (MGO) was significantly elevated in STZ-diabetic rat serum, and nondiabetic aortic rings incubated with MGO (100μM) for 12 hours showed significant endothelial dysfunction. Moreover, nondiabetic primary aortic ECs treated with MGO (100μM) for 5 days showed significant TRPV4 downregulation and significant suppression of 4-α-PDD-induced [Ca2+]i elevation, which was later restored by L-arginine (100μM) co-incubation. Incubating nondiabetic aortic rings with MGO (100μM) for 2 hours induced a spontaneous loss of noradrenaline-induced contractility persistence. Moreover, MGO induced significant [Ca2+]i elevation in Chinese hamster ovary cells expressing rat TRPM8 channels (rTRPM8), which was significantly inhibited by AMTB (1-5μM). Taken together, TRPV4, CAV-1, and eNOS can form a functional complex that is downregulated in STZ-diabetic aortic ECs and restored by insulin treatment. MGO elevation might furthermore contribute to diabetes endothelial dysfunction and TRPV4 downregulation. By contrast, MGO induced the loss of contractility persistence, possibly due to MGO's acting as a TRPM8 agonist.

616.4

Současné možnosti ovlivnění dlouhodobé průchodnosti koronárních bypassů / Current possibilities of influence long-term patency of coronary artery bypass grafts

Skalský, Ivo

January 2014

The main complication of aortocoronary reconstruction with vein grafts is restenosis in the course of time. The aim was to assess the effect of a periadventitial polyester system releasing sirolimus on intimal hyperplasia of autologous grafts. The controlled-release system comprises a polyester mesh coated with a sirolimus-eluting copolymer of L lactic acid and ε-caprolactone system designed to be wrapped around an autologous venous graft during its implantation. In vitro sirolimus release and its effects on smooth muscle and endothelial cells were assessed. In vitro, the copolymer-coated polyester mesh released sirolimus over a period of 6 weeks. Mesh-eluted sirolimus inhibited the growth of smooth muscle and endothelial cells in seven-day in vitro experiments. After seven days of sirolimus release from the mesh, smooth muscle and endothelial cell counts decreased by 29% and 75%, respectively, with the cells maintaining high viability. We implanted v. jugularis ext. into a. carotis communis in rabbits. The vein graft was either intact, or was wrapped with a pure polyester mesh, or with a sirolimus-releasing mesh. Three and six weeks after surgery, the veins were subjected to standard histological staining and the thicknesses of the tunica intima, the media and the intima-media complex were...