The smooth muscle cell membrane during atherogenesis: A potential target for amlodipine in atheroprotection

The smooth muscle cell membrane during atherogenesis: A potential target for amlodipine in atheroprotection

Background Atherosclerotic disease has been present in the human population apparently from the beginning of time. However, it has only been in the 20th century that improvements in the control of infectious diseases have allowed the average life span to increase to the point where atherosclerosis h...

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Bibliographic Details
Published in:The American heart journal Vol. 141; no. 2; pp. S1 - S11
Main Authors: Tulenko, T.N., Sumner, A.E., Chen, M., Huang, Y., Laury-Kleintop, L., Ferdinand, F.D.
Format: Journal Article Conference Proceeding
Language:English
Published: New York, NY Mosby, Inc 01-02-2001
Elsevier
Subjects:
Amlodipine - therapeutic use
Animals
Arteriosclerosis - metabolism
Arteriosclerosis - pathology
Arteriosclerosis - prevention & control
Atherosclerosis (general aspects, experimental research)
Biological and medical sciences
Blood and lymphatic vessels
Calcium - metabolism
Calcium Channel Blockers - therapeutic use
Cardiology. Vascular system
Cell Membrane - drug effects
Cell Membrane - metabolism
Cell Membrane - ultrastructure
Cell Membrane Permeability - drug effects
Cholesterol, LDL - metabolism
Disease Progression
Humans
Medical sciences
Muscle, Smooth, Vascular - drug effects
Muscle, Smooth, Vascular - metabolism
Muscle, Smooth, Vascular - pathology
Risk Factors
Cell proliferation
Pharmacologic test
Vasodilator agent
Calcium antagonist
Rabbit
Cardiovascular disease
Smooth muscle
Lagomorpha
Vascular disease
Vertebrata
Mammalia
Animal
Atherosclerosis
Plasma membrane
Amlodipine
Dihydropyridine derivatives
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Summary:Background Atherosclerotic disease has been present in the human population apparently from the beginning of time. However, it has only been in the 20th century that improvements in the control of infectious diseases have allowed the average life span to increase to the point where atherosclerosis has been able to affect the general population. By the middle of the 20th century, atherosclerosis had reached epidemic levels, and it is currently pandemic and increasing worldwide. Despite its growing significance to health care, we still know relatively little about the cellular basis for plaque genesis in the vessel wall. Current thinking holds that atherosclerosis is caused by an unchecked chronic inflammatory process involving the cells of the arterial wall and their interaction with LDL and various inflammatory cells. Considerable evidence suggests that the principal insults underlying atherogenesis are serum dyslipidemias and oxidative stress mediated primarily by oxidized LDL. However, just how these insults alter the cell biology of vascular cells and lead to the atherosclerotic phenotype is still under intense investigation. Moreover, recent clinical trials have provided evidence that certain classes of drugs, including newer calcium channel blockers (CCBs), can remodel the arterial smooth muscle cell (SMC) membrane and inhibit the progression of atherosclerotic disease. Methods This review summarizes our current thinking on atherogenesis in the arterial SMC and considers recent developments regarding alterations in the SMC membrane during the very early period of atherogenesis. We also discuss how certain CCBs might operate to produce atheroprotection. Results The SMC membrane becomes enriched in unesterified cholesterol soon after the development of serum hypercholesterolemia. With excess membrane cholesterol, the membrane becomes thicker and develops distinct cholesterol domains. These alterations in the membrane increase the permeability of SMC to calcium and induce a variety of alterations in SMC function that contribute to cellular atherogenic processes during plaque genesis. Amlodipine, a third-generation CCB, markedly inhibits the progression of lesions. The explanation of this novel action may lie in the effects of this drug on various potential cellular targets. Conclusions Evidence is accumulating that excess membrane cholesterol may contribute to the cellular defects responsible for the transformation of the SMC to the atherosclerotic phenotype. Amlodipine, which has membrane–remodeling properties, is emerging as an important atheroprotective drug. (Am Heart J 2001;141:S1-11.)
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ISSN:0002-8703
1097-6744
DOI:10.1067/mhj.2001.109947