Core modification of human low-density lipoprotein by artificial triacylglycerol emulsion

To determine whether an apolipoprotein-free artificial triacylglycerol emulsion can substitute for VLDL in studying cholesterol ester-triacylglycerol exchange processes between triacylglycerol-rich lipoproteins and cholesterol ester-rich lipoproteins, we used Intralipid to modify human plasma LDL. Intralipid was incubated with LDL in the presence of lipoprotein-poor plasma (d greater than 1.21 g/ml) at 37 degrees C. Intralipid served as an acceptor for cholesterol ester and as a donor of triacylglycerol, modifying the low-density lipoproteins so that triacylglycerol became the major core lipid in the particle - the contribution of cholesterol ester to LDL mass decreased from 38% to 18%, while that of triacylglycerol increased from 4.9% to 26%. On lipolysis most added LDL triacylglycerol (59-72%) was hydrolyzed, resulting in a smaller particle than the "native' LDL particle with net loss of cholesterol ester. Incubation of LDL with the original Intralipid emulsion resulted in modified LDL with a high relative weight of phospholipid (27.7%). On removal of excess phospholipid from Intralipid and incubation of the resultant "washed' Intralipid with LDL, the relative weight of phospholipid in modified LDL decreased to 20%, which was similar to that observed after incubation of LDL with VLDL. We demonstrate that artificial triacylglycerol emulsion can indeed substitute for VLDL in neutral lipid exchange processes, and further confirm that transfer of core cholesterol ester and triacylglycerol occurs independently of the apolipoproteins present in triacylglycerol-rich lipoproteins and LDL.     

Increases in the particle size of high-density lipoproteins induced by purified lecithin: cholesterol acyltransferase: effect of low-density lipoproteins

Homogeneous subpopulations of human high-density lipoproteins subfraction-3 (HDL3) have been incubated at 37 degrees C with purified lecithin: cholesterol acyltransferase, human serum albumin and varying concentrations of human low-density lipoproteins (LDL). Changes in HDL particle size and composition during these incubations were monitored. Incubation of HDL3a (particle radius 4.3 nm) in the absence of LDL resulted in an esterification of more than 70% of the HDL free cholesterol after 24 h of incubation. This, however, was sufficient to increase the HDL cholesteryl ester by less than 10% and was not accompanied by any change in particle size. When this mixture was incubated in the presence of progressively increasing concentrations of LDL, which donated free cholesterol to the HDL, the molar rate of production of cholesteryl ester was much greater; at the highest LDL concentration HDL cholesteryl ester content was almost doubled after 24 h and there was an increase in the HDL particle size up to the HDL2 range. In the case of HDL3b (radius 3.9 nm), there were again only minimal changes in particle size in incubations not containing LDL. In the presence of the highest concentration of LDL tested, however, the particles were again enlarged into the HDL2 size range after 24 h incubation. These HDL2-like particles were markedly enriched with cholesteryl ester but depleted of phospholipid and free cholesterol when compared with native HDL2. Furthermore, the ratio of apolipoprotein A-I to apolipoprotein A-II resembled that in the parent-HDL3 and was very much lower than that in native HDL2. It has been concluded that purified lecithin: cholesterol acyltransferase is capable of increasing the size of HDL3 towards that of HDL2 but that other factors must operate in vivo to modulate the chemical composition of the enlarged particles.     

Very low and low density lipoprotein synthesis and secretion by the human hepatoma cell line Hep-G2: effects of free fatty acid

The liver is a major source of the plasma lipoproteins; however, direct studies of the regulation of lipoprotein synthesis and secretion by human liver are lacking. Dense monolayers of Hep-G2 cells incorporated radiolabeled precursors into protein ([35S]methionine), cholesterol ([3H]mevalonate and [14C]acetate), triacylglycerol, and phospholipid ([3H]glycerol), and secreted them as lipoproteins. In the absence of free fatty acid in the media, the principal lipoprotein secretory product that accumulated had a density maximum of 1.039 g/ml, similar to serum low density lipoprotein (LDL). ApoB-100 represented greater than 95% of the radiolabeled apoprotein of these particles, with only traces of apoproteins A and E present. Inclusion of 0.8 mM oleic acid in the media resulted in a 54% reduction in radiolabeled triacylglycerol in the LDL fraction and a 324% increase in triacylglycerol in the very low density lipoprotein (VLDL) fraction. Similar changes occurred in the secretion of newly synthesized apoB-100. The VLDL contained apoB-100 as well as apoE. In the absence of exogenous free fatty acid, the radiolabeled cholesterol was recovered in both the LDL and the high density lipoprotein (HDL) regions. Oleic acid caused a 50% decrease in HDL radiolabeled cholesterol and increases of radiolabeled cholesterol in VLDL and LDL. In general, less than 15% of the radiolabeled cholesterol was esterified, despite the presence of cholesteryl ester in the cell. Incubation with oleic acid did not cause an increase in the total amount of radiolabeled lipid or protein secreted. We conclude that human liver-derived cells can secrete distinct VLDL and LDL-like particles, and the relative amounts of these lipoproteins are determined, at least in part, by the availability of free fatty acid.     

