Role of lipid transfers in the formation of a subpopulation of small high density lipoproteins

The effect of lipid transfers on the structure and composition of high density lipoproteins (HDL) has been studied in vitro in incubations that contained the lipoprotein-free fraction of human plasma as a source of lipid transfer protein. These incubations did not contain lecithin:cholesterol acyltransferase activity and were not supplemented with lipoprotein lipase. Incubations were performed at 37 degrees C for 6 hr in both the presence and absence of either added very low density lipoproteins (VLDL) or the artificial triglyceride emulsion, Intralipid. Incubation in the absence of added VLDL or Intralipid had little or no effect on the HDL. By contrast, incubation in the presence of either VLDL or Intralipid resulted in marked changes in the HDL. The effect of incubation with VLDL was qualitatively similar to that of Intralipid; both resulted in obvious transfers of lipid and changes in the density, particle size, and composition of HDL. Incubation of the plasma fraction of density 1.006-1.21 g/ml, total HDL, or HDL3 with either VLDL or Intralipid resulted in the following: 1) a depletion of the cholesteryl ester and free cholesterol content and an increase in the triglyceride content of both HDL2 and HDL3; 2) a decrease in density and an increase in particle size of the HDL3 to form a population of HDL2-like particles; and 3) the formation of a discrete population of very small lipoproteins with a density greater than that of the parent HDL3. The newly formed lipoproteins had a mean particle radius of 3.7-3.8 nm and consisted mainly of protein, predominantly apolipoprotein A-I and phospholipid.     

Study of the components of reverse cholesterol transport in lecithin:cholesterol acyltransferase deficiency

Enzymatic and lipid transfer reactions involved in reverse cholesterol transport were studied in healthy and lecithin:cholesterol acyltransferase (LCAT), deficient subjects. Fasting plasma samples obtained from each individual were labeled with [3H]cholesterol and subsequently fractionated by gel chromatography. The radioactivity patterns obtained corresponded to the elution volumes of the three major ultracentrifugally isolated lipoprotein classes (very low density lipoproteins (VLDL), low density lipoproteins (LDL), and high density lipoproteins (HDL)). In healthy subjects, the LCAT activity was consistently found in association with the higher molecular weight portion of HDL. Similar observations were made when exogenous purified LCAT was added to the LCAT-deficient plasma prior to chromatography. Incubation of the plasma samples at 37 degrees C resulted in significant reduction of unesterified cholesterol (FC) and an increase in esterified cholesterol (CE). Comparison of the data of FC and CE mass measurements of the lipoprotein fractions from normal and LCAT-deficient plasma indicates that: (i) In normal plasma, most of the FC for the LCAT reaction originates from LDL even when large amounts of FC are available from VLDL. (ii) The LCAT reaction takes place on the surface of HDL. (iii) The product of the LCAT reaction (CE) may be transferred to either VLDL or LDL although VLDL appears to be the preferred acceptor when present in sufficient amounts. (iv) CE transfer from HDL to lower density lipoproteins is at least partially impaired in LCAT-deficient patients. Additional studies using triglyceride-rich lipoproteins indicated that neither the capacity to accept CE from HDL nor the lower CE transfer activity were responsible for the decreased amount of CE transferred to VLDL and chylomicrons in LCAT-deficient plasma.     

Plasma phospholipid transfer protein enhances transfer and exchange of phospholipids between very low density lipoproteins and high density lipoproteins during lipolysis

