BACKGROUND AND PURPOSE: 7-Ketocholesterol, an oxysterol present in atherosclerotic lesions, induces smooth muscle cell (SMC) death, thereby destabilizing plaques. Statins protect patients from myocardial infarction, though they induce SMC apoptosis. We investigated whether statins and 7-ketocholesterol exerted additive cell death effects. EXPERIMENTAL APPROACH: Cultured rabbit aorta SMCs (passage 2-6) were exposed to 7-ketocholesterol with or without fluvastatin, simvastatin or pravastatin. Uptake of neutral red (NR), monolayer protein, cleavage of the pan-caspase substrate Asp-Glu-Val-Asp-rhodamine110, cell morphology (light and electron microscopy) and processing of microtubule-associated protein 1 light chain 3 (LC3, immunoblot) were determined. KEY RESULTS: NR uptake declined upon 18 h exposure to 25 microM 7-ketocholesterol (-41+/-3%, n=13), 100 microM fluvastatin (-59%) or 30-100 microM simvastatin (-28 to -74%). Oxysterol and high statin concentrations exerted additive effects, but lower concentrations (fluvastatin 10-30 microM, simvastatin 1-10 microM) partly reversed viability loss. 7-Ketocholesterol caused intense cytoplasmic vacuolization, processing of LC3-I to LC3-II, but little caspase activation (increase 29.5%). Fluvastatin (10-100 microM, 70-545% increase) and simvastatin (3-100 microM 43-322% increase) induced caspase activation without LC3 processing, but failed to activate caspases in 7-ketocholesterol-treated SMCs. Pravastatin up to 100 microM was always inactive. CONCLUSIONS AND IMPLICATIONS: 7-Ketocholesterol caused SMC death, mainly via autophagic vesicle formation with LC3 processing, whereas lipophilic statins evoked SMC apoptosis. Cell death following 7-ketocholesterol and low statin concentrations were not additive, presumably because the autophagic process interfered with statin-induced caspase activation. This further illustrates that drug effects in normal SMCs are not necessarily predictive for activities in atherosclerotic settings.
BACKGROUND AND PURPOSE:7-Ketocholesterol, an oxysterol present in atherosclerotic lesions, induces smooth muscle cell (SMC) death, thereby destabilizing plaques. Statins protect patients from myocardial infarction, though they induce SMC apoptosis. We investigated whether statins and 7-ketocholesterol exerted additive cell death effects. EXPERIMENTAL APPROACH: Cultured rabbit aorta SMCs (passage 2-6) were exposed to 7-ketocholesterol with or without fluvastatin, simvastatin or pravastatin. Uptake of neutral red (NR), monolayer protein, cleavage of the pan-caspase substrate Asp-Glu-Val-Asp-rhodamine110, cell morphology (light and electron microscopy) and processing of microtubule-associated protein 1 light chain 3 (LC3, immunoblot) were determined. KEY RESULTS: NR uptake declined upon 18 h exposure to 25 microM 7-ketocholesterol (-41+/-3%, n=13), 100 microM fluvastatin (-59%) or 30-100 microM simvastatin (-28 to -74%). Oxysterol and high statin concentrations exerted additive effects, but lower concentrations (fluvastatin 10-30 microM, simvastatin 1-10 microM) partly reversed viability loss. 7-Ketocholesterol caused intense cytoplasmic vacuolization, processing of LC3-I to LC3-II, but little caspase activation (increase 29.5%). Fluvastatin (10-100 microM, 70-545% increase) and simvastatin (3-100 microM 43-322% increase) induced caspase activation without LC3 processing, but failed to activate caspases in 7-ketocholesterol-treated SMCs. Pravastatin up to 100 microM was always inactive. CONCLUSIONS AND IMPLICATIONS: 7-Ketocholesterol caused SMC death, mainly via autophagic vesicle formation with LC3 processing, whereas lipophilic statins evoked SMC apoptosis. Cell death following 7-ketocholesterol and low statin concentrations were not additive, presumably because the autophagic process interfered with statin-induced caspase activation. This further illustrates that drug effects in normal SMCs are not necessarily predictive for activities in atherosclerotic settings.
Authors: C Miguet; S Monier; A Bettaieb; A Athias; G Besséde; A Laubriet; S Lemaire; D Néel; P Gambert; G Lizard Journal: Cell Death Differ Date: 2001-01 Impact factor: 15.828
Authors: J R Sindermann; L Fan; K A Weigel; D Troyer; J G Müller; A Schmidt; K L March; G Breithardt Journal: Atherosclerosis Date: 2000-06 Impact factor: 5.162
Authors: Jonathan W Wojtkowiak; Komal M Sane; Miriam Kleinman; Bonnie F Sloane; John J Reiners; Raymond R Mattingly Journal: J Pharmacol Exp Ther Date: 2011-01-12 Impact factor: 4.030
Authors: Allen M Andres; Genaro Hernandez; Pamela Lee; Chengqun Huang; Eric P Ratliff; Jon Sin; Christine A Thornton; Marichris V Damasco; Roberta A Gottlieb Journal: Antioxid Redox Signal Date: 2013-09-20 Impact factor: 8.401