Effect of lecithin:cholesterol acyltransferase on distribution of apolipoprotein A-IV among lipoproteins of human plasma

The effect of cholesterol esterification on the distribution of apoA-IV in human plasma was investigated. Human plasma was incubated in the presence or absence of the lecithin:cholesterol acyltransferase (LCAT) inhibitor 5,5-dithiobis(2-nitrobenzoic acid) (DTNB) and immediately fractionated by 6% agarose column chromatography. Fractions were monitored for apoA-IV, apoE, and apoA-I by radioimmunoassay (RIA). Incubation resulted in an elevated plasma concentration of cholesteryl ester and in an altered distribution of apoA-IV. After incubation apoA-IV eluted in the ordinarily apoA-IV-poor fractions of plasma that contain small VLDL particles, LDL, and HDL2. Inclusion of DTNB during the incubation resulted in some enlargement of HDL; however, both cholesterol esterification and lipoprotein binding of apoA-IV were inhibited. Addition of DTNB to plasma after incubation and prior to gel filtration had no effect on the apoA-IV distribution when the lipoproteins were immediately fractionated. Fasting plasma apoE was distributed in two or three peaks; in some plasmas there was a small peak that eluted with the column void volume, and, in all plasmas, there were larger peaks that eluted with the VLDL-LDL region and HDL2. Incubation resulted in displacement of HDL apoE to larger lipoproteins and this effect was observed in the presence or absence of DTNB. ApoA-I was distributed in a single broad peak that eluted in the region of HDL and the gel-filtered distribution was unaffected by incubation either in the presence or absence of DTNB. Incubation of plasma that was previously heated to 56 degrees C to inactivate LCAT resulted in no additional movement of apoA-IV onto lipoproteins, unless purified LCAT was present during incubation. The addition of heat-inactivated LCAT to the incubation, had no effect on movement of apoA-IV. These data suggest that human apoA-IV redistribution from the lipoprotein-free fraction to lipoprotein particles appears to be dependent on LCAT action. The mechanism responsible for the increased binding of apoA-IV to the surface of lipoproteins when LCAT acts may involve the generation of "gaps" in the lipoprotein surface due to the consumption of substrate from the surface and additional enlargement of the core. ApoA-IV may bind to these "gaps," where the packing density of the phospholipid head groups is reduced.     

In vitro incorporation of radiolabeled cholesteryl esters into high and low density lipoproteins

We have developed and validated a method for in vitro incorporation of radiolabeled cholesteryl esters into low density (LDL) and high density lipoproteins (HDL). Radiolabeled cholesteryl esters dissolved in absolute ethanol were mixed with LDL or HDL in the presence of lipoprotein-deficient serum (LPDS) as a source of core lipid transfer activity. The efficiency of incorporation was dependent on: a) the core lipid transfer activity and quantity of LPDS, b) the mass of added radiolabeled cholesteryl esters, c) the length of incubation, and d) the amount of acceptor lipoprotein cholesterol. The tracer incorporation was documented by repeat density gradient ultracentrifugation, agarose gel electrophoresis, and precipitation with heparin-MnCl2. The radiolabeling conditions did not affect the following properties of the lipoproteins: 1) chemical composition, 2) electrophoretic mobility on agarose gels, 3) hydrated density, 4) distribution of apoproteins on SDS gels, 5) plasma clearance rates, and 6) immunoprecipitability of HDL apoproteins A-I and A-II. Rat HDL containing radiolabeled cholesteryl esters incorporated in vitro had plasma disappearance rates identical to HDL radiolabeled in vivo.     