In order to determine the effects of a plasma phospholipid transfer protein on the transfer of phospholipids from very low density lipoproteins (VLDL) to high density lipoproteins (HDL) during lipolysis, biosynthetically labeled rat 32P-labeled VLDL was incubated with human HDL3 and bovine milk lipoprotein lipase (LPL) in the presence of the plasma d greater than 1.21 g/ml fraction or a partially purified human plasma phospholipid transfer protein (PTP). The addition of either the PTP or the d greater than 1.21 g/ml fraction resulted in a 2- to 3-fold stimulation of the transfer of phospholipid radioactivity from VLDL into HDL during lipolysis. In the absence of LPL, the PTP caused a less marked stimulation of transfer of phospholipid radioactivity. Both the d greater than 1.21 g/ml fraction and the PTP enhanced the transfer of VLDL phospholipid mass into HDL, but the percentage transfer of phospholipid radioactivity was greater than that of phospholipid mass, suggesting stimulation of both transfer and exchange processes. Stimulation of phospholipid exchange was confirmed in experiments where PTP was found to augment transfer of [14C]phosphatidylcholine radioactivity from HDL to VLDL during lipolysis. In experiments performed with human VLDL and human HDL3, both the d greater than 1.21 g/ml fraction and the PTP were found to stimulate phospholipid mass transfer from VLDL into HDL during lipolysis. Analysis of HDL by non-denaturing polyacrylamide gradient gel electrophoresis showed that enhanced lipid transfer was associated with only a slight increase in particle size, suggesting incorporation of lipid by formation of new HDL particles. In conclusion, the plasma d greater than 1.21 g/ml fraction and a plasma PTP enhance the net transfer of VLDL phospholipids into HDL and also exchange of the phospholipids of VLDL and HDL. Both the transfer and exchange activities of PTP are stimulated by lipolysis.     

Dissociation of high density lipoprotein precursors from apolipoprotein B-containing lipoproteins in the presence of unesterified fatty acids and a source of apolipoprotein A-I

Incubation of low (LDL), intermediate (IDL), or very low density lipoproteins (VLDL) with palmitic acid and either high density lipoproteins (HDL), delipidated HDL, or purified apolipoprotein (apo) A-I resulted in the formation of lipoprotein particles with discoidal structure and mean particle diameters ranging from 146 to 254 A by electron microscopy. Discs produced from IDL or LDL averaged 26% protein, 42% phospholipid, 5% cholesteryl esters, 24% free cholesterol, and 3% triglycerides; preparations derived from VLDL contained up to 21% triglycerides. ApoA-I was the predominant protein present, with smaller amounts of apoA-II. Crosslinking studies of discs derived from LDL or IDL indicated the presence of four apoA-I molecules per particle, while those derived from large VLDL varied more in size and contained as many as six apoA-I molecules per particle. Incubation of discs derived from IDL or LDL with purified lecithin:cholesterol acyltransferase (LCAT), albumin, and a source of free cholesterol produced core-containing particles with size and composition similar to HDL2b. VLDL-derived discs behaved similarly, although the HDL products were somewhat larger and more variable in size. When discs were incubated with plasma d greater than 1.21 g/ml fraction rather than LCAT, core-containing particles in the size range of normal HDL2a and HDL3a were also produced. A variety of other purified free fatty acids were shown to promote disc formation. In addition, some mono and polyunsaturated fatty acids facilitated the formation of smaller, spherical particles in the size range of HDL3c. Both discoidal and small spherical apoA-I-containing lipoproteins were generated when native VLDL was incubated with lipoprotein lipase in the presence of delipidated HDL. We conclude that lipolysis product-mediated dissociation of lipid-apoA-I complexes from VLDL, IDL, or LDL may be a mechanism for formation of HDL subclasses during lipolysis, and that the availability of different lipids may influence the type of HDL-precursors formed by this mechanism.     

Effects of sucrose feeding and injection of lipid transfer protein on rat plasma lipoproteins

Sucrose feeding increased rat plasma very-low-density lipoprotein (VLDL) triacylglycerol concentration and decreased the cholesterol level in high-density lipoprotein (HDL). Gel filtration chromatography cholesterol profiles of both normal-fed and sucrose-fed plasma lipoproteins showed a small peak of VLDL and a large peak of HDL. Injection of a partially purified human lipid transfer protein preparation into normal-fed rats did not alter the concentration of cholesterol in either VLDL or HDL to a great extent, but there was a disappearance of the larger HDL particles. Injection of lipid transfer protein into sucrose-fed rats resulted in an overall 35% reduction in the concentration of HDL cholesterol, a more dramatic loss of larger HDL particles and a slight decrease in the mean particle size of the major HDL population.     

