PLTP regulates STAT3 and NFκB in differentiated THP1 cells and human monocyte-derived macrophages.

Phospholipid transfer protein (PLTP) plays an important role in regulation of inflammation. Previously published studies have shown that PLTP binds, transfers and neutralizes bacterial lipopolysaccharides. In the current study we tested the hypothesis that PLTP can also regulate anti-inflammatory pathways in macrophages. Incubation of macrophage-like differentiated THP1 cells and human monocyte-derived macrophages with wild-type PLTP in the presence or absence of tumor necrosis factor alpha (TNFα) or interferon gamma (IFNγ) significantly increased nuclear levels of active signal transducer and activator of transcription 3, pSTAT3(Tyr705) (p<0.01). Similar results were obtained in the presence of a PLTP mutant without lipid transfer activity (PLTP(M159E)), suggesting that PLTP-mediated lipid transfer is not required for activation of the STAT3 pathway. Inhibition of ABCA1 by chemical inhibitor, glyburide, as well as ABCA1 RNA inhibition, reversed the observed PLTP-mediated activation of STAT3. In addition, PLTP reduced nuclear levels of active nuclear factor kappa-B (NFκB) p65 and secretion of pro-inflammatory cytokines in conditioned media of differentiated THP1 cells and human monocyte-derived macrophages. Our data suggest that PLTP has anti-inflammatory capabilities in macrophages.

SAA and PLTP activity in plasma of periodontal patients before and after full-mouth tooth extraction.

OBJECTIVE: To assess whether treatment of advanced periodontal disease affects plasma levels of serum amyloid A (SAA) and phospholipid transfer protein (PLTP) activity. DESIGN: We measured the levels of SAA and PLTP activity in plasma of 66 patients with advanced periodontal disease before and after treatment by full-mouth tooth extraction (FME). RESULTS: At baseline, median SAA levels in our study population were within the normal range (2.7 microg ml(-1)) but SAA was elevated (>5 microg ml(-1)) in 18% of periodontitis patients. Three months after FME, SAA levels were significantly reduced (P = 0.04). SAA did not correlate with any of the periodontal disease parameters. PLTP activity was elevated in patients with periodontitis, compared to the PLTP activity reference group (age-matched systemically healthy adults, n = 29; 18 micromol ml(-1) h(-1)vs 13 micromol ml(-1) h(-1), respectively, P = 0.002). PLTP activity inversely correlated with average periodontal pocket depth (PPD) per tooth (r(s) = -0.372; P = 0.002). Three months after FME, median PLTP activity did not change significantly. CONCLUSIONS: Full-mouth tooth extraction significantly reduces SAA, a marker of inflammation, while it does not affect plasma PLTP activity. However, the inverse correlation between PLTP activity and average PPD suggests that increased PLTP activity may limit periodontal tissue damage.

The measurement of apolipoprotein A-I and A-II levels in men and women by immunoassay.