Interaction between hepatic microsomal membrane lipids and apolipoprotein A-I

Incubation of apoprotein A-I (apo-A-I), the major protein component of human high density lipoprotein, with rat liver microsomal membranes under conditions of elevated pH and ionic strength leads to the production of a soluble protein:lipid complex (A-I/MM complex). The A-I/MM complex, as purified by density gradient centrifugation and agarose column chromatography, possesses a lipid composition similar to the hepatic microsomal membrane and a protein/lipid ratio similar to that of plasma high density lipoproteins, but markedly different from that of recombinant particles prepared with synthetic lipids. The A-I/MM complex constitutes a more physiological recombinant particle than can be formed using synthetic lipids and may be a suitable model for the newly assembled intracellular high density lipoproteins. Incubation of the erythrocyte plasma membranes with apo-A-I under the same conditions as used with microsomal membranes fails to generate any lipid:apoprotein complexes. This membrane specificity for forming soluble lipoprotein complexes suggests that the microsomal membranes possess a unique feature, possibly their lipid composition, which render them particularly suitable to serve as lipid donors to the apoproteins which are undergoing assembly within the endoplasmic reticulum/Golgi organelles.     

Lipoprotein B37, a naturally occurring lipoprotein containing the amino-terminal portion of apolipoprotein B100, does not bind to the apolipoprotein B,E (low density lipoprotein) receptor

In 1979, Steinberg and colleagues described a unique kindred with familial hypobetalipoproteinemia (Steinberg, D., Grundy, S. M., Mok, H. Y. I., Turner, J. D., Weinstein, D. B., Brown, W. V., and Albers, J. J. (1979) J. Clin. Invest. 64, 292-301). Recently, we demonstrated the existence of an abnormal species of apolipoprotein (apo-) B, apo-B37 (Mr = 203,000) in nine members of that kindred (Young, S. G., Bertics, S. J., Curtiss, L. K., and Witztum, J. L. (1987) J. Clin. Invest. 79, 1831-1841; Young, S. G., Bertics, S. J., Curtiss, L. K., Dubois, B. W., and Witztum, J. L. (1987) J. Clin. Invest. 79, 1842-1851). Apolipoprotein B37 contains only the amino-terminal portion of apo-B100. In affected individuals most of the apo-B37 is contained in the high density lipoprotein (HDL) fraction (d = 1.063-1.21 g/ml), where it is the principal apolipoprotein in a unique lipoprotein (Lp) particle, Lp-B37, which contains little, if any, apo-A-I. However, the most abundant lipoprotein in the HDL density fraction is a smaller particle, which contains apo-A-I, but no apo-B. The Lp-B37 particles were isolated from the HDL of affected individuals by immunoabsorption of apo-B37. Selected affinity antibodies specific for apo-B37 were used to prepare an anti-apo-B37-Sepharose 4B column. Lipoproteins not bound by the column (unbound HDL fraction) contained apo-A-I, but no apo-B. The Lp-B37, which was eluted from the column with 3 M KI, contained apo-B37 and trace amounts of apo-A-I, but no apo-B100. Over a 4-h period, normal human fibroblasts degraded 10-fold more 125I-low density lipoprotein (LDL) than 125I-Lp-B37. Also, whereas addition of excess unlabeled LDL markedly reduced degradation of 125I-LDL, it did not significantly reduce the degradation of 125I-Lp-B37. Unlabeled Lp-B37 did not inhibit uptake and degradation of 125I-LDL by fibroblasts. These data suggest that the amino-terminal portion of apo-B100, when expressed on a naturally occurring lipoprotein particle, does not contain a functional apo-B,E(LDL) receptor binding domain.     

Hydrolysis of cholesteryl ester in low density lipoprotein converts this lipoprotein to a liposome.