Inhibition of lipid transfer by a unique high density lipoprotein subclass containing an inhibitor protein

We have isolated from human plasma a unique subclass of the high density lipoproteins (HDL) which contains a potent lipid transfer inhibitor protein (LTIP) that inhibited cholesteryl ester, triglyceride, and phospholipid transfer mediated by the lipid transfer protein, LTP-I, and phospholipid transfer mediated by the phospholipid transfer protein, LTP-II. This HDL subclass not only inhibited cholesteryl ester transfer from HDL to LDL or VLDL, but also inhibited cholesteryl ester transfer from HDL to HDL. The inhibitor protein was isolated by sequential chromatography of human whole plasma on dextran sulfate-cellulose, phenyl-Sepharose, and chromatofocusing chromatography. Isolated LTIP had the following characteristics: an apparent molecular weight of 29,000 +/- 1,000, (n = 10) by sodium dodecyl sulfate gel electrophoresis, and an isoelectric point of 4.6 as determined by chromatofocusing. LTIP remained functional following delipidation with organic solvents. Antibody to LTIP was produced, and an immunoaffinity column of the anti-LTIP was prepared. Passage of human, rat, or pig whole plasma over the anti-LTIP column enhanced cholesteryl ester transfer activity in human (17%), pig (200%), and rat plasma (125%). The HDL subclass containing LTIP was isolated from whole human HDL (d 1.063-1.21 g/ml) by immunoaffinity chromatography. The isolated LTIP-HDL complex was shown to: i) contain about 60% protein and 40% lipid, ii) have alpha and pre-beta electrophoretic mobility, iii) have particle size distribution somewhat smaller than whole HDL, about 100,000 daltons, as determined by gradient gel electrophoresis, and iv) contain only a small amount of apoA-I (less than 5%) and a trace amount of apoA-II. Assay of ultracentrifugally obtained lipoprotein fractions revealed that approximately 85% of the total functional LTIP activity was in the d 1.063-1.21 g/ml HDL fraction. Furthermore, immunoblot analysis of whole plasma by nondenaturing gradient gel electrophoresis revealed that LTIP was found predominantly in particles in the size range of HDL. This unique HDL subclass may play an important role in the regulation of plasma lipid transfer and metabolism.     

Plasma lipoproteins in familial combined hyperlipidemia and monogenic familial hypertriglyceridemia

Plasma lipoprotein concentration, composition, and size were evaluated in two common familial forms of hypertriglyceridemia and compared with those in normal subjects. The very low density lipoproteins (VLDL) were triglyceride-enriched in familial hypertriglyceridemia (triglyceride/apoprotein B ratio: 25.7 +/- 8.9) as compared to normal (9.6 +/- 12.2, P < 0.001) or familial combined hyperlipidemia (9.7 +/- 3.3, P < 0.001). The diameter of VLDL was larger in familial hypertriglyceridemia (3.27 +/- 0.28 pm) than in familial combined hyperlipidemia (2.87 +/- 0.16 pm, P < 0.02). Although in familial hypertriglyceridemia VLDL tended to be larger, and in familial combined hyperlipidemia VLDL tended to be smaller than normal (3.08 +/- 0.48 pm), neither of these differences were significant. While VLDL was normally distributed in the control population, the size was skewed to larger particles in familial hypertriglyceridemia with fewer small particles (P < 0.05) and skewed to smaller particles in familial combined hyperlipidemia with fewer large particles (P < 0.05). VLDL was reciprocally related to low density lipoproteins (LDL) in familial combined hyperlipidemia (r = -0.80 to -0.87) suggesting that the concentrations of these individual lipoprotein groups were somehow interrelated. There was no significant relationship between these two lipoprotein classes in familial hypertriglyceridemia or in normals. In familial combined hyperlipidemia, the apoprotein A-I/A-II ratio was below normal (P < 0.01) suggestive of low HDL(2) levels. This change in apoprotein composition was independent of VLDL or LDL concentration. In familial hypertriglyceridemia, high density lipoprotein (HDL) cholesterol was reduced (33% below mean normal) and HDL triglyceride was increased (by 46%), while the concentration of apoA-I and apoA-II was normal. VLDL triglyceride was inversely related to HDL cholesterol in familial hypertriglyceridemia (r = -0.74, P < 0.005), but not in familial combined hyperlipidemia. The large, triglyceride-enriched VLDL observed in familial hypertriglyceridemia is compatible with the reported increase in VLDL triglyceride synthesis seen in this disorder. The increase in VLDL apoprotein B synthesis previously reported in familial combined hyperlipidemia was associated with VLDL of normal composition. The changes in HDL cholesterol in these two disorders might reflect exchange of triglyceride between VLDL and HDL or could be related to transfer of surface components during the catabolism of VLDL. The reciprocal relationship between various components of VLDL and LDL seen in familial combined hyperlipidemia, but not in familial hypertriglyceridemia or in normal subjects, might provide some insight into the pathological abnormalities in these disorders. The differences between these two common familial forms of hypertriglyceridemia provide further support that they are distinct entities.-Brunzell, J. D., J. J. Albers, A. Chait, S. M. Grundy, E. Groszek, and G. B. McDonald. Plasma lipoproteins in familial combined hyperlipidemia and monogenic familial hypertriglyceridemia.     

