Cardiolipin content of wild type and mutant yeasts in relation to mitochondrial function and development.

The phospholipid composition of various strains of the yeast, Saccharomyces cerevisiae, and several of their derived mitochondrial mutants grown under conditions designed to induce variations in the complement of mitochondrial membranes has been examined. Wild type and petite (cytoplasmic respiratory deficient) yeasts were fractionated into various subcellular fractions, which were monitored by electron microscopy and analyzed for cytochrome oxidase (in wild type) and phospholipid composition. 90% or more of the phospholipid, cardiolipin was found in the mitochondrial membranes of wild type and petite yeast. Cardiolipin content differed markedly under various growth conditions. Stationary yeast grown in glucose had better developed mitochondria and more cardiolipin than repressed log phase yeast. Aerobic yeast contained more cardiolipin than anaerobic yeast. Respiration-deficient cytoplasmic mitochondrial mutants, both suppressive and neutral, contained less cardiolipin than corresponding wild types. A chromosomal mutant lacking respiratory function had normal cardiolipin content. Log phase cells grown in galactose and lactate, which do not readily repress the development of mitochondrial membranes, contained as much cardiolipin as stationary phase cells grown in glucose. Cytoplasmic mitochondrial mutants respond to changes in the glucose concentration of the growth medium by variations in their cardiolipin content in the same way as wild type yeast does under similar growth conditions. It is concluded that cardiolipin content of yeast is correlated with, and is a good indicator of, the state of development of mitochondrial membrane.

Effect of Reye's syndrome serum on isolated chinchilla liver mitochondria.

A general impairment of liver mitochondrial enzymes is central to Reye's syndrome (RS). The respiration of isolated liver mitochondria was measured after the addition of concentrated normal serum or RS serum derived from 12 patients. RS serum stimulates oxygen consumption in isolated rat liver mitochondria. This effect is due to the oxidation of uric acid by peroxisomes contaminating the preparation and a stimulation of mitochondrial respiration (1.05 +/- 0.14 nmol of O2/min X mg of protein; control 0.30 +/- 0.08 nmol O2/min X mg). The stimulation of respiration occurs in the presence of all respiratory substrates, is dependent on the amount of serum added, and represents an uncoupling of oxidative phosphorylation. RS serum reduces ATP formation by 15-76%. The uncoupling effect correlates with the amount of free fatty acid in the serum sample and resembles the effect induced by the addition of a dicarboxylic fatty acid. Dicarboxylic fatty acids, especially long-chain dicarboxylic acids, impair ATP formation. Dicarboxylic acids were found in the serum of all RS patients and comprised as much as 54% of the total serum free fatty acids. 90% of the serum dicarboxylic acids were of 16-18 carbon lengths. The amount of dicarboxylic acids in the RS serum corresponded directly with the reduction in ATP formation by the RS serum. This demonstrates that dicarboxylic acids occur in RS and may be important in the general impairment of mitochondrial function in RS and other disorders where they are present.

Induction of omega-oxidation of monocarboxylic acids in rats by acetylsalicylic acid.

The accumulation of dicarboxylic acids, particularly long chain, is a prominent feature of Reye's syndrome and diseases of peroxisomal metabolism. We assessed the omega-oxidation of a spectrum of fatty acids in rats and asked whether pretreatment of rats with aspirin, which is known to predispose children to Reye's syndrome, would affect omega-oxidation of long chain fatty acids. We found that aspirin increased liver free fatty acids and increased the capacity for omega-oxidation three- to sevenfold. Omega-oxidation of long chain substrate was stimulated to a greater degree than medium chain substrate and was apparent within one day of treatment, at serum aspirin concentrations below the therapeutic range in humans. The apparent Km for lauric acid was 0.9 microM and 12 microM for palmitate. We also found a difference in the storage stability of activity toward medium and long chain substrate. Saturating concentrations of palmitate had no effect on the formation of dodecanedioic acid, whereas laurate decreased but never eliminated the omega-oxidation of palmitate. 97% of the total laurate omega-oxidative activity recovered was found in the microsomes, but 32% of palmitate omega-oxidative activity was present in the cytosol. These results demonstrate that aspirin is a potent stimulator of omega-oxidation and suggest that there may be multiple enzymes for omega-oxidation with overlapping substrate specificity.

