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Cholesterols reverse transport

The pathways of HDL metabolism and reverse cholesterol transport are complex (Fig. 3, [1]). HDL and its major apolipoprotein apoA-I are synthesized by both the intestine and the liver. A second major... [Pg.697]

Lipoprotein Metabolism. Figure 3 HDL metabolism and reverse cholesterol transport. [Pg.698]

Macrophage/athero- t Reverse cholesterol transport from foam cells l Progression of atherosclerosis... [Pg.943]

HDL concentrations vary reciprocally with plasma triacylglycerol concentrations and directly with the activity of lipoprotein lipase. This may be due to surplus surface constituents, eg, phospholipid and apo A-I being released during hydrolysis of chylomicrons and VLDL and contributing toward the formation of preP-HDL and discoidal HDL. HDLj concentrations are inversely related to the incidence of coronary atherosclerosis, possibly because they reflect the efficiency of reverse cholesterol transport. HDL, (HDLj) is found in... [Pg.210]

Four major groups of lipoproteins are recognized Chylomicrons transport lipids resulting from digestion and absorption. Very low density lipoproteins (VLDL) transport triacylglycerol from the liver. Low-density lipoproteins (LDL) deliver cholesterol to the tissues, and high-density lipoproteins (HDL) remove cholesterol from the tissues in the process known as reverse cholesterol transport. [Pg.217]

Figure 26-5. Factors affecting cholesterol balance at the cellular level. Reverse cholesterol transport may be initiated by pre 3 HDL binding to the ABC-1 transporter protein via apo A-l. Cholesterol is then moved out of the cell via the transporter, lipidating the HDL, and the larger particles then dissociate from the ABC-1 molecule. (C, cholesterol CE, cholesteryl ester PL, phospholipid ACAT, acyl-CoA cholesterol acyltransferase LCAT, lecithinicholesterol acyltransferase A-l, apolipoprotein A-l LDL, low-density lipoprotein VLDL, very low density lipoprotein.) LDL and HDL are not shown to scale. Figure 26-5. Factors affecting cholesterol balance at the cellular level. Reverse cholesterol transport may be initiated by pre 3 HDL binding to the ABC-1 transporter protein via apo A-l. Cholesterol is then moved out of the cell via the transporter, lipidating the HDL, and the larger particles then dissociate from the ABC-1 molecule. (C, cholesterol CE, cholesteryl ester PL, phospholipid ACAT, acyl-CoA cholesterol acyltransferase LCAT, lecithinicholesterol acyltransferase A-l, apolipoprotein A-l LDL, low-density lipoprotein VLDL, very low density lipoprotein.) LDL and HDL are not shown to scale.
Familial lecithimcholesterol acyltransferase (LCAT) deficiency Absence of LCAT leads to block in reverse cholesterol transport. HDL remains as nascent disks incapable of taking up and esterifying cholesterol. Plasma concentrations of cholesteryl esters and lysolecithin are low. Present is an abnormal LDL fraction, lipoprotein X, found also in patients with cholestasis. VLDL is abnormal ( 3-VLDL). [Pg.228]

Niacin (vitamin B3) has broad applications in the treatment of lipid disorders when used at higher doses than those used as a nutritional supplement. Niacin inhibits fatty acid release from adipose tissue and inhibits fatty acid and triglyceride production in liver cells. This results in an increased intracellular degradation of apolipoprotein B, and in turn, a reduction in the number of VLDL particles secreted (Fig. 9-4). The lower VLDL levels and the lower triglyceride content in these particles leads to an overall reduction in LDL cholesterol as well as a decrease in the number of small, dense LDL particles. Niacin also reduces the uptake of HDL-apolipoprotein A1 particles and increases uptake of cholesterol esters by the liver, thus improving the efficiency of reverse cholesterol transport between HDL particles and vascular tissue (Fig. 9-4). Niacin is indicated for patients with elevated triglycerides, low HDL cholesterol, and elevated LDL cholesterol.3... [Pg.189]

Bailey, KR, Ishida, BY, Duncan, KG, Kane, JP, and Schwartz, DM, 2004. Basal reverse cholesterol transport of retinal pigment epithelium cell digested photoreceptor outer segment lipids. Invest Ophthalmol Vis Sci 45, U721. [Pg.339]

Apolipoprotein AI (apoAI) is the major apolipoprotein of HDL and plays an important role in the formation of mature HDL and the reverse cholesterol transport. HDL concentrations are largely determined by the rate of synthesis of apoAI in the liver. As a consequence deficiency of apoAI results in an almost complete absence of HDL and in accelerated atherosclerosis. In the promoter of the apoAI... [Pg.272]

PXR CAR FXR LXR AhR 3A4 and others 2B, 2C, 3A4 7A 7A 1A1, 1A2, 1A6, 1B1, 2S1 Xenobiotic metabolism regulation, antioxidant Xenobiotic metabolism regulation Bile add metabolism and transport Reverse cholesterol transport and absorption Reproduction and development regulation... [Pg.320]

A high plasma concentration of LDL (usually measured as LDL-cholesterol) is a risk factor for the development of atheroma whereas a high concentration of HDL is an anti-risk factor for cardiovascular disease (CVD). Fundamental discoveries relating to cholesterol metabolism and the importance of the LDL receptor made by Nobel laureates Joseph Goldstein and Michael Brown led to an understanding of the role of LDL in atherosclerosis. The impact of HDL in reducing CVD risk is often explained by the removal of excess cholesterol from tissues and its return to the liver, a process known as reverse cholesterol transport. However, evidence from research by Gillian Cockerill and others shows that HDL has a fundamental anti-inflammatory role to play in cardioprotection. [Pg.165]