Lipid transfer inhibitor protein defines the participation of high density lipoprotein subfractions in lipid transfer reactions mediated by cholesterol ester transfer protein (CETP)

Cholesterol ester transfer protein (CETP) moves triglyceride (TG) and cholesteryl ester (CE) between lipoproteins. CETP has no apparent preference for high (HDL) or low (LDL) density lipoprotein as lipid donor to very low density lipoprotein (VLDL), and the preference for HDL observed in plasma is due to suppression of LDL transfers by lipid transfer inhibitor protein (LTIP). Given the heterogeneity of HDL, and a demonstrated ability of HDL subfractions to bind LTIP, we examined whether LTIP might also control CETP-facilitated lipid flux among HDL subfractions. CETP-mediated CE transfers from [3H]CE VLDL to various lipoproteins, combined on an equal phospholipid basis, ranged 2-fold and followed the order: HDL3 > LDL > HDL2. LTIP inhibited VLDL to HDL2 transfer at one-half the rate of VLDL to LDL. In contrast, VLDL to HDL3 transfer was stimulated, resulting in a CETP preference for HDL3 that was 3-fold greater than that for LDL or HDL2. Long-term mass transfer experiments confirmed these findings and further established that the previously observed stimulation of CETP activity on HDL by LTIP is due solely to its stimulation of transfer activity on HDL3. TG enrichment of HDL2, which occurs during the HDL cycle, inhibited CETP activity by approximately 2-fold and LTIP activity was blocked almost completely. This suggests that LTIP keeps lipid transfer activity on HDL2 low and constant regardless of its TG enrichment status. Overall, these results show that LTIP tailors CETP-mediated remodeling of HDL3 and HDL2 particles in subclass-specific ways, strongly implicating LTIP as a regulator of HDL metabolism.     

Mechanisms of enhancement of cholesteryl ester transfer protein activity by lipolysis

Lipoprotein lipase enhances the cholesteryl ester transfer protein (CETP)-mediated transfer of cholesteryl esters from plasma high density lipoproteins (HDL) to very low density lipoproteins (VLDL). In time course studies the stimulation of cholesteryl ester transfer by bovine milk lipase was correlated with accumulation of fatty acids in VLDL remnants. As the amount of fatty acid-poor albumin in the incubations was increased, there was decreased accumulation of fatty acids in VLDL remnants and a parallel decrease in the stimulation of cholesteryl ester transfer by lipolysis. Addition of sodium oleate to VLDL and albumin resulted in stimulation of the CETP-mediated transfer of cholesteryl esters from HDL to VLDL. The stimulation of transfer of cholesteryl esters into previously lipolyzed VLDL was abolished by lowering the pH from 7.5 to 6.0, consistent with a role of lipoprotein ionized fatty acids. CETP-mediated cholesteryl ester transfer from HDL to VLDL was also augmented by phosholipase A2 and by a bacterial lipase which lacked phospholipase activity. When VLDL and HDL were re-isolated after a lipolysis experiment, both lipoproteins stimulated CETP activity. Postlipolysis VLDL and HDL bound much more CETP than native VLDL or HDL. Lipolysis of apoprotein-free phospholipid/triglyceride emulsions also resulted in enhanced binding of CETP to the emulsion particles. Incubation conditions which abolished the enhanced cholesteryl ester transfer into VLDL remnants reduced binding of CETP to remnants, emulsions, and HDL. In conclusion, the enhanced CETP-mediated transfer of cholesteryl esters from HDL to VLDL during lipolysis is related to the accumulation of products of lipolysis, especially fatty acids, in the lipoproteins. Lipids accumulating in VLDL remnants and HDL as a result of lipolysis may augment binding of CETP to these lipoproteins, leading to more efficient transfer of cholesteryl esters from HDL to VLDL.     