Previously, we isolated and characterized unique liposomal-like, cholesterol-rich lipid particles that accumulate in human atherosclerotic lesions. Human plasma low density lipoprotein (LDL) has a molar ratio of total cholesterol to phospholipid (3:1) similar to that of this lesion cholesterol-rich lipid particle. However, LDL is enriched in cholesteryl ester while the lesion lipid particle is enriched in unesterified cholesterol. To examine a possible precursor-product relationship between LDL and the lesion lipid particle, we hydrolyzed the cholesteryl ester core of LDL with cholesterol esterase. Cholesteryl ester hydrolysis occurred only after LDL was treated with trypsin. Trypsin pretreatment was not required for cholesteryl ester hydrolysis of LDL oxidized with copper, a treatment that also degrades apolipoprotein B, the major protein moiety in LDL. In contrast to greater than 90% hydrolysis of cholesteryl ester in trypsin-cholesterol esterase-treated or copper-oxidized LDL, there was only 18% hydrolysis of cholesteryl ester in similarly treated high density lipoprotein. With a limited 10-min hydrolysis of LDL cholesteryl ester, LDL-sized particles and newly formed larger flattened films or discs were present. With complete hydrolysis of LDL cholesteryl ester, LDL particles converted to complex multilamellar, liposomal-like, structures with sizes approximately five times larger than native LDL. These liposomal-like particles derived from LDL were chemically and structurally similar to unesterified cholesterol-rich lipid particles that accumulate in atherosclerotic lesions.     

Synthetic high density lipoprotein particles. Application to studies of the apoprotein specificity for selective uptake of cholesterol esters

Particles closely resembling rat high density lipoproteins (HDL) in terms of equilibrium density profile and particle size were prepared by sonication of apoA-I with a microemulsion made with egg lecithin and cholesterol oleate. These particles, like authentic HDL, allowed selective uptake of their cholesterol ester moieties by cultured cells without parallel uptake of the particle itself. That uptake was saturable and competed by HDL. In rats, the plasma decay kinetics and sites of uptake of a cholesteryl ether tracer were similar whether that tracer was incorporated into synthetic or authentic HDL. Synthetic particles containing other apoproteins were made by generally the same method, but using in place of apoA-I either a mixture of rat apoCs or apoE that was either competent or reductively methylated to prevent interaction with the B/E receptor. These particles, of lower density and larger Stokes radius than those made with apoA-I, also allowed selective uptake of cholesterol esters, albeit with a lower degree of selectivity than in the case of apoA-I. Thus a specific apoprotein component in the subject lipoprotein particle is not required for selective uptake. However, selective uptake was shown to be a function of particle density or size, and part of the difference in rates of selective uptake from the particles made with various apoproteins was explained by their differences in density or size.     

Activation of lecithin: cholesterol acyltransferase by human apolipoprotein A-IV

Human plasma apoproteins (apo) A-I and A-IV both activate the enzyme lecithin:cholesterol acyltransferase (EC 2.3.1.43). Lecithin:cholesterol acyltransferase activity was measured by the conversion of [4-14C] cholesterol to [4-14C]cholesteryl ester using artificial phospholipid/cholesterol/[4-14C]cholesterol/apoprotein substrates. The substrate was prepared by the addition of apoprotein to a sonicated aqueous dispersion of phospholipid/cholesterol/[4-14C]cholesterol. The activation of lecithin:cholesterol acyltransferase by apo-A-I and -A-IV differed, depending upon the nature of the hydrocarbon chains of the sn-L-alpha-phosphatidylcholine acyl donor. Apo-A-I was a more potent activator than apo-A-IV with egg yolk lecithin, L-alpha-dioleoylphosphatidylcholine, and L-alpha-phosphatidylcholine substituted with one saturated and one unsaturated fatty acid regardless of the substitution position. When L-alpha-phosphatidylcholine esterified with two saturated fatty acids was used as acyl donor, apo-A-IV was more active than apo-A-I in stimulating the lecithin:cholesterol acyltransferase reaction. Complexes of phosphatidylcholines substituted with two saturated fatty acids served as substrate for lecithin:cholesterol acyltransferase even in the absence of any activator protein. Essentially the same results were obtained when substrate complexes (phospholipid-cholesterol-[4-14C]cholesterol-apoprotein) were prepared by a detergent dialysis procedure. Apo-A-IV-L-alpha-dimyristoylphosphatidylcholine complexes thus prepared were shown to be homogeneous particles by column chromatography and density gradient ultracentrifugation. It is concluded that apo-A-IV is able to facilitate the lecithin:cholesterol acyltransferase reaction in vitro.     

Conversion of human low density lipoprotein into a very low density lipoprotein-like particle in vitro.