To study apolipoprotein A-II, a simple, precise, and accurate immunodiffusion assay was developed and applied in a population sample of industrial employees. Apolipoprotein A-II (A-II) did not increase with age in men (r = -0.20, n = 172), but showed a slight increase with age in women (0.1 mg/dl per yr, r = 0.20, n = 188). A-II correlated significantly with apolipoprotein A-I (A-I) (r = 0.71) and high density lipoprotein (HDL) cholesterol (men, r = 0.64; women, r = 0.49). The A-I/A-II ratio was significantly related to HDL cholesterol (men, r = 0.29; women, r = 0.44). Women on no medication (n = 92) had A-II levels similar to men (34+/-5 and 33+/-5 mg/dl, mean+/-SD, respectively), whereas women on oral contraceptives or estrogens had significantly higher levels (39+/-6 mg/dl, n = 75, P < 0.01). The plasma A-I/A-II weight ratio was 3.6+/-0.4 for men and 3.8+/-0.5 for women. In the d = 1.10-1.21 subfraction, both males and females had similar A-I, A-II, and HDL cholesterol levels (men: mean, 97, 27, and 32 mg/dl, respectively; women: mean, 104, 28, and 36 mg/dl, respectively). Women had approximately twice the amount of A-I, A-II, and HDL cholesterol than men in the d = 1.063-1.10 fraction (men: mean, 10, 2, and 10 mg/dl, respectively; women: mean, 24, 4, and 19 mg/dl, respectively). The A-I/A-II weight ratio in the d = 1.063-1.10 fraction (men, 5.1+/-0.7; women, 6.1+/-1.3) was significantly greater (P < 0.01) than that in the d = 1.10-1.21 fraction (men, 3.7+/-0.2; women, 3.8+/-0.2). Furthermore, the weight ratio of cholesterol to total apoprotein A in the d = 1.063-1.10 fraction (men, 0.75+/-0.09; women, 0.67+/-0.05) was significantly higher (P < 0.01) than that found in the d = 1.10-1.21 fraction (men, 0.26+/-0.04, women, 0.28+/-0.05). Thus, the compositions of HDL hydrated density subclasses are significantly different from each other. These results suggest that the differences in HDL between men and women are due primarily to differences in the relative proportions of HDL subclasses rather than to the intrinsic differences in HDL structure.

Apoprotein B in fasting and postprandial human jejunal mucosa.

We tested whether apoprotein B is present in fasting and postprandial human duodenojejunal mucosa because lipoprotein-like particles are visualized by electron microscopy within the smooth endoplasmic reticulum and the Golgi cisternae of these absorptive cells. Duodenojejunal biopsies from normal volunteers were incubated in citrate buffer and were shaken in 1% EDTA so that absorptive cells could be freed from underlying tissue. Apoprotein B was determined by double-antibody radioimmunoassay in homogenates of absorptive cells. The preparations of absorptive cells were shown to be uncontaminated by plasma lipoproteins; they did not contain any albumin by immunodiffusion able to detect 2 mug/ml. They adsorbed less than 0.1% of 125I-low density lipoprotein which was added to the citrate buffer. Cell preparations from suction biopsies of human rectum contained no detectable apoprotein B. Duodenojejunal absorptive cells from 22 fasting subjects contained 3.2 +/- 0.5 mug of apoprotein B per 100 mg (wet wt) of biopsies or 1.3 mug of apoprotein B per mg of total cell protein. The amount of apoprotein B per milligram of cell protein fell to 0.3 mug in 14 of these individuals whose mucosa was also sampled 45 min after instilling fat intraduodenally. These experiments provide immunochemical evidence that human duodenojejunal absorptive cells contain apoprotein B. This technique should be valuable for studying the physiology of intestinal lipoproteins in absorption and in patients with hyperlipidemia.

Radioimmunoassay of human plasma lecithin-cholesterol acyltransferase.

A sensitive and precise competitive-displacement double-antibody radioimmunoassay was developed for the human plasma enzyme lecithin-cholesterol acyltransferase (LCAT; Ec 2.3 1.43). The ability of plasma from various animal species to displace labeled human LCAT from goat anti-human LCAT could be ranked in the following order: man and sheep > nonhuman primates > cat or dog > pig > rabbit or guinea pig > mouse > rat. Normolipidemic subjects had levels of LCAT of 6.14 +/- 0.98 micrograms/ml (mean +/- SD, n = 66). Subjects with dysbeta-lipoproteinemia had the highest plasma LCAT levels (7.88 +/- 0.39 micrograms/ml, n = 7, P < 0.05), followed by hypercholesterolemic subjects (7.00 +/- 1.30, n = 41) and hypertriglyceridemic subjects (6.96 +/- 1.3, n = 10). LCAT-deficient subjects had the lowest enzyme levels (0.89, 0.83, and 0.05 micrograms/ml, respectively, and two subjects with no detectable enzyme). Males had lower LCAT levels (6.42 +/- 1.05 micrograms/ml, n = 90, for all subjects; 5.99 +/- 1.03, n = 44, for normolipidemics) than females (7.01 +/- 1.14, n = 34, for all subjects P < 0.01; 6.44 +/- 0.79, n = 22, for normolipidemics, P < 0.01). LCAT levels correlated significantly with total cholesterol (males, r = 0.384, P < 0.001; females, r = 0.519, P < 0.002); and total triglyceride (only in females, r = 0.512, P < 0.002). LCAT levels in females correlated inversely with HDL cholesterol (r = 0.341, P < 0.05) and apoprotein D (r = 0.443, P < 0.02), but no such relationship existed in males.