Conversion of human plasma high density lipoprotein-2 to high density lipoprotein-3. Roles of neutral lipid exchange and triglyceride lipases

Cholesterol esters accumulating in human plasma high density lipoproteins (HDL) are important in conversion of HDL3 to larger HDL2. We studied whether mechanisms of removal of cholesterol esters from HDL might be important in a reverse direction, i.e. conversion of HDL2 to HDL3. Native HDL2 or HDL3 is incubated with very low density lipoproteins (VLDL) and lipoprotein-poor plasma (d greater than 1.21 g/ml) at 37 degrees C. After incubation, "modified" (M) VLDL, and HDL2 or HDL3 are reisolated by ultracentrifugation. In modified M-HDL2 or M-HDL3, triglyceride becomes the major core lipid as the triglyceride/cholesterol ester weight ratio increases 8-10-fold relative to native HDL. With only small changes in protein/phospholipid ratios in M-HDLs, the large decrease in cholesterol ester/protein ratios suggest net cholesterol ester loss from HDL. Quantitative recovery analyses prove that the cholesterol esters lost from HDL are transferred to M-VLDL, which is now richer in cholesterol ester and poorer in triglyceride. These substantial exchanges of HDL lipids are not associated by significant transfer of HDL apoproteins but are dependent on neutral lipid transfer factors present in human lipoprotein-poor plasma (d greater than 1.21 g/ml). Similar results are obtained when purified core lipid transfer protein replaces d greater than 1.21 g/ml plasma in these incubations. After depletion of cholesterol ester from HDL, most but not all, exchanged triglyceride can be removed by lipolysis with either hepatic or lipoprotein lipase, resulting in a post-lipolysis HDL2 with an increased triglyceride content relative to normal HDL. With successive incubations with VLDL, and core lipid transfer factors, HDL2 loses more than two-thirds of its cholesterol esters. After lipolysis of acquired triglyceride, HDL2 is remodeled, in both composition and flotation parameters, toward HDL3.     

Reactivity of human lipoproteins with purified lecithin: cholesterol acyltransferase during incubations in vitro

Studies have been performed to determine the proportion of the esterified cholesterol in high-density lipoproteins (HDL), low-density lipoproteins (LDL) and very-low-density lipoproteins (VLDL) that is attributable to a direct action of lecithin: cholesterol acyltransferase on each lipoprotein fraction. Esterification of [3H]cholesterol was examined in 37 degrees C incubations of either: (a) unseparated whole plasma, (b) plasma reconstituted after prior ultracentrifugation to separate the 1.21 g/ml supernatant, (c) a mixture comprising the 1.21 g/ml supernatant of plasma and purified lecithin: cholesterol acyltransferase or (d) the same mixture as (c) after supplementation with a preparation of partially purified lipid transfer protein. Each of these incubations was performed using samples collected from four different subjects, two of whom had normal and two of whom had elevated concentrations of plasma triacylglycerol. At the completion of 3-h incubations, the lipoproteins were separated into multiple fractions by gel filtration to obtain a continuous profile of esterified [3H]cholesterol across the whole spectrum of lipoproteins. There was an appearance of esterified [3H]cholesterol in each of the major lipoprotein fractions in all incubations. In unseparated plasma, 56% of the total (mean of four experiments) was in HDL, 33% in LDL and 11% in VLDL. A comparable distribution was observed in the incubations of reconstituted plasma and in the samples to which partially purified lipid transfer protein had been added. In the absence of lipid transfer protein activity in incubations containing purified lecithin: cholesterol acyltransferase, 73% of the esterified [3H]cholesterol was in HDL, 25% in LDL and only 1% in VLDL. It has been concluded that at physiological concentrations of lipoproteins, 70-80% of the cholesterol esterifying action of lecithin: cholesterol acyltransferase is confined to the HDL fraction, with most of the remainder involving the LDL fraction. Of the newly formed esterified cholesterol incorporated into LDL during incubations of unseparated plasma, it was apparent that more than 70% was independent of activity of the lipid transfer protein. Of that incorporated into VLDL in unseparated plasma, in contrast, almost 90% was derived as a transfer from other fractions as a consequence of activity of the lipid transfer protein.     