The lipid substrate specificity of Manduca sexta lipid transfer particle (LTP) was examined in in vitro lipid transfer assays employing high density lipophorin and human low density lipoprotein (LDL) as donor/acceptor substrates. Unesterified cholesterol was found to exchange spontaneously between these substrate lipoproteins, and the extent of transfer/exchange was not affected by LTP. By contrast, transfer of labeled phosphatidylcholine and cholesteryl ester was dependent on LTP in a concentration-dependent manner. Facilitated phosphatidylcholine transfer occurred at a faster rate than facilitated cholesteryl ester transfer; this observation suggests that either LTP may have an inherent preference for polar lipids or the accessibility of specific lipids in the donor substrate particle influences their rate of transfer. The capacity of LDL to accept exogenous lipid from lipophorin was investigated by increasing the high density lipophorin:LDL ratio in transfer assays. At a 3:1 (protein) ratio in the presence of LTP, LDL became turbid (and aggregated LDL were observed by electron microscopy) indicating LDL has a finite capacity to accept exogenous lipid while maintaining an overall stable structure. When either isolated human non B very low density lipoprotein (VLDL) apoproteins or insect apolipophorin III (apoLp-III) were included in transfer experiments, the sample did not become turbid although lipid transfer proceeded to the same extent as in the absence of added apolipoprotein. The reduction in sample turbidity caused by exogenous apolipoprotein occurred in a concentration-dependent manner, suggesting that these proteins associate with the surface of LDL and stabilize the increment of lipid/water interface created by LTP-mediated net lipid transfer. The association of apolipoprotein with the surface of modified LDL was confirmed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis, and scanning densitometry revealed that apoLp-III bound to the surface of LDL in a 1:14 apoB:apoLp-III molar ratio. Electron microscopy showed that apoLp-III-stabilized modified LDL particles have a larger diameter (29.2 +/- 2.6 nm) than that of control LDL (22.7 +/- 1.9 nm), consistent with the observed changes in particle density, lipid, and apolipoprotein content. Thus LTP-catalyzed vectorial lipid transfer can be used to introduce significant modifications into isolated LDL particles and provides a novel mechanism whereby VLDL-LDL interrelationships can be studied.     

Affinity of lipid transfer protein for lipid and lipoprotein particles as influenced by lecithin-cholesterol acyltransferase

The effects of lecithin-cholesterol acyltransferase (LCAT) on the transfer of cholesterol esters mediated by lipid transfer protein (LTP) and its affinity for lipid and lipoprotein particles were investigated. When the single bilayer vesicle preparations (containing phosphatidylcholine, cholesterol, cholesteryl ester, and apolipoprotein- (apo) A-I at the molar ratio of 90:30:1.2:0.18) or high density lipoprotein 3 (HDL3) were used as the cholesteryl ester donor and low density lipoproteins (LDL) as the acceptor, the transfer activity of LTP was enhanced by the addition of low concentrations of LCAT. In contrast, no enhancement of cholesteryl ester transfer was observed upon addition of LCAT to either the discoidal bilayer particle preparations (containing phosphatidylcholine, cholesterol, cholesteryl ester, and apo-A-I at the molar ratio of 90:30:1.2:1.0) or high density lipoprotein 2 (HDL2). Although both apo-A-I and apo-A-II promoted the transfer of cholesteryl ester from vesicles to LDL, the additional enhancement of the transfer by LCAT was observed only with the vesicles containing apo-A-I. Gel permeation chromatography of LTP/vesicle and LTP/HDL3 mixtures in the presence and absence of LCAT showed that the affinity of LTP for both the vesicles and HDL3 increased upon addition of LCAT. In contrast, neither HDL2 nor discoidal bilayer particles showed any significant enhancement of LTP binding upon addition of LCAT. By using LCAT covalently bound to Sepharose 4B, a maximal interaction between LTP and bound LCAT was shown to occur at the ionic strength of 0.16. Deviation from this ionic strength reduced the extent of the interaction. At the ionic strength of 0.01 and 0.5, the elution volume of LTP was identical to that of bovine serum albumin.     