Low-density lipoprotein receptor activity in cultured human skin fibroblasts. Mechanism of insulin-induced stimulation.

Low-density lipoproteins (LDL) receptor activity, as reflected by LDL degradation, was stimulated by the addition of insulin to cultures of human skin fibroblasts. These changes occurred independently of the glucose concentration of the incubation medium and occurred whether or not LDL receptor activity was suppressed. A comparison of the saturation kinetics of LDL receptor activity in the presence and absence of insulin indicated that insulin produced a 35% increase in Vmax with no difference in "apparent Km". These results suggest that insulin enhances LDL receptor activity by increasing the number of LDL receptors rather than by influencing binding affinity. In confirmation, LDL degradation by receptor negative cells was not enhanced by insulin. Sterol synthesis from [14C]acetate was also stimulated by insulin, but egress of cholesterol and cellular cholesterol content were unaffected by the hormone. The effect of insulin on LDL receptors was not dependent on its known ability to enhance cellular DNA synthesis and proliferation, because insulin stimulated LDL receptor activity in cells kept quiescent by maintenance in plasma-derived serum that was devoid of platelet derived growth factor. Nevertheless, the effect of insulin in enhancing LDL receptor number, coupled with stimulation of endogenous cholesterol synthesis, provides a mechanism whereby the cell could theoretically increase its supply of cholesterol during times of additional need.

Specific high-affinity binding of high density lipoproteins to cultured human skin fibroblasts and arterial smooth muscle cells.

Binding of human high density lipoproteins (HDL, d = 1.063-1.21) to cultured human fibroblasts and human arterial smooth muscle cells was studied using HDL subjected to heparin-agarose affinity chromatography to remove apoprotein (apo) E and B. Saturation curves for binding of apo E-free 125I-HDL showed at least two components: low-affinity nonsaturable binding and high-affinity binding that saturated at approximately 20 micrograms HDL protein/ml. Scatchard analysis of high-affinity binding of apo E-free 125I-HDL to normal fibroblasts yielded plots that were significantly linear, indicative of a single class of binding sites. Saturation curves for binding of both 125I-HDL3 (d = 1.125-1.21) and apo E-free 125I-HDL to low density lipoprotein (LDL) receptor-negative fibroblasts also showed high-affinity binding that yielded linear Scatchard plots. On a total protein basis, HDL2 (d = 1.063-1.10), HDL3 and very high density lipoproteins (VHDL, d = 1.21-1.25) competed as effectively as apo E-free HDL for binding of apo E-free 125I-HDL to normal fibroblasts. Also, HDL2, HDL3, and VHDL competed similarly for binding of 125I-HDL3 to LDL receptor-negative fibroblasts. In contrast, LDL was a weak competitor for HDL binding. These results indicate that both human fibroblasts and arterial smooth muscle cells possess specific high affinity HDL binding sites. As indicated by enhanced LDL binding and degradation and increased sterol synthesis, apo E-free HDL3 promoted cholesterol efflux from fibroblasts. These effects also saturated at HDL3 concentrations of 20 micrograms/ml, suggesting that promotion of cholesterol efflux by HDL is mediated by binding to the high-affinity cell surface sites.

A frameshift mutation in the human apolipoprotein A-I gene causes high density lipoprotein deficiency, partial lecithin: cholesterol-acyltransferase deficiency, and corneal opacities.

