 | | CETP as a Target in HDL-Raising Therapy: Lessons from APOE*3-Leiden.CETP Transgenic Mice |
|  | | CETP as a target in HDL-raising therapy lessons from APOE*3-Leiden.CETP mice |
|
 | | Outline of Presentation |
|  | | Outline of Presentation |
|
 | | Lipoprotein metabolism |
|  | | Lipoprotein metabolism |
|
 | | Role of CETP in lipoprotein metabolism |
|  | | Therapy of CVD-associated dyslipidemia�money spent on drugs to treat dyslipidemia� |
|
 | | CVD-associated dyslipidemia�mainly treated with statins |
|  | | Novel therapeutic strategies�currently in development |
|
 | | Outline of Presentation |
|  | | HDL-C is a strong inverse predictor�of CHD risk at all levels of LDL-C |
|
 | | Antiatherogenic properties of HDL |
|  | | First HDL-raising strategy: CETP inhibition |
|
 | | CETP inhibitor: Torcetrapib |
|  | | Torcetrapib strongly increases HDL-C levels�Phase I studies in normolipidemic healthy volunteers |
|
 | | Torcetrapib strongly increases HDL but does not reduce atherosclerosis! |
|  | | Elucidation of (adverse) effects of torcetrapib in mice through translational research |
|
 | | Wild-type mice:�low (V)LDL and high HDL |
|  | | Mouse model for human-like lipoprotein metabolism |
|
 | | Structure apoE |
|  | | APOE*3-Leiden.CETP transgenic mice:�human-like lipoprotein metabolism |
|
 | | APOE*3-Leiden.CETP transgenic mice: human-like lipoprotein metabolism |
|  | | APOE*3-Leiden.CETP mice:�human-like lipoprotein metabolism |
|
 | | Effect CETP expression on atherosclerosis�study design |
|  | | CETP expression in APOE*3-Leiden mice aggravates diet-induced atherosclerosis |
|
 | | Atherosclerosis development in E3L.CETP mice�is not simply predicted from cholesterol exposure |
|  | | APOE*3-Leiden.CETP mouse:�model for human-like lipoprotein metabolism |
|
 | | Torcetrapib in E3L.CETP mice |
|  | | Torcetrapib decreases CETP activity�Oral gavage in solutol:ethanol:saline (10:10:80) |
|
 | | Torcetrapib decreases CETP activity�Oral gavage in solutol:ethanol:saline (10:10:80) (10 mg/kg) |
|  | | Torcetrapib tends to decreases cholesterol�Diet + 0.1% cholesterol + torcetrapib |
|
 | | Torcetrapib increases HDL in E3L.CETP mice�Diet + 0.1% cholesterol + 0.01% torcetrapib |
|  | | Effect of torcetrapib on atherosclerosis development in APOE*3-Leiden.CETP mice |
|
 | | Torcetrapib reduces CETP activity�and increases CETP mass |
|  | | Torcetrapib reduces CETP activity |
|
 | | Torcetrapib reduces plasma total cholesterol�and increases HDL-cholesterol |
|  | | Torcetrapib reduces atherosclerotic lesion area, but does not add to the effect of atorvastatin |
|
 | | Torcetrapib reduces atherosclerotic plaque severity,�but not beyond atorvastatin |
|  | | Torcetrapib increases MCP-1 content, monocyte adherence, and macrophage content of the plaque |
|
 | | Torcetrapib decreases collagen content of the plaque, independent of smooth muscle cell content |
|  | | Torcetrapib induces an unstable lesion phenotype as compared to atorvastatin |
|
 | | Torcetrapib tends to increase�general inflammatory status |
|  | | Torcetrapib increases general�inflammatory status and plasma aldosterone |
|
 | | Torcetrapib increases plasma aldosterone via�class-specific effect independent of CETP inhibition |
|  | | Outline of Presentation |
|
 | | Current drugs that increase HDL-C levels |
|  | | Fenofibrate and atorvastatin in E3L.CETP mice |
|
 | | Fenofibrate |
|  | | Fenofibrate decreases TG in E3L.CETP mice�Diet + 0.25% cholesterol + 0-0.04% fenofibrate (males) |
|
 | | Fenofibrate increases HDL in E3L.CETP mice�Diet + 0.25% cholesterol + fenofibrate (males) |