Triacylglycerol increase in plasma very low density lipoproteins in cyclophosphamide-treated rabbit: relationship with cholesteryl ester transfer activity

We have studied the cholesteryl ester transfer between HDL and VLDL in cyclophosphamide-treated rabbits, in order to explain the abnormal cholesteryl ester partition between these two lipoprotein classes. The hypertriglyceridemia caused by treatment with the drug was associated with cholesteryl ester- and triacylglycerol-rich VLDL and with HDL poor in esterified cholesterol but relatively enriched in triacylglycerol. These two lipoprotein classes were characterized by their chemical composition and by gel filtration chromatography. VLDL particles were slightly larger in size, compared with controls. Different transfer combinations were envisaged between these abnormal lipoproteins and control ones. The transfer study involved the plasma fraction of d greater than 1.21 g/ml containing the cholesteryl ester transfer protein (CETP). It appeared that the chemical composition of lipoproteins was responsible for the level of cholesteryl ester transfer between lipoproteins. Actually, when the cholesteryl ester acceptor lipoproteins (VLDL) were enriched in triacylglycerol, the transfer was enhanced. Therefore, the effect of lipolysis on the transfer has also been explored. Lipoprotein lipase seemed to enhance the transfer of cholesteryl ester from HDL to VLDL when these lipoproteins were normal, but an important decline was obtained when triacylglycerol-rich VLDL were lipolyzed. This study defines the relationship between lipoprotein chemical composition and transfer activity of cholesteryl ester from HDL to VLDL.     

Comparison of two ultracentrifugation procedures for separation of nonhuman primate lipoproteins.

A comparison of nonhuman primate plasma lipoproteins isolated by swinging bucket rotor density gradient or fixed angle rotor differential ultracentrifugation is described. Whereas these two methods produced comparable results for the composition of low density (LDL) and high density (HDL) lipoproteins, the very low density lipoprotein (VLDL) fraction isolated with the swinging-bucket rotor contained relatively more cholesterol (free and esterified) and less phospholipid and protein than that fraction obtained with the fixed-angle rotor. Estimations of lipoprotein concentration by agarose gel electrophoresis and particle size by electron microscopy coupled with molar ratios of surface to core constituents indicate that the swinging bucket procedure resulted in a more complete harvest of VLDL particles, especially those in the larger size range.     

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.     

Regulation of plasma lecithin:cholesterol acyltransferase in man. III. Role of high density lipoprotein cholesteryl esters in the activating effect of a high-fat test meal.

Plasma lecithin:cholesterol acyltransferase (LCAT) activity is increased during the clearance phase of alimentary lipemia induced by a high-fat test meal in normal subjects. Ultracentrifugal fractionation of high density lipoproteins (HDL) into HDL(2), HDL(3), and very high density (VHD) subfractions followed by analyses of lipid and protein components has been accomplished at intervals during alimentary lipemia to seek associations with enzyme changes. HDL(2) lipids and protein increased substantially, characterized primarily by enrichment with lecithin. HDL(3), which contain the main LCAT substrates, revealed increased triglycerides and generally reduced cholesteryl esters which were reciprocally correlated, demonstrating a phenomenon previously observed in vitro by others. Both changes correlated with LCAT activation, but partial correlation analysis indicated that ester content is primarily related to triglycerides rather than LCAT activity. The VHD cholesteryl esters and lysolecithin were also reduced. Plasma incubation experiments with inactivated LCAT showed that alimentary lipemic very low density lipoproteins (VLDL) could reduce levels of cholesteryl esters in HDL by a nonenzymatic mechanism. In vitro substitution of lipemic VLDL for postabsorptive VLDL resulted in enhanced reduction of cholesteryl esters in HDL(3) and VDH, but not in HDL(2), during incubation. Nevertheless, augmentation of LCAT activity did not result, indicating that cholesteryl ester removal from substrate lipoproteins is an unlikely explanation for activation. Since VHD and HDL(3), which contain the most active LCAT substrates, were also most clearly involved in transfers of esters to VLDL and low density lipoproteins, the suggestion that LCAT product lipoproteins are preferentially involved in nonenzymatic transfer and exchange is made. The main determinant of ester transfer, however, appears to be the level of VLDL, both in vitro and in vivo. Rose, H. G., and J. Juliano. Regulation of plasma lecithin: cholesteryl acyltransferase in man. III. Role of high density lipoprotein cholesteryl esters in the activating effect of a high-fat test meal.     