Epidemiologic data of recent years have identified an important role of HDL deficiency in the etiology of atherosclerosis. Biochemical data suggest that some of these deficiencies may be a consequence of defects in the structural genes of HDL apolipoproteins or of plasma enzymes that modify HDL. We analyzed the genetic defect in a 42-yr-old patient suffering from corneal opacities and complete absence of HDL cholesterol but not of coronary artery disease, thus clinically resembling fish eye disease. The observation of an abnormal immunoblot banding pattern of apolipoprotein A-I (apo A-I) and of reduced lecithin: cholesterol acyltransferase (LCAT) activity in plasma led to sequence analysis of the genes for apo A-I and LCAT in this patient and his family. Direct sequencing of polymerase chain reaction amplified DNA segments containing the exons of the candidate genes, resulted in the identification of a frameshift mutation in apo A-I while the LCAT sequence was identical to the wild type. The apo A-I mutation was predictive for an extensive alteration of the COOH-terminal sequence of the encoded protein. Evidence for the release of this mutant protein into the plasma compartment and for the absence of normal apo A-I was derived from ultraviolet laser desorption/ionization mass spectrometry analysis. Our results suggest that a defective apo A-I is the causative defect in this case of HDL deficiency with corneal opacities.

Metabolic studies in an unusual case of asymptomatic familial hypobetalipoproteinemia with hypolphalipoproteinemia and fasting chylomicronemia.

A new kindred with asymptomatic hypobetalipoproteinemia is reported. The proband, age 67, differs from previously described cases in several respects: (a) unusually low levels of low density lipoprotein (LDL) cholesterol (4-8 mg/dl); (b) normal triglyceride levels; (c) low levels of high density lipoprotein; (d) mild fat malabsorption; and (e) a defect in chylomicron clearance. On a high-carbohydrate diet his plasma triglyceride levels, instead of rising, actually fell. Turnover of triglycerides in very low density lipoproteins (VLDL) was low (2.8 mg/kg per h). Fractional catabolic rate of LDL protein was just above the normal range (0.655/d) but net turnover was <10% of normal (0.65 mg/kg per d). The half-life of his chylomicrons was 29 min, five times the normal value. Postheparin lipoprotein lipase activity was normal and apolipoprotein C-II, the activator protein for lipoprotein lipase, was present and functional. Apolipoprotein C-III(1), however, was not detected in the VLDL fraction, a finding previously reported in patients with abetalipoproteinemia. Fecal excretion of cholesterol was almost twice normal; total sterol balance was increased by congruent with40%. The unusual features in the proband that distinguish him from previously described cases and from his affected first-degree relatives suggested that, in addition to the basic gene defect affecting LDL metabolism, he might have a second abnormality affecting clearance of chylomicrons and VLDL. The ratio of apolipoprotein E(3) to E(2) in his VLDL fraction was 0.93, just below the lower limit of normal, suggesting heterozygosity for E(3) deficiency. Whether or not this contributes to his hypertriglyceridemia remains to be established.

Fish eye syndrome: a molecular defect in the lecithin-cholesterol acyltransferase (LCAT) gene associated with normal alpha-LCAT-specific activity. Implications for classification and prognosis.

We have identified the molecular defect in two siblings presenting with classical clinical and biochemical features of Fish Eye disease (FED), including corneal opacities, HDL cholesterol < 10 mg/dl, normal plasma cholesteryl esters, and elevated triglycerides. In contrast to previously reported patients with FED who are unable to esterify HDL-associated cholesterol, our patients' plasma lecithin-cholesterol acetyltransferase (alpha-LCAT)-specific activities assayed using an HDL-like proteoliposome substrate were 12.7-25.7 nmol/micrograms (19.5 +/- 1.8 in controls). In addition, significant residual cholesterol esterification was present in VLDL/LDL-depleted plasma, confirming the presence of HDL-associated alpha-LCAT activity. DNA sequence analysis of the proband's LCAT gene identified deletion of the triplet coding for leu300, which resulted in the loss of a restriction site for MlnI. Digestion of PCR-amplified DNA using MlnI established that both siblings are homozygous for this defect. Expression of LCAT300-del. in human embryonic kidney-293 cells revealed normal mRNA and intracellular LCAT concentrations. However, reduced amounts of LCAT300-del., which had a normal specific alpha-LCAT activity, were present in the media. In summary, we report the first case of FED associated with a mutant enzyme that has a normal alpha-LCAT-specific activity. The functional significance of this LCAT gene defect has been established in an in vitro expression system, which demonstrates that very small amounts of this functional LCAT mutant enzyme accumulate in the media. Characterization of LCAT300-del. established that selective alpha-LCAT deficiency is not a prerequisite for the development of FED. On the basis of our combined results, we propose that the residual amounts of total plasma LCAT activity and not its distribution on lipoproteins primarily determines the heterogeneity in phenotypic expression observed in familial LCAT deficiency syndromes.

