Heterogeneidade e mecanismos moleculares da atividade anti-apoptótica das subfrações de HDL em células endoteliais humanas / Heterogeneity and molecular mechanisms of anti-apoptotic activity of high-density lipoprotein (HDL) subfractions on endothelial cells

Souza, Juliana Ascenção de

19 March 2007

Introdução: A lipoproteína de baixa densidade (LDL) e suas formas oxidadas (LDLox) possuem múltiplas propriedades aterogênicas, atuando na deposição de colesterol, indução e manutenção da inflamação, disfunção endotelial, surgimento de células espumosas na parede arterial e conseqüente formação da placa de ateroma. Adicionalmente, LDLox induz apoptose de células endoteliais humanas (HMEC). A lipoproteína de alta densidade (HDL) possui inúmeras atividades antiaterogênicas, incluindo ações antioxidante, anti-inflamatória e anti-trombótica. A HDL é capaz de proteger as HMEC contra apoptose. As subfrações de HDL (sHDL) são heterogêneas em sua composição físico-química e atividades biológicas. A atividade antioxidante das sHDL aumenta com a densidade (HDL2b<HDL2a<HDL3a<HDL3b <HDL3c) e está deficiente em pacientes com SMet. Contudo, a heterogeneidade da atividade anti-apoptótica das sHDL é ainda desconhecida. Objetivos: (i) avaliar a heterogeneidade da atividade protetora das sHDL de indivíduos normolipidêmicos (n=7) e de pacientes com SMet (n=16) contra apoptose de HMEC induzida por LDLox; (ii) definir os mecanismos moleculares envolvidos nesta atividade. Métodos: Através de ultracentrifugação por gradiente de densidade, isolamos cinco diferentes sHDL. HMEC foram incubadas com LDLox (200 ?g apoB/ml) na presença ou não das sHDL (5-100 ?g proteína/ml). Os marcadores de toxicidade (MTT) e de apoptose celular (microscopia de fluorescência, marcagem com anexina V, cit c, AIF, degradação Bid, atividade caspase-3 e fragmentação do ADN) foram analisados. Resultados: Todas sHDL protegeram as HMEC contra a toxicidade e apoptose induzidas pela LDLox. Com mesma concentração de proteína, as subfrações HDL3c (60% proteção - MTT - e >100% - anexina V) e 3b (43% e 67%, respectivamente) de indivíduos normolipidêmicos apresentaram atividade anti-apoptótica mais potente do que as subfrações HDL2a (29% e 28%; p<0,01 vs. HDL3c, respectivamente) e 2b (25% e 62%; p<0,001 vs. HDL3c, respectivamente). Todas sHDL reduziram geração de espécies reativas de oxigênio (ROS) induzida pela LDLox, sendo a HDL3c (54%) mais potente do que HDL2b (21%; p<0.05 vs. HDL3c). Houve correlação positiva entre as atividades anti-apoptótica e antioxidante intracelular com conteúdo de apoA-I e esfingosina 1-fosfato (E1F) das sHDL, senda HDL3b e 3c ricas em E1F. A atividade anti-apoptótica da E1F e das sHDL parece depender da interação com as células endoteliais via apoA-I e seu receptor SR-BI. Finalmente, as HDL3c (n=5) isoladas de pacientes com SMet possuem conteúdo significativamente menor de apoA-I e reduzida atividade anti-apoptótica (60%, p<0,01), quando comparada aos controles normolipidêmicos (n=5). Houve tendência à diminuição da proteção contra a geração de ROS (SMet, n=10). Conclusão: As subfrações HDL3c protegem de forma potente as células endoteliais humanas contra toxicidade e apoptose induzidas pela LDLox, assim como contra geração de ROS. Esta atividade antiapoptótica está reduzida na SMet. / Background: Low density lipoprotein (LDL) and its oxidized forms (oxLDL) have several atherogenic properties, including cholesterol deposition, inflammation, endothelial dysfunction and foam cell formation on the arterial wall, leading to atherosclerotic plaque development. In addition, oxLDL induces human endothelial cell apoptosis (HMEC). High-density lipoprotein (HDL) has number of antiatherogenic activities, as antioxidative, anti-inflammatory and anti-thrombotic actions. HDL displays anti-apoptotic activity and is able to protect endothelial cells against oxLDL-induced apoptosis. HDL subfractions (sHDL) are highly heterogeneous in their physical and chemical composition and biological functions. Antioxidative activity of HDL subfractions increases with increment in density, HDL2b<HDL2a<HDL3a<HDL3b <HDL3c. Important, HDL subfractions from subjects with metabolic syndrome (MetS), display a significantly lower antioxidative activity as compared to healthy controls. However, the heterogeneity of their anti-apoptotic activity was not demonstrated. Objectives: (i) to evaluate the heterogeneity of antiapoptotic activity of sHDL from normolipidemic controls (n=7) and MetS patients (n=16) towards oxLDL-induced apoptosis of HMEC; (ii) to define molecular mechanisms involved in this anti-apoptotic action. Methods: Five major sHDL were fractionated by density gradient ultracentrifugation. HMEC were incubated with mildly oxLDL (200 ?g apoB/ml) in the presence or absence of each sHDL (5-100 ?g protein/ml). Markers of cellular toxicity (MTT) and apoptosis (fluorescent nucleic acid staining, annexin V binding, cytochrome c, AIF and Bid, caspase-3 activity and DNA fragmentation) were observed. Results: All HDL subfractions isolated from normolipidemic subjects protected HMEC against oxLDL-induced toxicity and apoptosis. At equal protein concentrations, HDL3c (60% protection in the MTT test; >100% in annexin V biding) and 3b subfractions (43% and 67%, respectively) were more potent against oxLDL-induced toxicity and apoptosis as compared to HDL2a (29% and 28%; p<0.01 vs. HDL3c, respectively) and 2b subfractions (25% and 62%; p<0.001 vs. HDL3c, respectively). All HDL subfractions attenuated of reactive oxygen species (ROS) generation in HMEC induced by oxLDL. Again, HDL3c (54% inhibition) were more potent as compared to HDL2b (21%; p<0.05 vs. HDL3c). The anti-apoptotic and intracellular antioxidative activities of HDL3 were positively correlated with apoA-I and sphingosine 1-phosphate (S1P) content of sHDL and, possibly, depend on their cellular interaction through apoA-I and its SR-BI receptor. The sHDL3c isolated from MetS patients (n=5) possess reduced content of apoA-I and less potent anti-apoptotic activity (-60%, p<0.01) than controls (n=5). Conclusion: Normolipidemic small dense HDL3 provide potent protection of human endothelial cells from oxLDL-induced apoptosis; this anti-apoptotic activity is reduced in the MetS.

