Differential modulation of ACAT1 and ACAT2 transcription and activity by long chain free fatty acids in cultured cells.

Fatty acyl CoA and cholesterol are the substrates for cholesteryl ester synthesis by acyl coenzyme A:cholesterol acyltransferase (ACAT). Two ACAT genes have been identified; ACAT1 is expressed ubiquitously while ACAT2 is primarily expressed in intestine and liver. We tested effects of different free fatty acids (FFAs) on ACAT1 and ACAT2 expression and activity in HepG2 human hepatocytes and THP1 human macrophages. Incubation of oleic acid, arachidonic acid, or eicosapentaenoic acid, but not 25-hydroxycholesterol, induced ACAT1 mRNA levels 1.5--2-fold in HepG2, with no affect on ACAT2 mRNA. FFA had no affect on ACAT1 mRNA in THP1 cells. To determine if FFAs affect ACAT1 or ACAT2 posttranscriptionally, cells were labeled with [(3)H]cholesterol in the presence of the different FFAs for 1--5 h. Both HepG2 and THP1 cells showed the greatest cholesteryl ester production with oleic acid. This was also confirmed by the observation that more [(3)H]oleic acid incorporated into CE compared to [(3)H]eicosapentaenoic acid, even though there was no difference in the total uptake of these FFAs. In ACAT-deficient SRD4, CHO cells stably transfected with human ACAT1 or ACAT2, ACAT1 expressing cells showed a strong preference for oleic acid while ACAT2 expressing cells utilized unsaturated FFAs. Acyl CoA substrate specificity was further tested in microsomes isolated from these cells as well as HepG2 and THP1. THP1 and ACAT1 cells utilized oleoyl CoA preferentially. In contrast, HepG2 and ACAT2 microsomes utilized linolenoyl CoA as well. We conclude that FFAs increase ACAT1 mRNA levels in a cell specific manner, and furthermore that the ACAT reactions exhibit differential FFA utilization.

Free cholesterol enhances adenoviral vector gene transfer and expression in CAR-deficient cells.

Efficient adenovirus vector-mediated gene transfer depends on the presence of sufficient amounts of the high-affinity coxsackie-adenovirus (Ad) receptor (CAR) on the surface of the target cell leading to receptor-mediated endocytosis of the vector. The present study evaluates the effect of free cholesterol, a lipid component of endocytic vesicles, on Ad uptake into CAR-deficient cells. Infection in the presence of free cholesterol at its maximum solubility in water led to increased binding, uptake, and expression of Ad in human skin fibroblasts and alveolar macrophages, two primary human cells known to be deficient in CAR. The effect of free cholesterol was maximal at its solubility maximum in aqueous solution. Increase of Ad vector-mediated gene transfer with cholesterol was dependent on the lack of CAR receptor expression on the surface and was diminished by overexpression of CAR in CAR-deficient cells. Cholesterol-mediated increase of Ad-mediated gene expression was dependent on coincubation of both cholesterol and Ad and was not dependent on the cholesterol content of the cell. Increased Ad vector-mediated gene expression in the presence of free cholesterol was also observed in murine skin in vivo. Structural analysis of the Ad-cholesterol mixture showed complexation between Ad particles leading to formation of multivirus aggregates due to hydrophobic interaction. The addition of free cholesterol with Ad vectors may be a simple way to increase Ad-mediated gene transfer to cells that are poor targets due to their lack of a sufficient number of Ad receptors.

Lipoprotein lipase-mediated selective uptake from low density lipoprotein requires cell surface proteoglycans and is independent of scavenger receptor class B type 1.

Lipoprotein lipase (LpL) hydrolyzes chylomicron and very low density lipoprotein triglycerides to provide fatty acids to tissues. Aside from its lipolytic activity, LpL promotes lipoprotein uptake by increasing the association of these particles with cell surfaces allowing for the internalization by receptors and proteoglycans. Recent studies also indicate that LpL stimulates selective uptake of lipids from high density lipoprotein (HDL) and very low density lipoprotein. To study whether LpL can mediate selective uptake of lipids from low density lipoprotein (LDL), LpL was incubated with LDL receptor negative fibroblasts, and the uptake of LDL protein, labeled with (125)I, and cholesteryl esters traced with [(3)H]cholesteryl oleoyl ether, was compared. LpL mediated greater uptake of [(3)H]cholesteryl oleoyl ether than (125)I-LDL protein, a result that indicated selective lipid uptake. Lipid enrichment of cells was confirmed by measuring cellular cholesterol mass. LpL-mediated LDL selective uptake was not affected by the LpL inhibitor tetrahydrolipstatin but was nearly abolished by heparin, monoclonal anti-LpL antibodies, or chlorate treatment of cells and was not found using proteoglycan-deficient Chinese hamster ovary cells. Selective uptake from HDL, but not LDL, was 2-3-fold greater in scavenger receptor class B type I overexpressing cells (SR-BI cells) than compared control cells. LpL, however, induced similar increases in selective uptake from LDL and HDL in either control or SR-BI cells, indicative of the SR-BI-independent pathway. This was further supported by ability of LpL to promote selective uptake from LDL in human embryonal kidney 293 cells, cells that do not express SR-BI. In Chinese hamster ovary cell lines that overexpress LpL, we also found that selective uptake from LDL was induced by both endogenous and exogenous LpL. Transgenic mice that overexpress human LpL via a muscle creatine kinase promoter had more LDL selective uptake in muscle than did wild type mice. In summary LpL stimulates selective uptake of cholesteryl esters from LDL via pathways that are distinct from SR-BI. Moreover this process also occurs in vivo in tissues where abundant LpL is present.

Fatty acids: links between genes involved in fatty acid and cholesterol metabolism.

Fatty acids are a major constituent of dietary fats and form an integral part of the cellular membrane and lipoproteins. The gene regulatory potential of fatty acids has long been recognized, but the precise regulatory mechanisms are unknown. The regulatory ability of fatty acids on the expression of a number of genes together with potential mechanisms and pathways of regulation are reviewed. In this review, we emphasize a key aspect of regulation mediated by the sterol regulatory element binding-protein, and its effects on sterol regulatory elements.

Polyunsaturated fatty acids decrease expression of promoters with sterol regulatory elements by decreasing levels of mature sterol regulatory element-binding protein.

Membrane physiology, plasma lipid levels, and intracellular sterol homeostasis are regulated by both fatty acids and cholesterol. Sterols regulate gene expression of key enzymes of cholesterol and fatty acid metabolism through proteolysis of the sterol regulatory element-binding protein (SREBP), which binds to sterol regulatory elements (SRE) contained in promoters of these genes. We investigated the effect of fatty acids on SRE-dependent gene expression and SREBP. Consistent results were obtained in three different cell lines (HepG2, Chinese hamster ovary, and CV-1) transfected with SRE-containing promoters linked to the luciferase expression vector. We show that micromolar concentrations of oleate and other polyunsaturated fatty acids (C18:2-C22:6) dose-dependently (0.075-0.6 mmol) decreased transcription of SRE-regulated genes by 20-75%. Few or no effects were seen with saturated free fatty acids. Fatty acid effects on SRE-dependent gene expression were independent and additive to those of exogenous sterols. Oleate decreased levels of the mature sterol regulatory element-binding proteins SREBP-1 and -2 and HMG-CoA synthase mRNA. Oleate had no effect in sterol regulation defective Chinese hamster ovary cells or in cells transfected with mutant SRE-containing promoters. We hypothesize that unsaturated fatty acids increase intracellular regulatory pools of cholesterol and thus affect mature SREBP levels and expression of SRE-dependent genes.