The effect of hypoxia on uptake and degradation of low density lipoproteins by cultured human arterial smooth muscle cells.

Atheroma have been produced in experimental animal by systemic hypoxia. This study assessed the effects of hypoxia on binding, uptake and degradation of human low density lipoprotein (LDL) by human arterial smooth muscle cells, the cell involved in atherogenesis. The LDL content of the smooth muscle cell grown in the usual conditions (95% air [20% O2], 5% CO2) increased with the incubation time of LDL in the medium (7.5 mug protein/ml of medium); the trypsin releasable LDL "binding" reached a plateau by 24 h (2.2 +/- 1.3 [x +/- S.D.]) ng/mug LDL protein added per 10(6) cells whereas the LDL in the cell after trypsinization ("net uptake") continued to increase up to 48 h (6.5 +/- 4.6 ng/mug LDL protein added per 10(6) cells at 48 h). LDL protein degradation increases rapidly between 7 and 48 h (10.4 ng/mug LDL protein added per 10(6) cells at 24 h) after an initial delay of approximately 7 h. Smooth muscle cells grown under hypoxic conditions (5%02) had similar LDL "binding " but showed increased "net uptake" (10.7 +/- 4.8 ng/mug LDL protein added per 10(6) cells) and a 36 +/- 13% decrease in degradation (p less than 0.05; n =8). The impaired degradation of lipoprotein by smooth muscle cells may, in part, explain the role of hypoxia in atherogenesis.

Lipoprotein uptake by cultured human arterial smooth muscle cells.

Human arterial smooth muscle cells growing in tissue culture, in contrast to rat cells, preferentially bind and take up large, lipid-rich lipoproteins (125I-labeled low density and very low density lipoproteins) in comparison to the known difference in the propensity of these two species to develop atherosclerosis.

A rapid large-scale procedure for purification of lecithin-cholesterol acyltransferase from human and animal plasma.

A rapid and convenient procedure was developed for large-scale purification of lecithin-cholesterol acyltransferase from the plasma of humans, pigs, dogs, goats and rabbits. The procedure included dextran sulfate-Mg2+ precipitation, Phenyl-Sepharose column, Affi-gel blue column, DEAE-Sepharose column, DEAE-Affi-gel blue column and hydroxyapatite column. Lecithin-cholesterol acyltransferase was purified approx. 20 000-fold with about 14% yield from human plasma. A similar result of purification was obtained from pigs, dogs, goats and rabbits. The final enzyme preparation from all five mammalian species was homogeneous as judged by SDS-polyacrylamide gel electrophoresis and high-performance gel filtration in the presence of SDS. The apparent molecular weight of the purified enzymes from humans, pigs, dogs, goats and rabbits were 65 000, 66 000, 65 000, 65 000 and 66 000, respectively, as determined by SDS-polyacrylamide gel electrophoresis and were 67 000, 67 000, 66 000, 66 000 and 67 000, respectively, by high-performance gel filtration. Studies with DEAE-Sepharose columns demonstrated that lecithin-cholesterol acyltransferase from these mammalian species was similar in molecular charge. The pH optimum for activity of purified enzyme ranged from 7.4 to 8.0 among these species. All purified lecithin-cholesterol acyltransferase species were activated by human apolipoprotein A-I and were similarly inhibited by p-hydroxymercuribenzoate and phenylmethylsulfonyl fluoride. We concluded that this purification scheme is suitable for rapid isolation of lecithin-cholesterol acyltransferase from the plasma of humans, pigs, dogs, goats and rabbits and, by inference, from other mammalian species. The availability of purified active lecithin-cholesterol acyltransferase from various animal species should facilitate phylogenetic and comparative studies of the enzyme.

