Hypercholesterolemia accelerates the Alzheimer's amyloid pathology in a transgenic mouse model.

Cellular Cholesterol Efflux Mediated by Cyclodextrins

Age-related myelin breakdown: a developmental model of cognitive decline and Alzheimer’s disease

Due to its presumed role in regulating cellular cholesterol homeostasis, and in various pathophysiological conditions, acyl-coenzyme A:cholesterol acyltransferase (ACAT) has attracted much attention. Cloning the ACAT gene provides the necessary tool to advance molecular studies of this enzyme. The topics reviewed in this chapter include the pathophysiological roles of ACAT, the biochemistry and molecular biology of the ACAT protein and the ACAT gene, and the mode of regulation by sterol or nonsterol agents in mammalian cells. In addition, we present a working model linking the presumed allosteric property of ACAT with cholesterol trafficking into and out of the endoplasmic reticulum.

Acyl-coenzyme a:cholesterol acyltransferase

Use of cyclodextrins for manipulating cellular cholesterol content.

Membrane cholesterol is distributed asymmetrically both within the cell or within cellular membranes. Elaboration of intracellular cholesterol trafficking, targeting and intramembrane distribution has been spurred by both molecular and structural approaches. The expression of recombinant sterol carrier proteins in L-cell fibroblasts has been especially useful in demonstrating for the first time that such proteins actually elicit intracellular and intra-plasma membrane redistribution of sterol. Additional advances in the use of native fluorescent sterols allowed resolution of transbilayer and lateral cholesterol domains in plasma membranes from cultured fibroblasts, brain synaptosomes and erythrocytes. In all three cell surface membranes, cholesterol is enriched in the inner, cytofacial leaflet. Up to three different cholesterol domains have been identified in the lateral plane of the plasma membrane: a fast exchanging domain comprising less than 10% of cholesterol, a slowly exchanging domain comprising ab...

Cholesterol domains in biological membranes.

Spontaneous and Protein-mediated Sterol Transfer between Intracellular Membranes

Rat liver fatty acid binding protein (L-FABP) and rat intestine fatty acid binding protein (I-FABP) are homologous proteins which are both found in intestinal epithelial cells. It was once well accepted that liver fatty acid binding protein bound fatty acyl-CoAs, but the recent finding of a novel acyl-CoA binding protein (ACBP) in preparations of L-FABP has challenged the role of FABPs in acyl-CoA metabolism. Prior to the discovery of ACBP, L-FABP preparations from liver were shown to modulate the rate of fatty acyl-CoA synthesis (Burrier et al., 1987) and their conversion to phospholipids (Bordewick et al., 1989). Studies using FABPs free of ACBP are needed to determine the role of I-FABP and L-FABP in fatty acyl-CoA metabolism. In this study, highly pure recombinant L-FABP and I-FABP were used first to establish binding to fatty acyl-CoAs and then to examine the effects of these FABPs on microsomal phosphatidic acid synthesis. The standard Lipidex-1000 binding assay using [14C]oleoyl-CoA and a new fluorescence binding assay using the fluorescent fatty acyl-CoA cis-parinaroyl-CoA were used to determine binding. The results of these assays indicate that L-FABP binds fatty acyl-CoAs at two sites with a high-affinity Kd = 3-14 microM. These binding assays showed that I-FABP has a much lower affinity for fatty acyl-CoAs than does L-FABP. Furthermore, in vitro only L-FABP significantly increases the rate of incorporation of oleoyl-CoA into lysophosphatidic acid and phosphatidic acid.

Recombinant liver fatty acid binding protein interacts with fatty acyl-coenzyme A.

Fatty acid-binding proteins (FABP) are abundant cytosolic proteins whose level is responsive to nutritional, endocrine, and a variety of pathological states. Although FABPs have been investigated in vitro for several decades, little is known of their physiological function. Liver L-FABP binds both fatty acids and cholesterol. Competitive binding analysis and molecular modeling studies of L-FABP indicate the presence of two ligand binding pockets that accomodate one fatty acid each. One fatty acid binding site is identical to the cholesterol binding site. To test whether these observations obtained in vitro were physiologically relevant, the cDNA encoding L-FABP was transfected into L-cells, a cell line with very low endogenous FABP and sterol carrier proteins. Uptake of both ligands did not differ between control cells and low expression clones. In contrast, both fatty acid uptake and cholesterol uptake were stimulated in the high expression cells. In high expression cells, uptake of fluorescent cis-parinaric acid was enhanced more than that of trans-parinaric acid. This is consistent with the preferential binding of cis-fatty acids to L-FABP but in contrast to the preferential binding of trans-parinaric acid to the L-cell plasma membrane fatty acid transporter (PMFABP). These data show that the level of cytosolic fatty acids in intact cells can regulate both the extent and specificity of fatty acid uptake. Last, sphingomyelinase treatment of L-cells released cholesterol from the plasma membrane to the cytoplasm and stimulated microsomal acyl-CoA: cholesteryl acyl transferase (ACAT). This process was accelerated in high expression cells. These observations show for the first time in intact cells that L-FABP, a protein most prevalent in liver and intestine where much fat absorption takes place, may have a role in fatty acid and cholesterol absorption.

Expression of rat L-FABP in mouse fibroblasts: role in fat absorption

The interaction of human recombinant sterol carrier protein-2 (SCP-2) with sterols was examined. Two independent ligand binding methods, Lipidex 1000 binding of [3H]cholesterol and a fluorescent dehydroergosterol binding assay, were used to determine the affinity of SCP-2 for sterols. Binding analysis indicated SCP-2 bound [3H]cholesterol and dehydroergosterol with aKd of 0.3 and 1.7 μM, respectively, and suggested the presence of a single binding site. Phase fluorometry and circular dichroism were used to characterize the SCP-2 sterol binding site. Alterations in dehydroergosterol lifetime, SCP-2 tryptophan lifetime, and SCP-2 tryptophan quenching by acrylamide upon cholesterol binding demonstrated a shielding of the SCP-2 tryptophan from the aqueous solvent by bound sterol. Differential polarized phase fluorometry revealed decreased SCP-2 tryptophan rotational correlation time upon cholesterol binding. Circular dichroism of SCP-2 indicated that cholesterol elicited a small decrease in SCP-2 alpha helical content. The data suggest that SCP-2 binds sterols with affinity consistent with a lipid transfer protein that may act either as an aqueous carrier or at a membrane surface to enhance sterol desorption.

Judith K. Woodford

Papers

Cholesterol domains in biological membranes.

Spontaneous and Protein-mediated Sterol Transfer between Intracellular Membranes

Recombinant liver fatty acid binding protein interacts with fatty acyl-coenzyme A.

Expression of rat L-FABP in mouse fibroblasts: role in fat absorption

Cholesterol interaction with recombinant human sterol carrier protein-2.