The metabolism of proinsulin and insulin by the liver.

The removal of bovine proinsulin by the isolated perfused rat liver has been studied and the results compared with the removal of insulin. At high concentrations of insulin (> 180 ng/ml) the removal process was saturated and the t(1/2) varied between 35 and 56 min. With low initial insulin levels the disappearance followed first-order kinetics, the mean regression coefficient being - 0.022, t(1/2) 13.8 min, and the hepatic extraction 4.0 ml/min. The results with proinsulin were in striking contrast to these findings. At both high and low concentrations the hepatic removal of proinsulin was considerably slower, averaging 10-15 times less than that of insulin. Specific immunoassay techniques and gel filtration of samples taken from perfusions to which both labeled and unlabeled proinsulin had been added did not show conversion to either insulin or the C-peptide. Bovine and rat (131)I-labeled proinsulins were degraded more slowly than bovine insulin-(131)I by bovine and rat liver homogenates. Both proinsulin and insulin inhibited the degradation of insulin-(131)I, equimolar quantities of proinsulin being 2-5 times less effective than insulin. These results indicate significant differences in the capacity of the liver to remove and degrade insulin and proinsulin. The low hepatic extraction of proinsulin may account for its prolonged half-life in vivo and contribute to its relatively high plasma concentration in the fasting state. Furthermore this finding will have to be taken into account in the interpretation of changes in the proinsulin:insulin ratios in peripheral blood in a variety of metabolich situations.

Position-specific inhibition of yeast mitochondrial transcription by a poly(T) sequence.

The 3' flanking nucleotide(s) of the octanucleotide promoter sequence regulates transcriptional efficiency of some mitochondrial genes in Saccharomyces cerevisiae. To understand this regulation the in vitro transcriptional activity of various synthetic mitochondrial promoters carrying different 3' flanking sequences was examined. The results presented here demonstrate that consecutive thymidine residues, but no other polynucleotides or secondary structure, in the promoter-proximal non-transcribed DNA strand inhibited mitochondrial transcription. The location and the number of T residues in the cluster as well as the concentration of UTP in the transcription reaction are the important factors determining this transcriptional inhibition. For example, a pair of thymidine nucleotides at positions +2 and +3 is sufficient for inactivation of mitochondrial transcription, whereas more than three consecutive thymidine nucleotides beyond these positions are required for inhibition of mitochondrial transcription. However, a cluster of six to 12 thymidine residues beyond position +11, a point where mtRNA polymerase has been shown to form a stable transcription complex, did not interfere with mitochondrial transcription. Interestingly, at low UTP concentration the mtRNA polymerase generates a large quantity of aborted initiation products on a template carrying promoter-proximal poly(T) sequence probably due to the inability of the polymerase to clear this promoter. On the other hand at high UTP concentration the same mtRNA polymerase on the same mitochondrial promoter produces a higher level of productive initiation complex. These observations suggest that the mechanism of poly(T) inhibition of mitochondrial transcription is a UTP-limited transcriptional attenuation at the promoter site, which might occur under specific physiological conditions (i.e. glucose repression-derepression, switching of aerobic-anaerobic conditions).

Effect of immune deficiency on lipoproteins and atherosclerosis in male apolipoprotein E-deficient mice.