Activation of lecithin: cholesterol acyltransferase by apolipoproteins E-2, E-3, and A-IV isolated from human plasma.

Apolipoprotein A-IV, apolipoprotein E-2 and apolipoprotein E-3 were individually incorporated into defined phosphatidylcholine/cholesterol liposomes for study of lecithin:cholesterol acyltransferase activation. Enzyme activities obtained with these liposomes were compared with that from liposomes containing purified apolipoprotein A-I. Apolipoprotein A-IV, apolipoprotein E-2, and apolipoprotein E-3 all activated lecithin:cholesterol acyltransferase. With purified enzyme and with egg yolk phosphatidylcholine as the acyl donor, maximal activation was obtained at a concentration of approximately 0.5 nmol for apolipoprotein A-IV and 0.4 nmol for the apolipoprotein E isoforms. Apolipoprotein A-IV was approximately 25% as efficient as apolipoprotein A-I for the activation of purified enzyme; apolipoprotein E-2 was 40% as efficient, and apolipoprotein E-3, 30%. Similar activation results were obtained using plasma as the enzyme source. Analysis of the plasma of patients with absence of apolipoprotein A-I or with only trace amounts of apolipoprotein A-I exhibited a reduced rate of cholesterol esterification and lecithin:cholesterol acyltransferase activity that was proportional to the reduced level of the enzyme's mass. These results indicate that apolipoprotein A-IV and apolipoprotein E may serve as physiological cofactors for the enzyme reaction.

Interspecies activation of lecithin-cholesterol acyltransferase by apolipoprotein A-I isolated from the plasma of humans, horses, sheep, goats and rabbits.

The abilities of apolipoprotein A-I species isolated from humans, horses, sheep, goats and rabbits to activate purified human lecithin-cholesterol acyltransferase and the enzyme from homologous plasmas and plasma of other mammalian species were compared. Each purified apolipoprotein A-I species was individually incorporated into phosphatidylcholine/cholesterol vesicles by the cholate dialysis method to form proteoliposome common substrates (apolipoprotein A-I/phosphatidylcholine/cholesterol molar ratio of 1:250:12.5) for the enzyme activity assay. All apolipoprotein A-I species tested had the ability, but with different effectiveness, to activate plasma lecithin-cholesterol acyltransferase from their own and other animal species and from purified human lecithin-cholesterol acyltransferase. Horse apolipoprotein A-I was nearly as effective as human apolipoprotein A-I, whereas apolipoproteins A-I from goats, sheep or rabbits were, in descending order, slightly less effective than either horse or human apolipoprotein A-I in activating human plasma lecithin-cholesterol acyltransferase. A similar trend in ability to activate purified human lecithin-cholesterol acyltransferase by these apolipoprotein A-I species was seen, but apolipoprotein A-I from sheep, goats and rabbits was only about 55-65% as effective as human apolipoprotein A-I. In general, apolipoprotein A-I from the same animal species as the lecithin-cholesterol acyltransferase enzyme was a better activator of the enzyme than was apolipoprotein A-I from another animal species. Comparison of lecithin-cholesterol acyltransferase activities of each plasma paired with its own apolipoprotein A-I, which reflects the level of the enzyme in the plasma, revealed descending levels of the enzyme's activity (nmol/h per ml) as follows: humans (98.9 +/- 10.3), horses (90.7 +/- 10.6), sheep (69.9 +/- 9.7), goats (64.9 +/- 9.2) and rabbits (52.0 +/- 6.2). Studies with DEAD-Sepharose columns, gel electrophoresis, and proteoliposome substrates demonstrated that apolipoprotein A-I from these mammalian species are similar in molecular charge and weight and are functionally similar in lecithin-cholesterol acyltransferase activation.