|  | | Fenofibrate increases HDL in E3L.CETP mice�Diet + 0.25% cholesterol + 0.04% fenofibrate (males) |
|
 | | Fenofibrate increases HDL in E3L.CETP mice�Diet + 0.25% cholesterol + 0.04% fenofibrate (males) |
|  | | FF does not differentially affect HDL genes�Diet + 0.25% cholesterol + 0.04% fenofibrate (males) |
|
 | | Fenofibrate increases HDL in E3L.CETP mice�Diet + 0.25% cholesterol + 0.04% fenofibrate (males) |
|  | | Atorvastatin in E3L.CETP mice |
|
 | | Atorvastatin |
|  | | Atorvastatin decreases TC in E3L.CETP mice�Diet + 0.1% cholesterol + atorvastatin (females) |
|
 | | Atorvastatin increases HDL in E3L.CETP mice�Diet + 0.25% cholesterol + 0.01% atorvastatin (males) |
|  | | Atorvastatin increases HDL in E3L.CETP mice�Diet + 0.25% cholesterol + 0.01% atorvastatin (males) |
|
 | | Atorva does not differentially affect HDL genes�Diet + 0.25% cholesterol + 0.01% atorvastatin (males) |
|  | | Atorvastatin reduces CETP expression�Diet + 0.25% cholesterol + 0.01% atorvastatin (males) |
|
 | | Atorvastatin reduces CETP mass and activity�Diet + 0.25% cholesterol + atorvastatin (females) |
|  | | Mechanism underlying HDL-raising effect�of statins and fibrates |
|
 | | Niacin |
|  | | Niacin strongly reduces cardiac events |
|
 | | Atheroprotective effect of niacin is accompanied by a large increase in HDL level |
|  | | Niacin potently increases plasma HDL levels |
|
 | | Niacin does not affect HDL in E3L mice�Diet + 0.1% cholesterol + 0.3% niacin (female mice) |
|  | | Niacin decreases TG and TC in E3L.CETP�Diet + 0.1% cholesterol + niacin (female mice) |
|
 | | Niacin decreases TG and TC in E3L.CETP�Diet + 0.1% cholesterol + niacin (female mice) |
|  | | Niacin increases HDL in E3L.CETP mice�Diet + 0.1% cholesterol + niacin (female mice) |
|
 | | Niacin increases HDL in E3L.CETP mice�Diet + 0.1% cholesterol + niacin (female mice) |
|  | | Niacin decreases clearance of 125I-apoAI-HDL�Diet + 0.1% cholesterol + niacin (female mice) |
|
 | | Niacin decreases liver lipids�Diet + 0.1% cholesterol + niacin (female mice) |
|  | | Niacin decreases plasma CETP activity�Diet + 0.1% cholesterol + niacin (female mice) |
|
 | | Niacin increases HDL particle size�Diet + 0.1% cholesterol + niacin (female mice) |
|  | | Mechanism underlying HDL-raising effect�of niacin |
|
 | | Niacin causes regression of atherosclerosis |
|  | | Translational research: relation between�liver lipid, CETP and HDL-C in humans |
|
 | | Determination of liver TG by�proton MR spectroscopy of the liver |
|  | | Pioglitazone and metformin�equally reduce plasma apoB100 and TG |
|
 | | Pioglitazone raises HDL-C,�reduces CETP and reduces liver lipid |
|  | | Outline of Presentation |
|
 | | Conclusions |
|  | | APOE*3-Leiden.CETP mouse |
|
 | | APOE*3-Leiden.CETP mice |
|  | | Acknowledgments |
|
 | | Thank you! |
|  | | The atherogenicity of CETP depends on TG�Prospective data from the Epic-Norfolk study� |
|
 | | CETP mutation Ile405Val increases HDL… |
|  | | … but increases CVD risk! |
|
 | | Effect of CETP on VLDL levels seem to largely explain increased atherosclerosis |
|  | | Slide 94 |
|
 | | Effect of CETP expression on atherosclerosis in APOE*3-Leiden mice |
|  | | APOE*3-Leiden.CETP mice�altered lipoprotein profile (female, chow diet) |
|
 | | Effect CETP expression on atherosclerosis�study design |
|  | | CETP expression increases plasma cholesterol and shifts cholesterol distribution |
|
 | | Quantification of atherosclerosis development in heart valve area in aortic root |
|  | | CETP aggravates lesion severity in aortic root�Western-type diet (19 weeks); HPS staining� |
|
 | | CETP increases atherosclerotic lesion area�Western-type diet (19 weeks); HPS staining� |
