Cholesterol esters structure

Although lanosterol may appear similar to cholesterol in structure, another 20 steps are required to convert lanosterol to cholesterol (Figure 25.35). The enzymes responsible for this are all associated with the endoplasmic reticulum. The primary pathway involves 7-dehydroeholesterol as the penultimate intermediate. An alternative pathway, also composed of many steps, produces the intermediate desmosterol. Reduction of the double bond at C-24 yields cholesterol. Cholesterol esters—a principal form of circulating cholesterol—are synthesized by acyl-CoA cholesterol acyltransferases (ACAT) on the cytoplasmic face of the endoplasmic reticulum. 

HDL and VLDL are assembled primarily in the endoplasmic reticulum of the liver (with smaller amounts produced in the intestine), whereas chylomicrons form in the intestine. LDL is not synthesized directly, but is made from VLDL. LDL appears to be the major circulatory complex for cholesterol and cholesterol esters. The primary task of chylomicrons is to transport triacylglycerols. Despite all this, it is extremely important to note that each of these lipoprotein classes contains some of each type of lipid. The relative amounts of HDL and LDL are important in the disposition of cholesterol in the body and in the development of arterial plaques (Figure 25.36). The structures of the various... 

FIGURE 9-1. Lipoprotein structure. Lipoproteins are a diverse group of particles with varying size and density. They contain variable amounts of core cholesterol esters and triglycerides, and have varying numbers and types of surface apolipoproteins. The apolipoproteins function to direct the processing and removal of individual lipoprotein particles. (Reprinted from LipoScience, Inc. with permission.)... 

An old hypothesis is based on the observations of Dahlen et al. (D3), who demonstrated that above a certain concentration in plasma, Lp(a) could bind to glycosaminoglycans in the arterial wall (B12). Colocalization of Lp(a) and fibrin on the arterial wall can lead to oxidative changes in the lipid moiety of Lp(a) and induce the formation of oxidatively modified cholesterol esters, which in turn can influence the interaction of Lp(a) and its receptors on macrophages. This process is promoted by the presence of calcium ions. Cushing (C14), Loscalzo (L22), and Rath (R3) reported a colocalization of undegraded Lp(a) and apo-Bl00 in the extracellular space of the arterial wall. In contrast to LDL, Lp(a) is a substrate for tissue transglutaminase and Factor XUIa and can be altered to products that readily interact with cell surface structures (B21). 

The stratum corneum consists of separated, nonviable, cornified, almost nonpermeable corneocytes embedded into a continuous lipid bilayer made of various classes of lipids, for example, ceramides, cholesterol, cholesterol esters, free fatty acids, and triglycerides [6], Structurally, this epidermis layer is best described by the so-called brick-and-mortar model [7], The stratum corneum is crucial for the barrier function of the skin, controlling percutaneous absorption of dermally applied substances and regulating fluid homeostasis. The thickness of the stratum corneum is usually 10-25 /an, with exceptions at the soles of the feet and the palms, and swells several-fold when hydrated. All components of the stratum corneum originate from the basal layer of the epidermis, the stratum germinativum. 

Figure 11.15 The reaction catalysed by lecithin cholesterol acyltransferase (LCAT). LinoLeate is transferred from a phospholipid in the blood to cholesterol to form cholesteryl linoleate, catalysed by LCAT. The cholesterol ester forms the core of HDL, which transfers cholesterol to the liver. Discoidal HDL (i.e. HDL3) is secreted by the liver and collects cholesterol from the peripheral tissues, especially endothellial cells (see Figure 22.10). Cholesterol is then esterified with lin-oleic acid and HDL changes its structure (HDL2) to a more stable form as shown in the lower part of the figure. R is linoleate.

The general structure of lipoproteins is shown schematically in Figure 3. The core of the lipoprotein contains the more hydrophobic lipids namely cholesterol ester (CE) and triglyceride (TG) and is surrounded by a surface monolayer consisting of the more polar phospholipid (PL) and free cholesterol (FC). Apoproteins are associated with the lipoprotein surface. The proportional composition of human plasma lipoproteins is given in Table 7. 

The principal routes of penetration are thus transcellular and intercellular. Currently there is considerable debate as to which of these predominates. Work with esters of nicotinic acid has shown that the intercellular channels are significant [5.] and considerable effort is being conducted to identify their exact nature and role. Microscopic examination shows that they contain structured lipids the chemical nature of which is complex [6J. Cholesterol esters, cerebrosides and sphingomyelins are present in association with other lipids in smaller concentrations. It is likely that the main barrier to skin penetration resides in the channels and that a diffusing drug molecule experiences a lipid environment which has considerable structure. Penetration enhancers may act by temporarily altering the nature of the structured lipids, perhaps by lowering their normal phase transition temperature which occurs around 38°C. 