Apolipoproteína A-I

ApolipoproteinA-I

Apoptose

Apoptosis and endothelial cell

Células endoteliais

Dislipidemia

Dislipidemias

Esfingosina

HDL subfractions

Lipoproteínas do colesterol HDL

Metabolic syndrome

Oxidised LDL

Síndrome X metabólica

Sphingosine 1-phosphate

Effets athéroprotecteurs de la curcumine et d’extraits riches en polyphénols d’Antirhea borbonica et de Doratoxylon apetalum / Atheroprotective effects of curcumin and polyphenol rich extracts of Antirhea borbonica and Doratoxylon apetalum

Bonneville, Jonathan

27 June 2018

Les maladies cardiovasculaires représentent la première cause de mortalité en France avec une prévalence encore plus importante à La Réunion. La plupart des décès sont attribuables aux cardiopathies ischémiques due à la rupture d'une plaque d'athérosclérose et à la formation d'un caillot entrainant une ischémie cardiaque. L'oxydation des lipoprotéines de basse densité (LDL) et la dysfonction de l'endothélium représentent des étapes importantes dans la déstabilisation de la plaque, d'où l’intérêt de rechercher un traitement capable de diminuer l'oxydation des LDL ou de protéger les cellules endothéliales de leurs effets cytotoxiques. Les polyphénols sont des molécules antioxydantes très présentes dans le règne végétal. Des études préliminaires du laboratoire sur des adipocytes humain on montré que des extraits riches en polyphénols d'Antirhea borbonica et de Doratoxylon apetalum, deux espèces respectivement endémique et indigène de l'Île de La Réunion, possédaient des propriétés antioxydantes et anti-inflammatoires (Marimoutou, M et al. 2015). Le But de cette thèse était, dans un premier temps, de tester les capacités antioxydantes et cytoprotectrices d'extraits riches en polyphénols de ces deux espèces sur des cellules endothéliales. Puis dans un second temps nous avons testé l'extrait de Doratoxylon apetalum sur un modèle murin d'athérosclérose (souris ApoE KO) pour évaluer son effet anti-inflammatoire sur les plaques d'athérome. / Cardiovascular diseases are the leading cause of death in France with an even higher prevalence in Reunion. Most deaths are due to ischemic heart disease because of atherosclerotic plaque rupture and thrombus formation leading to cardiac ischemia. The oxidation of low density lipoproteins (LDL) and endothelial dysfunction represent important steps in the destabilization of plaque, hence the interest of a treatment capable of reducing the oxidation of LDL or of protecting endothelial cells from their cytotoxic effects. Polyphenols are antioxidant molecules very present in the plant kingdom. Preliminary studies on human adipocytes have shown that polyphenol-rich extracts of Antirhea borbonica and Doratoxylon apetalum, respectively endemic and indigenous species of Reunion Island, had antioxidant and anti-inflammatory properties (Marimoutou , M et al., 2015). The aim of this thesis was, first, to test the antioxidant and cytoprotective capacities of polyphenol rich extracts of these two species on endothelial cells. Then in a second time we tested the extract of Doratoxylon apetalum on a murine model of atherosclerosis (ApoE KO mice) to evaluate its anti-inflammatory effect on atheroma plaques.