Size transformations of intermediate and low density lipoproteins induced by unesterified fatty acids

Plasma from individual human subjects is known to contain multiple discrete subpopulations of low (LDL) and intermediate (IDL) density lipoproteins that differ in particle size and density. The metabolic origins of these subpopulations are unknown. Transformation of IDL and larger LDL to smaller, denser LDL particles had been postulated to occur as a result of the combined effects of triglyceride hydrolysis and lipid transfer. However, the presence of multiple small LDL subspecies has been described in patients lacking cholesteryl ester transfer protein. We have characterized an alternative pathway in which size decrements in IDL or LDL are produced in the presence of unesterified fatty acids and a source of apolipoprotein (apo) A-I. Incubation of IDL or LDL subfractions with palmitic acid and either high density lipoproteins (HDL), apoHDL, or purified apoA-I gives rise to apoA-I, apoB-containing complexes that can dissociate into two particles, an apoB-containing lipoprotein with particle diameter 10-30 A smaller than the starting material, and a still smaller species (apparent peak particle diameter 140-190 A) containing lipid and apoA-I but no apoB. The newly formed IDL or LDL are depleted in phospholipid and free cholesterol with no change in apoB-100 as assessed by SDS gel electrophoresis. We hypothesize that this reaction may contribute to the formation of discrete IDL and LDL subpopulations of varying size during the course of hydrolysis of triglyceride-rich lipoproteins in plasma.     

Human low density lipoprotein subfractions separated by gradient gel electrophoresis: composition, distribution, and alterations induced by cholesteryl ester transfer protein

Low density lipoprotein (LDL) subfractions were studied in sera from 208 normolipidemic, 22 hypercholesterolemic, and 33 hypertriglyceridemic subjects. Whole serum without preliminary ultracentrifugation was submitted to electrophoresis in a nondenaturing polyacrylamide gel. Three main LDL patterns were observed in normolipidemic sera: type 1, characterized by the presence of only one major band; type 2, characterized by the presence of two close major bands; and type 3, where LDL were more dispersed and presented at least three distinct bands. Type 1 was more frequent in men (43%) than in women (19%). The tendency for a higher potential coronary disease risk profile sera, namely higher triglyceride level, higher very low density lipoprotein + LDL fraction and lower high density lipoprotein (HDL) fraction, was type 3 less than type 2 less than type 1. The LDL patterns found in hypercholesterolemic sera were of type 1. Hypertriglyceridemic sera were characterized by the presence of a major band of small size. Separated LDL subfractions were collected by electroelution and analyzed for composition. In all subspecies, the mass ratio of core to surface components was constant as well as the molar ratio of the two lipid surface components, phospholipids and free cholesterol. Surface lipid to apolipoprotein B ratio, cholesteryl ester to triglyceride ratio, and cholesteryl ester to apoB ratio increased with particle size increment. Incubation of LDL with HDL and purified cholesteryl ester transfer protein induced a transfer of lipids, mainly cholesteryl esters and phospholipids, to LDL and an increase of the sizes of LDL subfractions. This suggests that lipid transfers from HDL to LDL might be a process of intravascular LDL remodeling and a factor of LDL polymorphism.     

Effect of fish oil versus lard diets on the chemical and physical properties of low density lipoproteins of nonhuman primates

Twenty-four adult male African green grivet monkeys were fed diets containing 42% of calories as lard or menhaden oil and 0.76 mg of cholesterol/kcal for a period of 8 months. Plasma samples from fasting animals were then taken and low density lipoproteins (LDL) were isolated by ultracentrifugation and agarose column chromatography. The LDL were analyzed chemically, and physical properties of the particles were studied by differential scanning calorimetry. The fish oil group had significantly smaller LDL (2.91 vs. 3.43 g/mumol), which contained fewer molecules per particle of all lipid constituents, except triglyceride, compared to the lard-fed animals. The fish oil-fed group had 15% of the total cholesteryl esters as n-3 fatty acyl species and the number of n-3, but not n-6, cholesteryl esters per LDL particle was proportional to LDL size. The numbers of saturated and monounsaturated cholesteryl ester species per LDL particle were highly correlated with LDL size for both diet groups. The LDL of the fish oil group had broad reversible thermotropic transitions that were 12-13 degrees C lower than those of the lard group. These transitions were indicative of order-disorder transitions of the LDL core cholesteryl esters. The peak transition temperature of LDL of the lard group was proportional to the ratio of saturated and monounsaturated to polyunsaturated cholesteryl ester species (CEFA ratio). However, the much lower peak transition temperature of the LDL of the fish oil group was not related to the CEFA ratio nor to the triglyceride content of the particles, but rather, to the n-3 cholesteryl ester content of the particles. Studies of cholesteryl ester model systems demonstrated that relatively small amounts of n-3 cholesteryl esters (less than 15% of total cholesteryl ester) could result in a lowering of the peak transition temperature of cholesteryl linoleate similar to that seen for intact LDL. We conclude that n-3 cholesteryl esters in small quantities have a marked disordering effect on the core cholesteryl esters of LDL, resulting in a striking depression of LDL transition temperature. In addition, we conclude that n-3 cholesteryl esters are preferentially utilized relative to n-6 cholesteryl esters to increase the number of cholesteryl esters per LDL particle with LDL enlargement in fish oil-fed animals.     