Synergistic effects of lipid transfers and hepatic lipase in the formation of very small high-density lipoproteins during incubation of human plasma

Studies have been performed to determine the involvement of very-low-density lipoproteins (VLDL), cholesteryl ester transfer protein (CETP) and hepatic lipase (HL) in the formation of very small HDL particles. Human whole plasma has been incubated for 6 h at 37 degrees C in the absence and in the presence of various additions. There was minimal formation of very small HDL in incubations of non-supplemented plasma or in plasma supplemented with either VLDL, CETP or HL alone; nor were small HDL prominent after incubating plasma supplemented with mixtures of VLDL plus CETP, VLDL plus HL or CETP plus HL. By contrast, when plasma was supplemented with a mixture containing all three of VLDL, CETP and HL, incubation resulted in an almost total conversion of the HDL fraction into very small particles of radius 3.7 nm. The appearance of these very small HDL was independent of activity of lecithin: cholesterol acyltransferase. It was, however, dependent on both duration of incubation and on the concentrations of the added VLDL, CETP and HL. The effects of these incubations was also assessed in terms of changes to the concentration and distribution of lipid constituents across the lipoprotein spectrum. It was found that not only did lipid transfers and HL exhibit a marked synergism in promoting a reduction in HDL particle size but also that HL, although deficient in intrinsic transfer activity, enhanced the CETP-mediated transfers of cholesteryl esters from HDL to other lipoprotein fractions.     

Pathogenesis of the hypertriglyceridemia at early stages of alcoholic liver injury in the baboon

To study the mechanism of alcoholic hypertriglyceridemia, baboons were pair-fed liquid diets containing 50% of energy as ethanol or as additional carbohydrate for 5-16 months. Alcohol-fed animals developed hypertriglyceridemia and early stages of alcoholic injury, namely fatty liver with or without perivenular fibrosis. In the fasting state, the triglyceride content was sixfold higher in very low density (VLDL) and intermediate density (IDL) lipoproteins and twofold higher in low density (LDL) and high density (HDL) lipoproteins. The increase in VLDL was markedly exaggerated in the postprandial state. To investigate the source of these increases, we determined net output or removal of serum triglycerides during circulation through either splanchnic or extrasplanchnic (lower extremities) vascular beds. In the splanchnic territory, there was net output of triglycerides in VLDL and net removal from the other lipoproteins. In alcohol-fed baboons, the output of VLDL-triglycerides into the hepatic (but not into the portal) vein tripled. This increase was mainly due to production of VLDL particles that were larger and had a flotation (Sf greater than 400) different from the Sf 20-400 which predominated in controls. This was associated with increased splanchnic removal of labeled chylomicron- or VLDL-triglycerides. In the lower extremities, there was an arteriovenous difference in VLDL-triglyceride concentration and this was increased in the alcohol-fed animals. Thus, the primary mechanism of the hypertriglyceridemia in alcohol-fed baboons was increased production of large, chylomicron-like VLDL by the liver, whereas both the extrasplanchnic extraction of VLDL-triglycerides and the splanchnic extraction of triglycerides from chylomicron- and VLDL-remnants were secondarily enhanced.     

In vivo evidence of a role for hepatic lipase in human apoB-containing lipoprotein metabolism, independent of its lipolytic activity