Von Eckardstein, A., Nofer, J.R., and Assmann, G., 2001, High density hpoproteins and arteriosclerosis. Role of cholesterol efflux and reverse cholesterol transport, Arterioscler. Thromb. Vase. Biot. 21 13-27. [Pg.150]

ICAT (or PCAT, phosphatidylcholine-cholesterol acyltransferase) is an enzyme in the blood that is activated by apoA-1 on HDL. LCAT adds a fatty add to cholesterol, producing cholesterol esters, which dissolve in the core of the HDL, allowing HDL to transport cholesterol from the periphery to the liver. This process of reverse cholesterol transport is shown in Figure 1-15-7. [Pg.215]

The HDL may subsequently be picked up by the liver throu the apoE receptor or deliver cholesterol throi the scavenger receptor SR-Bl (reverse cholesterol transport firom the periphery to the liver). The HDL may also transfer the cholesterol to an IDL reforming a normal, unoxidized LDL particle. [Pg.217]

Another receptor, LXR (Liver X receptor), also exists in alpha and beta forms, and acts as a receptor for cholesterol and its degradation products, which accumulate when cholesterol levels are high. LXRs are expressed in the liver and lower digestive tract, where they regulate cholesterol and bile-acid homeostasis. LXR-beta activates reverse cholesterol transport from the periphery to the liver. LXR-alpha, which is found in the liver, promotes catabolism in the liver and drives catabolism of cholesterol to BAs. Its activation in the liver increases... [Pg.5]

G. HDL particles have several functions, but among the most important is transport of excess cholesterol scavenged from the cell membranes back to the liver, a process called reverse cholesterol transport. [Pg.105]

Low HDL cholesterol (<35 mg/dL) is an independent risk factor for CHD. HDL appears to antagonize atherogenesis by at least two mechanisms. HDL can mobilize cholesterol from extrahepatic cells (such as arterial wall foam cells) and transport it to the liver for disposal (reverse cholesterol transport) HDL also has antioxidant properties. HDL contains the potent antioxidant enzyme paraoxonase, which may protect LDL lipids from oxidation. Thus, hypertriglyceridemia with... [Pg.273]

Whole plasma can also be fractionated into specific lipoprotein size classes to further resolve the underlying biochemistry and metabolism of tissues that deliver these lipids to blood and selectively remove them. Thus, TrueMass analysis can be used to measure the lipid profiles of very-low-density lipoprotein, quantify the lipid pathways responsible for metabolic changes in the liver and measure profiles of high-density lipoprotein to quantify the flux of lipids in reverse cholesterol transport. [Pg.39]

The HDL lipids are removed from the circulation by a selective uptake and by an indirect pathway. The selective uptake of cholesterol esters from HDL into he-patocytes and steroidogenic cells is mediated by the binding of HDL to scavenger receptor B1 (SR-BI). This selective uptake by SR-BI may depend on the presence of cofactors such as HL, which hydrolyses phospholipids on the surface of both HDL and plasma membranes and thereby enables the flux of cholesteryl esters from the lipoprotein core into the plasma membrane [42]. The indirect pathway involves the enzyme CETP, which exchanges cholesteryl esters of a-HDL with triglycerides of chylomicrons, VLDL, IDL, and LDL. The a-HDL derived cholesteryl esters are therefore removed via the LDL-receptor pathway. The removal of excess cholesterol from the periphery and the delivery to the liver for excretion in the bile is termed reverse cholesterol transport. [Pg.499]

Eckardstein A von, Huang Y, Wu S, Funke H, Noseda G, Assmann G (1995) Reverse cholesterol transport in plasma of patients with different forms of familial HDL deficiency. Arterioscler Thromb Vase Biol 15 691-703... [Pg.545]

HDL may be taken up in the liver by receptor-mediated endocytosis, but at least some of the cholesterol in HDL is delivered to other tissues by a novel mechanism. HDL can bind to plasma membrane receptor proteins called SR-BI in hepatic and steroidogenic tissues such as the adrenal gland. These receptors mediate not endocytosis but a partial and selective transfer of cholesterol and other lipids in HDL into the cell. Depleted HDL then dissociates to recirculate in the bloodstream and extract more lipids from chylomicron and VLDL remnants. Depleted HDL can also pick up cholesterol stored in extrahepatic tissues and carry it to the liver, in reverse cholesterol transport pathways (Fig. 21-40). In one reverse transport path, interaction of nascent HDL with SR-BI receptors in cholesterol-rich cells triggers passive movement of cholesterol from the cell surface into HDL, which then carries it back to the liver. In a second pathway, apoA-I in depleted HDL in-... [Pg.824]

As mentioned in Chapter 21, there are several related receptors with similar structures. Two of them have a specificity for apolipoprotein E and can accept remnants of VLDL particles and chylomicrons.216 220 The LDL receptor-related protein is a longer-chain receptor.216 221 LDL particles, especially when present in excess or when they contain oxidized lipoproteins, may be taken up by endocytosis into macrophages with the aid of the quite different scavenger receptors.221 225 The uptake of oxidized lipoproteins by these receptors may be a major factor in promoting development of atherosclerosis (Box 22-B). On the other hand, scavenger receptor SR-B1, which is also present in liver cells, was recently identified as the receptor for HDL and essential to the "reverse cholesterol transport" that removes excess cholesterol for excretion in the bile.213/213a... [Pg.1251]


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