Enhancing the contrast of ApoB to locate the surface components in the 3D density map of human LDL

A 26 Å resolution map of the structure of human low-density lipoprotein (LDL) was obtained from electron cryomicroscopy and single-particle image reconstruction. The structure showed a discoidal-shaped LDL particle with high-density regions mainly distributed at the edge of the particle and low-density regions at the flat surface that covers the core region. To determine the chemical components that correspond to these density regions and to delineate the distribution of protein and phospholipid located at the particle surface at the resolution of the map, we used Mono-Sulfo-NHS-Undecagold labeling to increase preferentially the contrast of the apolipoprotein B component on the LDL particle. In the three-dimensional map from the image reconstruction of the undecagold-labeled LDL particles, the high-density region from the undecagold label was distributed mainly at the edge of the particle, and lower density regions were found at the flat surfaces that cover the neutral lipid core. This suggests that apolipoprotein B mainly encircles LDL at the edge of the particle and the phospholipid monolayers are located at the flat surfaces, which are parallel to the cholesterol ester layers in the core and may interact with the core lipid layers through the acyl chains.     

Cellular free cholesterol in Hep G2 cells is only partially available for down-regulation of low-density-lipoprotein receptor activity.

We have previously shown that in Hep G2 cells and human hepatocytes, as compared with fibroblasts, the low-density lipoprotein (LDL) receptor activity is only weakly down-regulated after incubation of the cells with LDL, whereas incubation with high-density lipoproteins (HDL) of density 1.16-1.20 g/ml (heavy HDL) strongly increased the LDL-receptor activity. To elucidate this difference between hepatocytes and fibroblasts, we studied the cellular cholesterol homoeostasis in relation to the LDL-receptor activity in Hep G2 cells. (1) Interrupting the cholesteryl ester cycle by inhibiting acyl-CoA: cholesterol acyltransferase (ACAT) activity with compound 58-035 (Sandoz) resulted in an enhanced LDL-mediated down-regulation of the receptor activity. (2) The stimulation of the receptor activity by incubation of the cells with cholesterol acceptors such as heavy HDL was not affected by ACAT inhibition. (3) Incubation of the Hep G2 cells with LDL, heavy HDL or a combination of both grossly affected LDL-receptor activity, but did not significantly change the intracellular content of free cholesterol, suggesting that in Hep G2 cells the regulatory free cholesterol pool is small as compared with the total free cholesterol mass. (4) We used changes in ACAT activity as a sensitive (indirect) measure for changes in the regulatory free cholesterol pool. (5) Incubation of the cells with compactin (2 microM) without lipoproteins resulted in a 4-fold decrease in ACAT activity, indicating that endogenously synthesized cholesterol is directed to the ACAT-substrate pool. (6) Incubation of the cells with LDL or a combination of LDL and heavy HDL stimulated ACAT activity 3-5 fold, whereas incubation with heavy HDL alone decreased ACAT activity more than 20-fold. Our results suggest that in Hep G2 cells exogenously delivered (LDL)-cholesterol and endogenously synthesized cholesterol are primarily directed to the cholesteryl ester (ACAT-substrate) pool or, if present, to extracellular cholesterol acceptors (heavy HDL) rather than to the free cholesterol pool involved in LDL-receptor regulation.     