Hepatic lipase (HL) is a key player in lipoprotein metabolism by modulating, through its lipolytic activity, the triglyceride (TG) and phospholipid content of apolipoprotein B (apoB)-containing lipoproteins and of high density lipoproteins (HDL), thereby affecting their size and density. A new and separate role has been suggested for HL in cellular lipoprotein metabolism, in which it serves as a ligand promoting cellular uptake of apoB-containing remnant lipoproteins and HDL. We tested the hypothesis that HL has both a lipolytic and a nonlipolytic role in human lipoprotein metabolism, by measuring lipid plasma concentrations, lipoprotein density distribution by density gradient ultracentrifugation, and lipoprotein composition, in three subjects with HL deficiency: two of the patients (S-1 and S-3) were characterized as having neither plasma HL activity nor detectable HL protein; the third subject (S-2) had no plasma HL activity but a detectable amount (35.5 ng/ml) of HL protein. All HL-deficient subjects showed a severalfold increase in lipoprotein TG content across the lipoprotein density spectrum [very low density lipoprotein (VLDL), intermediate density lipoprotein (IDL), low density lipoprotein (LDL), and HDL] as compared with control subjects. They also had remarkably more buoyant LDL particles (LDL-R(f) = 0.342;-0.394) as compared with the control subjects (LDL-R(f) = 0.303). Subjects S-1 and S-3 (no HL activity or protein) presented with a distinct increase in cholesterol and apoB levels in the IDL and VLDL density range as compared with patient S-2, with detectable HL protein, and the control subjects.This study provides evidence in humans that HL indeed plays an important role in lipoprotein metabolism independent of its enzymatic activity: in particular, inactive HL protein appears to affect VLDL and IDL particle concentration, whereas HL enzymatic activity seems to influence VLDL-, IDL-, LDL-, and HDL-TG content and their physical properties.     

Interactions of high density lipoproteins with very low and low density lipoproteins during lipolysis

Interactions of high density lipoproteins (HDL) with very low (VLDL) and low (LDL) density lipoproteins were investigated during in vitro lipolysis in the presence of limited free fatty acid acceptor. Previous studies had shown that lipid products accumulating on lipoproteins under these conditions promote the formation of physical complexes between apolipoprotein B-containing particles (Biochim. Biophys. Acta, 1987. 919: 97-110). The presence of increasing concentrations of HDL or delipidated HDL progressively diminished VLDL-LDL complex formation. At the same time, association of HDL-derived apolipoprotein (apo) A-I with both VLDL and LDL could be demonstrated by autoradiography of gradient gel electrophoretic blots, immunoblotting, and apolipoprotein analyses of reisolated lipoproteins. The LDL increased in buoyancy and particle diameter, and became enriched in glycerides relative to cholesterol. Both HDL2 and HDL3 increased in particle diameter, buoyancy, and relative glyceride content, and small amounts of apoA-I appeared in newly formed particles of less than 75 A diameter. Association of apoA-I with VLDL or LDL could be reproduced by addition of lipid extracts of lipolyzed VLDL or purified free fatty acids in the absence of lipolysis, and was progressively inhibited by the presence of increasing amounts of albumin. We conclude that lipolysis products promote multiple interactions at the surface of triglyceride-rich lipoproteins undergoing lipolysis, including physical complex formation with other lipoprotein particles and transfers of lipids and apolipoproteins. These processes may facilitate remodeling of lipoproteins in the course of their intravascular metabolism.     

Plasma very-low-density lipoprotein, low-density lipoprotein, and high-density lipoprotein oxidative modification induces procoagulant profiles in endogenous hypertriglyceridemia

This study was to investigate whether oxidatively modified lipoproteins were associated with changes of pro- and anticoagulant profiles in hypertriglyceridemic subjects. Plasma VLDL, LDL, and HDL were isolated with the one-step density gradient ultracentrifugation method. The oxidation of the lipoproteins was identified. Prothrombin time (PT) and activated partial thrombplastin time (APTT), tissue plasminogen activator and plasminogen activator inhibitor-1, and platelet aggregation rate were determined with a reaction system consisting of mixed fresh normal plasma, in endogenous hypertriglyceridemic (HTG) patients, in in vitro modified lipoproteins from a normolipidemic donor, and in experimental rats. The results indicated that oxVLDL, oxLDL, and oxHDL occurred in the plasma of HTG patients. Compared with the control group, PT and APTT, incubated with plasma VLDL, LDL, or HDL from HTG patients, respectively, were significantly reduced, while platelet maximal aggregation rates were significantly higher (P < 0.05-0.01). Similar procoagulant profiles were observed in in vitro modified lipoprotein components and in rats with intrinsic hypertriglyceridemia as well. These results support our previous finding that LDL, VLDL, and HDL were all oxidatively modified in vivo in the subjects with HTG, and suggest that procoagulation state may result from the abnormal plasma lipoprotein oxidative modification in vivo.