Polyphénols

Athérosclérose

LDL

LDL oxydées

Doratoxylon apetalum

Antirhea Borbonica

Antioxydant

Cytoprotecteur

Polyphenols

Atherosclerosis

LDL

Oxidised LDL

Doratoxylon apetalum

Antirhea Borbonica

Antioxidant

Cytoprotective

Heterogeneidade e mecanismos moleculares da atividade anti-apoptótica das subfrações de HDL em células endoteliais humanas / Heterogeneity and molecular mechanisms of anti-apoptotic activity of high-density lipoprotein (HDL) subfractions on endothelial cells

Juliana Ascenção de Souza

19 March 2007

Introdução: A lipoproteína de baixa densidade (LDL) e suas formas oxidadas (LDLox) possuem múltiplas propriedades aterogênicas, atuando na deposição de colesterol, indução e manutenção da inflamação, disfunção endotelial, surgimento de células espumosas na parede arterial e conseqüente formação da placa de ateroma. Adicionalmente, LDLox induz apoptose de células endoteliais humanas (HMEC). A lipoproteína de alta densidade (HDL) possui inúmeras atividades antiaterogênicas, incluindo ações antioxidante, anti-inflamatória e anti-trombótica. A HDL é capaz de proteger as HMEC contra apoptose. As subfrações de HDL (sHDL) são heterogêneas em sua composição físico-química e atividades biológicas. A atividade antioxidante das sHDL aumenta com a densidade (HDL2b<HDL2a<HDL3a<HDL3b <HDL3c) e está deficiente em pacientes com SMet. Contudo, a heterogeneidade da atividade anti-apoptótica das sHDL é ainda desconhecida. Objetivos: (i) avaliar a heterogeneidade da atividade protetora das sHDL de indivíduos normolipidêmicos (n=7) e de pacientes com SMet (n=16) contra apoptose de HMEC induzida por LDLox; (ii) definir os mecanismos moleculares envolvidos nesta atividade. Métodos: Através de ultracentrifugação por gradiente de densidade, isolamos cinco diferentes sHDL. HMEC foram incubadas com LDLox (200 ?g apoB/ml) na presença ou não das sHDL (5-100 ?g proteína/ml). Os marcadores de toxicidade (MTT) e de apoptose celular (microscopia de fluorescência, marcagem com anexina V, cit c, AIF, degradação Bid, atividade caspase-3 e fragmentação do ADN) foram analisados. Resultados: Todas sHDL protegeram as HMEC contra a toxicidade e apoptose induzidas pela LDLox. Com mesma concentração de proteína, as subfrações HDL3c (60% proteção - MTT - e >100% - anexina V) e 3b (43% e 67%, respectivamente) de indivíduos normolipidêmicos apresentaram atividade anti-apoptótica mais potente do que as subfrações HDL2a (29% e 28%; p<0,01 vs. HDL3c, respectivamente) e 2b (25% e 62%; p<0,001 vs. HDL3c, respectivamente). Todas sHDL reduziram geração de espécies reativas de oxigênio (ROS) induzida pela LDLox, sendo a HDL3c (54%) mais potente do que HDL2b (21%; p<0.05 vs. HDL3c). Houve correlação positiva entre as atividades anti-apoptótica e antioxidante intracelular com conteúdo de apoA-I e esfingosina 1-fosfato (E1F) das sHDL, senda HDL3b e 3c ricas em E1F. A atividade anti-apoptótica da E1F e das sHDL parece depender da interação com as células endoteliais via apoA-I e seu receptor SR-BI. Finalmente, as HDL3c (n=5) isoladas de pacientes com SMet possuem conteúdo significativamente menor de apoA-I e reduzida atividade anti-apoptótica (60%, p<0,01), quando comparada aos controles normolipidêmicos (n=5). Houve tendência à diminuição da proteção contra a geração de ROS (SMet, n=10). Conclusão: As subfrações HDL3c protegem de forma potente as células