Plasma phospholipid mass transfer rate: relationship to plasma phospholipid and cholesteryl ester transfer activities and lipid parameters.

Human plasma phospholipid transfer protein (PLTP) has been shown to facilitate the transfer of phospholipid from liposomes or isolated very low and low density lipoproteins to high density lipoproteins. Its activity in plasma and its physiological function are presently unknown. To elucidate the role of PLTP in lipoprotein metabolism and to delineate factors that may affect the rate of phospholipid transfer between lipoproteins, we determined the plasma phospholipid mass transfer rate (PLTR) in 16 healthy adult volunteers and assessed its relationship to plasma lipid levels, and to phospholipid transfer activity (PLTA) and cholesteryl ester transfer activity (CETA) measured by radioassays. The plasma PLTR in these subjects was 27.2 +/- 11.8 nmol/ml per h at 37 degrees C (mean +/- S.D.), and their PLTA and CETA were 13.0 +/- 1.7 mumol/ml per h and 72.8 +/- 15.7 nmol/ml per h, respectively. Plasma PLTR was correlated directly with total, non-HDL, and HDL triglyceride (rs = 0.76, P < 0.001), total and non-HDL phospholipid (rs > 0.53, P < 0.05), and inversely with HDL free cholesterol (rs = -0.54, P < 0.05), but not with plasma PLTA and CETA. When 85% to 96% of the PLTA in plasma was removed by polyclonal antibodies against recombinant human PLTP, phospholipid mass transfer from VLDL and LDL to HDL was reduced by 50% to 72%, but 80% to 100% of CETA could still be detected. These studies demonstrate that PLTP plays a major role in facilitating the transfer of phospholipid between lipoproteins, and suggest that triglyceride is a significant modulator of intravascular phospholipid transport. Furthermore, most of the PLTP and CETP in human plasma is associated with different particles. Plasma PLTA and CETA were also measured in mouse, rat, hamster, guinea pig, rabbit, dog, pig, and monkey. Compared to human, PLTA in rat and mouse was significantly higher and in rabbit and guinea pig was significantly lower while the remaining animal species had PLTA similar to humans. No correlation between PLTA and CETA was observed among animal species.

Regulatory role of insulin in the degradation of low density lipoprotein by cultured human skin fibroblasts.

The degradation of 125I-labeled low density lipoprotein by cultured human skin fibroblasts was enhanced 25% by preincubation of cells with insulin. This effect of insulin appeared to be mediated via stimulation of low density lipoprotein binding to its cell surface receptor, since binding and subsequent internalization of low density lipoprotein were stimulated to a similar extent as was degradation. In addition, insulin enhanced binding of low density lipoprotein at 4 degrees C, at which temperature internalization of the lipoprotein does not occur. A similar effect of insulin on the interaction of very low density lipoprotein with cultured fibroblasts was observed. Insulin-induced changes in the degradation of low density lipoprotein and very low density lipoprotein appeared to be a function of the change in lipoprotein binding. Thus, insulin may play a role in the regulation of low density lipoprotein and very low density lipoprotein degradation by peripheral cells by influencing the receptor-mediated transport of these lipoproteins.

Phospholipid transfer protein enhances removal of cellular cholesterol and phospholipids by high-density lipoprotein apolipoproteins.

High-density lipoprotein (HDL) apolipoproteins remove excess cholesterol from cells by an active transport pathway that may protect against atherosclerosis. Here we show that treatment of cholesterol-loaded human skin fibroblasts with phospholipid transfer protein (PLTP) increased HDL binding to cells and enhanced cholesterol and phospholipid efflux by this pathway. PLTP did not stimulate lipid efflux in the presence of albumin, purified apolipoprotein A-I, and phospholipid vesicles, suggesting specificity for HDL particles. PLTP restored the lipid efflux activity of mildly trypsinized HDL, presumably by regenerating active apolipoproteins. PLTP-stimulated lipid efflux was absent in Tangier disease fibroblasts, induced by cholesterol loading, and inhibited by brefeldin A treatment, indicating selectivity for the apolipoprotein-mediated lipid removal pathway. The lipid efflux-stimulating effect of PLTP was not attributable to generation of prebeta HDL particles in solution but instead required cellular interactions. These interactions increased cholesterol efflux to minor HDL particles with electrophoretic mobility between alpha and prebeta. These findings suggest that PLTP promotes cell-surface binding and remodeling of HDL so as to improve its ability to remove cholesterol and phospholipids by the apolipoprotein-mediated pathway, a process that may play an important role in enhancing flux of excess cholesterol from tissues and retarding atherogenesis.