To determine whether T cells and B cells influence lipid metabolism and atherosclerosis, we crossed apolipoprotein E-deficient (apoE degrees ) mice with recombination activating gene 2-deficient (RAG2 degrees ) mice. Total plasma cholesterol levels were approximately 20% higher in male apoE degrees mice compared with the apoE degrees RAG2 degrees mice at 8 weeks of age, and plasma triglyceride levels were 2.5-fold higher in the apoE degrees mice even when plasma cholesterol levels were similar. Male mice with plasma cholesterol levels between 400 and 600 mg/dL at 8 weeks of age were euthanized at 27 and 40 weeks of age. The aortic root lesion area in the apoE degrees RAG2 degrees mice, compared with that in the immune-competent apoE degrees mice, was 81% and 57% smaller at 27 and 40 weeks of age, respectively. In contrast, there was no difference in the size of the brachiocephalic trunk lesions. Similar results were obtained with mice euthanized at 40 weeks of age that had 8-week cholesterol levels between 300 and 399 mg/dL. In apoE degrees RAG2 degrees mice, aortic root atherosclerosis was more profoundly suppressed at lower cholesterol levels. Thus, T and B cells and their products differentially influence the development of atherosclerosis at different sites. We also demonstrate a profound effect of the immune system on plasma lipid homeostasis.

Neurons of the human frontal cortex display apolipoprotein E immunoreactivity: implications for Alzheimer's disease.

Apolipoprotein E (apoE) is a plasma protein that regulates lipid transport and cholesterol homeostasis. In humans, apoE occurs as 3 major isoforms (apoE2, E3, and E4). Genetic evidence demonstrates an overrepresentation of the apoE epsilon 4 allele in Alzheimer's disease (AD). While apoE immunoreactivity (IR) is associated with the amyloid plaques and neurofibrillary tangles of AD, few studies have characterized the localization of apoE in normal human brains. We examined the distribution of apoE in the cerebral cortex of normal aged individuals and compared the results to clinically diagnosed and pathologically confirmed AD cases. In addition, we characterized the apoE IR in brains from high plaque non-demented (HPND) cases. We observed consistent and widespread apoE staining in cortical neurons from normal and HPND individuals. This finding was confirmed by double immunostaining which colocalized apoE with microtubule-associated protein-2, as well as low density lipoprotein receptor-related protein, an apoE receptor found on neurons. In contrast, AD brains displayed apoE IR in plaques and neurofibrillary tangles with little neuronal staining. These data clearly establish the presence of apoE in normal neurons, supporting an intracellular role for apoE. Moreover, the results suggest that this function of apoE is disrupted in AD, where apoE staining of neurons was drastically reduced.

The effect of thyroid hormone on in vitro rat liver mitochondrial RNA synthesis.

Liver mitochondrial preparations from normal, thyroidectomized, and triiodothyronine-treated thyroidectomized rats were assayed for in vitro RNA synthetic activity. Thyroidectomized rat mitochondrial preparations incorporated UTP into RNA at 70% the rate of normal control preparations. Mitochondrial preparations from triiodothyronine-treated thyroidectomized rats incorporated UTP at rates 35%-45% greater than those of sham-injected thyroidectomized rats. These differences were statistically significant and could not be attributed to inequalities in mitochondrial sampling, dilution of labeled precursor specific activity, nucleotide substrate concentrations, or differences in ribonuclease activities.

Loss of atheroprotective effect of estradiol in immunodeficient mice.

Estradiol significantly decreases fatty streak formation in the aortic root of chow-fed apolipoprotein E-deficient mice. In contrast, immunodeficient mice with homozygous disruption at the recombinase activating gene 2 loci present fatty streak development that is insensitive to estradiol. Lymphocytes thus appear to be required for development of the atheroprotective effect of estradiol in this mouse model.

Suppression of plasma testosterone leads to an increase in serum total and high density lipoprotein cholesterol and apoproteins A-I and B.