Characterization of subfractions of triglyceride-rich lipoproteins separated by gel chromatography from blood plasma of normolipemic and hyperlipemic humans

As judged from measurements of the diameters of particles fixed with osmium tetroxide and shadowed with platinum, gel chromatography on 2% agarose has been shown to be an effective quantitative method for separating triglyceride-rich lipoproteins according to particle size. Particles in the size range of chylomicrons, uncontaminated by lipoproteins smaller than about 700 A or by other serum proteins, emerged in the void volume of the column, and very low density lipoproteins with diameters between 400 and 700 A were separated into fractions with average standard deviation of 71 A from the mean. Systematic comparison of the relationship between diameter and chemical composition of fractions obtained from subjects with various hyperlipoproteinemic disorders demonstrated a precise correlation consistent with a spherical model for these lipoproteins in which phospholipids, free cholesterol, and protein occupy a surface monolayer with an invariant thickness of 21.5 A surrounding a liquid core of triglycerides and cholesteryl esters. The chemical composition of very low density lipoproteins of given particle size in most recognized types of hyperlipemia was similar to that of normolipemic subjects, but particles in the size range of chylomicrons sometimes had higher contents of cholesteryl esters and free cholesterol. Results obtained in subjects with dysbetalipoproteinemia were consistent with the presence of three populations of particles. Two of these, with mean diameters of about 850 and 350 A, had unusually high cholesteryl ester content and reduced triglyceride content and may represent "remnants" of the metabolism of structurally normal chylomicrons and very low density lipoproteins, respectively. The third, a heterogeneous group with intermediate range of particle size and pre-beta mobility, may represent a population of very low density lipoproteins with relatively normal composition.     

Packing of cholesterol molecules in human low-density lipoprotein

High-resolution, proton-decoupled 13C nuclear magnetic resonance spectra (90.55 MHz) of human low-density lipoprotein (LDL) have been employed to investigate the physical state of unesterified cholesterol molecules in this particle. Approximately half of the cholesterol molecules in LDL were replaced with [4-13C]cholesterol by exchange from Celite. About two-thirds of the cholesterol molecules contribute to a resonance at delta 41.8 from the C-4 atom. This signal is assigned to cholesterol molecules located at the surface of the LDL particle in a mixed monolayer with phospholipid molecules; the spin-lattice relaxation of the C-4 nucleus of such cholesterol molecules is enhanced by the presence of Mn2+ ions in the aqueous phase. The remaining one-third of the cholesterol molecules are apparently neither associated with phospholipid nor exposed to the aqueous phase; these cholesterol molecules are presumed to be located in the core of the particle. Cholesterol molecules in the two microenvironments are in slow exchange on the NMR time scale but in fast exchange on a biological time scale, so that the cholesterol molecules in LDL behave physiologically as one pool. There is a loss of about 20% of the intensity of the N(CH3)3 resonance from phosphatidylcholine and sphingomyelin molecules in the LDL spectrum; this is attributed to the presence of apolipoprotein B in the surface of LDL particles, which may immobilize some of the phospholipid polar groups. Spin-lattice relaxation time measurements suggest that the fast axial motions of cholesterol molecules in the surface of LDL are the same as in high-density lipoprotein (HDL).(ABSTRACT TRUNCATED AT 250 WORDS)     

Serum amyloid A-containing human high density lipoprotein 3. Density, size, and apolipoprotein composition

Serum amyloid A protein (apo-SAA), an acute phase reactant, is an apolipoprotein of high density lipoproteins (HDL), in particular the denser subpopulation HDL3. The structure of HDL3 isolated from humans affected by a variety of severe disease states was investigated with respect to density, size, and apolipoprotein composition, using density gradient ultracentrifugation, gradient gel electrophoresis, gel filtration, and solid phase immunoadsorption. Apo-SAA was present in HDL particles in increasing amounts as particle density increased. Apo-SAA-containing HDL3 had bigger radii than normal HDL3 of comparable density. Purified apo-SAA associated readily with normal HDL3 in vitro, giving rise to particles containing up to 80% of their apoproteins as apo-SAA. The addition of apo-SAA resulted in a displacement of apo-A-I and an increase in particle size. Acute phase HDL3 represented a mixture of particles, polydisperse with respect to apolipoprotein content; for example, some particles were isolated that contained apo-A-I, apo-A-II, and apo-SAA, whereas others contained apo-A-I and apo-SAA but no apo-A-II. We conclude that apo-SAA probably associates in the circulation of acute phase patients with existing HDL particles, causing the remodeling of the HDL shell to yield particles of bigger size and higher density that are relatively depleted of apo-A-I.