Cholesterol esterification by lecithin-cholesterol acyltransferase in A-I-free plasma.

Lecithin-cholesterol acyltransferase (LCAT) mass, activity and endogenous cholesterol esterification rate were measured in plasma and apolipoprotein A-I-free (A-I-free) plasma from two normolipidemic and two hyperlipidemic subjects, and from a patient with Tangier disease. A-I was removed from plasma by an anti-A-I immunosorbent. LCAT activity was measured using an exogenous substrate. The plasma LCAT concentration of the four non-Tangier subjects was 4.63 +/- 0.64 micrograms/ml (mean +/- S.D.); means of 26 +/- 7% of total LCAT mass and 22 +/- 11% of plasma LCAT activity were found in their A-I-free plasma. The plasma LCAT concentration of the Tangier subject was 1.49 micrograms/ml. About 95% of LCAT mass and all LCAT activity were found in the A-I-free plasma. Thus, the LCAT mass (1.4 micrograms/ml) and activity (43.1 nmol/h per ml) in Tangier A-I-free plasma were not significantly different from that found in the four non-Tangier A-I-free plasmas (mass = 1.21 +/- 0.44 micrograms/ml; activity: 27.3 +/- 18.4 nmol/h per ml). Although the LCAT activity per unit mass of the enzyme in plasma and A-I-free plasma were comparable (24.9 +/- 2.8 vs. 22.8 +/- 7.8 nmol/h per micrograms LCAT, n = 5), the plasma cholesterol esterification rate of A-I-free plasma from all subjects was lower than that found in plasma (7.5 +/- 2.7 vs. 13.0 +/- 3.8 nmol/h per micrograms LCAT). In conclusion, although A-I-containing lipoproteins are the preferred substrates of LCAT, other LCAT substrates and cofactors are found in A-I-free plasma along with LCAT. Thus, non-A-I-containing particles can serve as physiological substrates for cholesterol esterification mediated by LCAT.

Uptake of chylomicron remnants causes cholesterol accumulation in cultured human arterial smooth muscle cells.

Chylomicron remnants (Sf greater than 100) were prepared by treating human chylomicrons (Sf greater than 400) with human post heparin plasma. Chylomicron remnants recovered after 70-80% of chylomicron triacylglycerol was hydrolyzed, suppressed LDL-receptor activity and increased cell cholesterol esterification to the same extent as did LDL when added to cultured human arterial smooth muscle cells at an equal cholesterol concentration. Cell cholesterol mass increased 36% after incubation with 25 micrograms LDL cholesterol/ml and 35% with 25 micrograms chylomicron-remnant cholesterol/ml. Addition of 30 microM chloroquine plus LDL or chylomicron remnants further increased cholesterol content of cells (74% and 87%, respectively) and caused a significant rise in cell esterified cholesterol (344% and 369%, respectively). Cholesterol content per unit of apolipoprotein B mass of remnants was 2-3-fold higher than that of LDL. Therefore, if lipoprotein particles were added at equivalent apolipoprotein B mass chylomicron remnants increased cell cholesterol content and cholesterol esterification and suppressed LDL receptor activity significantly more than did LDL. This suggests that an additional determinant, presumably apolipoprotein E, is important for receptor recognition of chylomicron remnants. These results may be relevant to the delivery of chylomicron-derived cholesterol to arterial cells proposed as a feature of atherogenesis.