Abstract
Small angle X-ray diffraction was used to examine arterial smooth muscle cell (SMC) plasma membranes isolated from control and cholesterol-fed (2%) atherosclerotic rabbits. A microsomal membrane enriched with plasma membrane obtained from animals fed cholesterol for up to 13 weeks showed a progressive elevation in the membrane unesterified (free) cholesterol:phospholipid (C/PL) mole ratio. Beyond 9 weeks of cholesterol feeding, X-ray diffraction patterns demonstrated a lateral immiscible cholesterol domain at 37 degrees C with a unit cell periodicity of 34 A coexisting within the liquid crystalline lipid bilayer. On warming, the immiscible cholesterol domain disappeared, and on cooling it reappeared, indicating that the immiscible cholesterol domain was fully reversible. These effects were reproduced in a model C/PL binary lipid system. In rabbits fed cholesterol for less than 9 weeks, lesser increases in membrane C/PL mole ratio were observed. X-ray diffraction analysis demonstrated an increase in membrane bilayer width that correlated with the C/PL mole ratio. This effect was also reproduced in a C/PL binary lipid system. Taken together, these findings demonstrate that in vivo, feeding of cholesterol causes cholesterol-phospholipid interactions in the membrane bilayer that alter bilayer structure and organization. This interaction results in an increase in bilayer width peaking at a saturating membrane cholesterol concentration, beyond which lateral phase separation occurs resulting in the formation of separate cholesterol bilayer domains. These alterations in structure and organization in SMC plasma membranes may have significance in phenotypic modulation or aortic SMC during early atherogenesis.
Highlights
Small angle X-ray diffraction was used to examine arterial smooth muscle cell (SMC) plasma membranes isolated from control and cholesterol-fed (2%) atherosclerotic rabbits
The results of this study indicate that fundamental changes in SMC plasma membrane structure and lipid organization occur as a direct result of physical interactions of cholesterol with neighboring membrane phospholipid molecules in vivo during the development of dietary atherosclerosis, which may account, in part, for some of the changes in the cell biology of SMC in this disease
Microsomal membranes isolated from freshly dispersed SMC cells showed a 13-fold enrichment in the specific plasma membrane marker, alkaline phosphodiesterase (APD)
Summary
Small angle X-ray diffraction was used to examine arterial smooth muscle cell (SMC) plasma membranes isolated from control and cholesterol-fed (2%) atherosclerotic rabbits. X-ray diffraction analysis demonstrated an increase in membrane bilayer width that correlated with the C/PL mole ratio This effect was reproduced in a C/PL binar y lipid system. Taken together, these findings demonstrate that in vivo, feeding of cholesterol causes cholesterol–phospholipid interactions in the membrane bilayer that alter bilayer structure and organization. Incorporation of cholesterol into lipid bilayers increases the modulus of compressibility (K) of the liquid-crystalline state [7, 8] These studies demonstrate that changes in membrane cholesterol content alter the physical properties of the lipid bilayer which may, in turn, modulate membrane protein function, and cell function. Small angle X-ray diffraction studies have provided direct evidence of physical interactions of cholesterol with membranes, suggesting that cholesterol perturbs the structure of the membrane lipid bilayer [9, 10], including hydrocarbon core width, in a concentration-dependent
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