endoteliais humanas contra toxicidade e apoptose induzidas pela LDLox, assim como contra geração de ROS. Esta atividade antiapoptótica está reduzida na SMet. / Background: Low density lipoprotein (LDL) and its oxidized forms (oxLDL) have several atherogenic properties, including cholesterol deposition, inflammation, endothelial dysfunction and foam cell formation on the arterial wall, leading to atherosclerotic plaque development. In addition, oxLDL induces human endothelial cell apoptosis (HMEC). High-density lipoprotein (HDL) has number of antiatherogenic activities, as antioxidative, anti-inflammatory and anti-thrombotic actions. HDL displays anti-apoptotic activity and is able to protect endothelial cells against oxLDL-induced apoptosis. HDL subfractions (sHDL) are highly heterogeneous in their physical and chemical composition and biological functions. Antioxidative activity of HDL subfractions increases with increment in density, HDL2b<HDL2a<HDL3a<HDL3b <HDL3c. Important, HDL subfractions from subjects with metabolic syndrome (MetS), display a significantly lower antioxidative activity as compared to healthy controls. However, the heterogeneity of their anti-apoptotic activity was not demonstrated. Objectives: (i) to evaluate the heterogeneity of antiapoptotic activity of sHDL from normolipidemic controls (n=7) and MetS patients (n=16) towards oxLDL-induced apoptosis of HMEC; (ii) to define molecular mechanisms involved in this anti-apoptotic action. Methods: Five major sHDL were fractionated by density gradient ultracentrifugation. HMEC were incubated with mildly oxLDL (200 ?g apoB/ml) in the presence or absence of each sHDL (5-100 ?g protein/ml). Markers of cellular toxicity (MTT) and apoptosis (fluorescent nucleic acid staining, annexin V binding, cytochrome c, AIF and Bid, caspase-3 activity and DNA fragmentation) were observed. Results: All HDL subfractions isolated from normolipidemic subjects protected HMEC against oxLDL-induced toxicity and apoptosis. At equal protein concentrations, HDL3c (60% protection in the MTT test; >100% in annexin V biding) and 3b subfractions (43% and 67%, respectively) were more potent against oxLDL-induced toxicity and apoptosis as compared to HDL2a (29% and 28%; p<0.01 vs. HDL3c, respectively) and 2b subfractions (25% and 62%; p<0.001 vs. HDL3c, respectively). All HDL subfractions attenuated of reactive oxygen species (ROS) generation in HMEC induced by oxLDL. Again, HDL3c (54% inhibition) were more potent as compared to HDL2b (21%; p<0.05 vs. HDL3c). The anti-apoptotic and intracellular antioxidative activities of HDL3 were positively correlated with apoA-I and sphingosine 1-phosphate (S1P) content of sHDL and, possibly, depend on their cellular interaction through apoA-I and its SR-BI receptor. The sHDL3c isolated from MetS patients (n=5) possess reduced content of apoA-I and less potent anti-apoptotic activity (-60%, p<0.01) than controls (n=5). Conclusion: Normolipidemic small dense HDL3 provide potent protection of human endothelial cells from oxLDL-induced apoptosis; this anti-apoptotic activity is reduced in the MetS.

Apolipoproteína A-I

Apoptose

Células endoteliais

Dislipidemias

Esfingosina

Lipoproteínas do colesterol HDL

Síndrome X metabólica

ApolipoproteinA-I

Apoptosis and endothelial cell

Dislipidemia

HDL subfractions

Metabolic syndrome

Oxidised LDL

Sphingosine 1-phosphate