Men have lower high density lipoprotein (HDL) and higher low density lipoprotein (LDL) levels than women. To dynamically evaluate the role of endogenous testosterone on the lipoprotein profile, eight normal men received a long-acting gonadotropin releasing hormone analog (LHRHA) for 10 weeks by SC injection. Plasma testosterone levels were acutely lowered below 1 ng/ml after 4 weeks of LHRHA treatment and remained depressed at this level for the duration of administration of the analog. There were prompt increases in total cholesterol [baseline vs. peak (milligrams per dl) mean +/- SEM, 177 +/- 18 vs. 208 +/- 22; P less than 0.005], apoprotein B (apo B; 69 +/- 12 vs. 97 +/- 13; P less than 0.05), HDL-cholesterol (23 +/- 2 vs. 33 +/- 2; P less than 0.005), and apo A-I (80 +/- 7 vs. 112 +/- 5; P less than 0.005), but not in apo A-II (40 +/- 3 vs. 40 +/- 4; P = NS) levels. The peaks occurred after 10 weeks of treatment and were followed by a fall in these values after discontinuing LHRHA. These changes were largely prevented in a second study (six men) in which LHRHA was administered together with im testosterone enanthate, which was given every 2 weeks. These results show that suppression of endogenous testosterone leads to increases in HDL and LDL, demonstrating that testosterone has an important effect on lipoprotein metabolism and plays a key role in defining the lipoprotein profile in men.

Postprandial lipoprotein metabolism in normal and obese subjects: comparison after the vitamin A fat-loading test.

Abnormalities in fasting lipid and lipoprotein levels are known to occur in obesity and other hyperinsulinemic states. However, postprandial lipoprotein metabolism has not been studied systematically in obese subjects using sensitive techniques to distinguish between triglyceride-rich lipoprotein particles derived from the intestine and the liver. In the present study the vitamin A fat-loading test was used to label intestinally derived triglyceride-rich lipoprotein particles in the postprandial state. Lipid parameters in seven normolipidemic obese subjects [body mass index, 43.7 +/- 2.81 kg/m2 (mean +/- SEM)] were compared to those in eight matched normal weight controls (body mass index, 23.6 +/- 0.72 kg/m2) during the 24-h period following ingestion of a mixed meal with a high fat content to which vitamin A had been added. Although subjects were selected for normal fasting lipid levels, in the obese group fasting triglycerides were significantly higher (1.35 +/- 0.12 vs. 0.68 +/- 0.08 mmol/L; P less than 0.0005) and high density lipoprotein (HDL) cholesterol was lower (0.94 +/- 0.08 vs. 1.35 +/- 0.11 mmol/L; P less than 0.01). The obese subjects had a greater postprandial triglyceride response to the test meal (P less than 0.05). The cumulative increment in total plasma triglycerides was 3.35-fold greater in obese than control subjects, while that of retinyl ester was only 1.63-fold greater, suggesting that a significant portion of the postprandial triglyceride response is due to endogenous hepatic lipoproteins. Postprandial plasma triglyceride and retinyl ester increment correlated with basal triglycerides (r = 0.72; P less than 0.005 and r = 0.57; P less than 0.03, respectively) and negatively with fasting HDL (r = -0.51; P less than 0.05 and r = -0.60; P less than 0.02, respectively). In the obese, the HDL triglyceride content increased maximally 4 h postprandially (4.1% to 6.1%; P less than 0.005) and phospholipid at 12 h (25.8% to 28.7%; P less than 0.05), with lower cholesteryl ester (21.1% to 17.5%; P less than 0.002) at 8 h, reflecting exchange of surface and core lipids with triglyceride-rich particles after the meal. In obese and control subjects the magnitude of HDL triglyceride enrichment after the meal correlated positively with the postprandial triglyceride increment (r = 0.74; P less than 0.007) and negatively with the fasting HDL cholesterol concentration (r = -0.80; P = 0.002). We conclude that even normolipidemic obese subjects have greater postprandial lipemia and triglyceride enrichment of HDL after ingestion of a high fat meal.(ABSTRACT TRUNCATED AT 400 WORDS)

Role of basal triglyceride and high density lipoprotein in determination of postprandial lipid and lipoprotein responses.