|  | | LXR agonist in E3L.CETP mice |
|
 | | LXR agonist decreases HDL in E3L.CETP�Diet + 0.25% cholesterol + 0.01% T0901317 (male mice) |
|  | | LXR agonist decreases HDL in E3L.CETP�Diet + 0.25% cholesterol + 0.01% T0901317 (male mice) |
|
 | | LXR agonist decreases HDL in E3L.CETP�Diet + 0.25% cholesterol + 0.01% T0901317 (male mice) |
|  | | Torcetrapib |
|
 | | Torcetrapib increases HDL in E3L.CETP mice�Oral gavage in solutol:ethanol:saline (10:10:80) (females) |
|  | | Torcetrapib tends to decreases cholesterol�Diet + 0.1% cholesterol + torcetrapib (females) |
|
 | | Torcetrapib increases HDL in E3L.CETP mice�Diet + 0.1% cholesterol + 0.01% torcetrapib (females) |
|  | | CETP inhibitor Merck in CETP mice |
|
 | | CETP-I increases HDL-C in CETP mice�Chow diet + 0.05% CETP inhibitor (~50 mg/kg) |
|  | | CETP-I increases HDL-C in CETP mice�Chow diet + 0.05% CETP inhibitor (male mice) |
|
 | | CETP-I increases HDL-C in CETP mice�Diet + 0….% cholesterol + …% CETP-I (male mice) |
|  | | Bile acids in E3L.CETP mice |
|
 | | Bile acids decrease HDL-C in E3L.CETP mice�Chow diet + 0.5% TCA (male mice) |
|  | | Bile acids increase CETP in E3L.CETP mice�Chow diet + 0.5% TCA (male mice) |
|
 | | Conclusions |
|  | | Human Lipoprotein Metabolism |
|
 | | Lipoprotein metabolism – back to basics! |
|  | | Reduction of LDL cholesterol by statins (II) |
|
 | | Lipoproteins - Composition |
|  | | Lipoproteins - Size |
|
 | | Lipoproteins differ in size and density |
|  | | Lipoproteins differ in size and density |
|
 | | Lipoprotein Metabolism |
|  | | Dyslipidemia |
|
 | | Statins reduce LDL-cholesterol by inhibiting HMG-CoA reductase |
|  | | Factors known to reduce HDL-C levels (I) |
|
 | | Factors known to reduce HDL-C levels (II) |
|  | | Anti-atherogenic activities of HDL particles (II) |
|
 | | Anti-atherogenic activities of HDL particles (I) |
|  | | HDL is an anti-inflammatory agent |
|
 | | Torcetrapib strongly increases HDL-C levels�Phase I studies in normolipidemic healthy volunteers (II) |
|  | | Torcetrapib: large phase III trial in patients |
|
 | | Torcetrapib lacks anti-atherosclerotic efficacy! |
|  | | Potential explanations for failure of torcetrapib |
|
 | | Lipoprotein Metabolism - mouse |
|  | | Lipoprotein Metabolism |
|
 | | APOE*3-Leiden mouse |
|  | | Atherosclerosis development in APOE*3-Leiden mice depends on cholesterol exposure |
|
 | | Rosuvastatin reduces plasma cholesterol�in APOE*3-Leiden mice |
|  | | Rosuvastatin reduces atherosclerosis compared�to high and low cholesterol groups |
|
 | | Rosuvastatin reduces expression of�monocyte chemotactic protein-1 (MCP-1) |
|  | | Rosuvastatin reduces expression of MCP-1 compared to high and low cholesterol groups |
|
 | | Rosuvastatin reduces serum amyloid A (SAA) compared to high and low cholesterol groups |
|  | | Regression of atherosclerosis�in APOE*3-Leiden mice |
|
 | | Introduction of CETP in APOE*3-Leiden mice |
|  | | Introduction of CETP in APOE*3-Leiden mice |
|
 | | Overview of Presentation |
|  | | raising HDL: novel therapeutic targets |
|
 | | raising HDL: novel therapeutic targets |
|  | | Experimental HDL-directed drugs |
|
 | | ApoAIMilano (I) |
|  | | ApoAIMilano (II) |
|
 | | D4F |
|  | | Niacin decreases plasma lipase activity�Diet + 0.1% cholesterol + niacin (female mice) |
|
 | | Therapy of CVD-associated dyslipidemia�market for drugs to treat dyslipidemia� |
|  | | Anti-atherogenic activities of HDL particles |
|
 | | HDL plays role in reverse cholesterol transport |
|  | | Anti-atherogenic activities of HDL particles |
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