Lipids (fats) are generally insoluble in water but are soluble in organic solvents. Solubility characteristics depend on structural features those fats that have no polar residues are least water soluble, and they exist away from the aqueous environments of the organism (e.g., cholesterol esters and triglycerides). Others have hydrophilic along with hydrophobic residues. These are called amphipathic substances (also amphiphiles), and they may exist at the interface between aqueous and nonaqueous environments (e.g., phosphoglycerides). 

These proteins are of great interest because of their relationship to coronary heart disease (CHD). Lipoproteins, a group of macromicellar complexes of lipids and proteins, are closely associated with the risk of developing CHD. Structurally, lipoprotein particles contain a nonpolar lipid core of triglycerides and cholesterol esters and a polar surface that is comprised of apolipoproteins and unesterified cholesterol and phospholipids. There are three principle classes of lipoproteins ... 

ACAT transfers amino-acyl groups from one molecule to another. ACAT is an important enzyme in bile acid synthesis, and catalyses the intracellular esterification of cholesterol and formation of cholesteryl esters. ACAT-mediated esterification of cholesterol limits its solubility in the cell membrane and thus promotes accumulation of cholesterol ester in the fat droplets within the cytoplasm this process is important in preventing the toxic accumulation of free cholesterol that would otherwise damage ceU-membrane structure and function. Most of the cholesterol absorbed during intestinal transport undergoes ACAT-mediated esterification before incorporation into chylomicrons. In the liver, ACAT-mediated esterification of cholesterol is involved in the production and release of apo-B-containing lipoproteins. 

Fats and fat-like compounds of varying chemical structures are classified as lipids. They have a low molecular weight and are insoluble in water. The original substance in fat biosynthesis is acetyl-CoA (so-called activated acetic acid). On the basis of chemical criteria, they may be divided into simple lipids (glycerides, cholesterol, cholesterol esters, bile acids) and complex lipids, (s. tab. 3.7)... 

In liver cirrhosis, there are several changes reduction in LCAT (with cholesterol ester fall ), HDL and LDL as well as in VLDL, with a corresponding change in their distribution pattern occurrence of hypertriglycerid-aemia and atypical lipoproteins reduction in phospholipid synthesis (28), possibly with greatly impaired structure and function of the biomembranes. Hepatic extraction of bile acids is reduced with the result that they reach the peripheral circulation - even in the early stages of cirrhosis - and give rise to increased serum values. Bile acids have cholestatic and cytotoxic effects. When bile acid metabolism is markedly compromised, enteral absorption of fat-soluble vitamins is impeded, so that A, D, E and K hypovitaminoses may be observed. 

The stratum corneum intercellular lipids exist as a continuous lipid phase occupying about 20% of the stratum corneum volume and arranged in multiple lamellar structures. They are composed of cholesterol (27 /o) and ceramides (41 /o), together with free fatty acids (9 /o), cholesteryl esters (10 /o) and cholesteryl sulfate (2 /o) (Table 1). Phospholipids, which dominate in the basal layer, are converted to glucosylceramides and subsequently to ceramides and free fatty acids, and are virtually absent in the outer layers of the stratum corneum. Eight classes of ceramides have been isolated and identified in human stratum corneum but the functions of the individual ceramide types are not fully understood. Similarly, the exact function of cholesterol esters within the stratum corneum lamellae is also elusive but it is theoretically possible that cholesterol esters may span adjacent bilayers and serve as additional stabilizing moieties. 

Cholesterol esters form crystalline structures that are similar to those formed by other lipids, consisting of alternating infinite lamellae, so that the hydrocarbon chains form close-packed sheets segregated from layers of cholesterol skeletons. There are three t) s of such structures [6]. One such can be represented by the chiral molecule cholesterol oleate, where pairs of cholesterol skeletons are arranged in an antiparallel packing in one layer, with the hydrocarbon chains in the adjacent layer. The cross-sectional area of the cholesterol molecule is about 40 A2 (derived from pressure-area monolayer curves), corresponding to the cross-sectional area of two hydrocarbon chains. The chains therefore form an interpenetrating layer. 

The structure of the blue phase is of some importance. Among the lipoproteins carrying lipids in the blood, low-density lipoproteins (LDL) have attracted much attention. They are the factors mainly responsible for plaque formation, which ultimately leads to atheriosclerotic changes and heart disease. The major components of the LDL-particles are cholesterol fatty acid esters. A remarlmble property is the constant size of LDL particles [28], which indicates that the interior must possess some degree of order. It seems probable that the structure proposed above for cholesterol esters in the cholesteric liquid-crystalline structure should occur also in the LDL-particle. In that case the LDL particle can be viewed as a dispersed blue phase, whose size is related to the periodicity of the liquid-crystalline phase, and the protein coat at the surface is oriented parallel to adjacent specific crystallographic planes of the blue phase. These amphiphilic proteins will expose lipophilic segments inwards emd expose hydrophilic groups towards tiie enviroiunent. 

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