The present study reports on the interaction between basal triglyceride and high density lipoprotein (HDL) cholesterol in determining the magnitude of postprandial triglyceridemia. The vitamin A fat-loading test was used to label intestinally derived triglyceride-rich particles after a high fat meal in 18 subjects with low HDL cholesterol and 6 control subjects who had normal fasting triglyceride and HDL cholesterol levels. The patients with low HDL cholesterol were divided into 2 groups on the basis of their basal triglyceride concentrations; 11 had normal triglyceride levels, and 7 had elevated serum triglycerides (HTG). In the HTG-low HDL group, the incremental area under the triglyceride curve was significantly greater (P less than 0.0003) than that in the other 2 groups, between whom no significant differences in triglyceride response were observed. Retinyl palmitate levels measured in whole plasma, an Sf greater than 1000 chylomicron fraction, and an Sf less than 1000 nonchylomicron fraction were also significantly greater in low HDL subjects with HTG, while the concentrations in low HDL subjects with normal triglyceride levels and control subjects were similar. Although basal HDL cholesterol levels in all study subjects were negatively correlated with the area under the incremental triglyceride curve (r = -0.42; P less than 0.05), this correlation was weak, in contrast to the correlation between fasting triglyceride levels and incremental triglyceride area (r = 0.56; P less than 0.005). Furthermore, basal HDL cholesterol levels did not correlate with the area under the chylomicron or nonchylomicron curves, whereas basal triglyceride levels were significantly correlated (P = 0.0001) with both of these variables. The HDL particles of both low HDL groups had a significantly higher proportion of triglyceride compared to the HDL particles in the control subjects. In conclusion, 1) fasting triglyceride levels are a more powerful indicator of the postprandial lipid response than basal HDL cholesterol in subjects with low HDL cholesterol levels; 2) patients with low HDL cholesterol levels do not preferentially accumulate chylomicron remnants after a meal unless they have coexisting hypertriglyceridemia; and 3) abnormalities in the levels of triglyceride-rich particles post-prandially are unlikely to be responsible for the increased incidence of atherosclerosis in low HDL patients who are normotriglyceridemic.

Fasting hypertriglyceridemia in noninsulin-dependent diabetes mellitus is an important predictor of postprandial lipid and lipoprotein abnormalities.

Postprandial lipoprotein metabolism may be important in atherogenesis and has not been studied in detail in noninsulin-dependent diabetes mellitus (NIDDM). We used the vitamin A fat-loading test to label triglyceride-rich lipoprotein particles of intestinal origin after ingestion of a high fat mixed meal containing 60 g fat/m2 and 60,000 U vitamin A/m2 in 12 untreated NIDDM subjects with normotriglyceridemia (NTG; triglycerides, less than 1.7 mmol/L), 7 untreated NIDDM subjects with moderate hypertriglyceridemia (HTG; triglycerides, 1.7-4.7 mmol/L), and 8 age- and weight-matched normotriglyceridemic nondiabetic controls. The postprandial triglyceride increment was greater in NIDDM with HTG (P = 0.0001) and correlated strongly in all groups with the fasting triglyceride concentration (r = 0.83; P = 0.0001). Retinyl palmitate measured in whole plasma, an Sf greater than 1000 chylomicron fraction, and an Sf less than 1000 nonchylomicron fraction was also significantly greater in NIDDM with HTG, but did not differ significantly between NIDDM with NTG and controls. In NIDDM with HTG, chylomicrons appeared to be cleared at a slower rate, as evidenced by the significantly later intersection of the chylomicron and nonchylomicron retinyl palmitate response curves (13.7 h in HTG NIDDM vs. 8.5 h in NTG NIDDM vs. 7.3 h in controls; P less than 0.01). Although fasting FFA levels were similar in all three groups, the HTG diabetic subjects had a late postprandial surge in FFAs that lasted for up to 14 h. The postprandial FFA elevation in all groups correlated with the fasting triglyceride concentration (r = 0.57; P less than 0.002) and postprandial triglyceride increment (r = 0.80; P = 0.0001). The fasting core triglyceride content of the HDL particles in NIDDM with HTG was significantly elevated compared to those in NIDDM with NTG and controls (21.0% vs. 14.0% vs. 14.1% respectively; P less than 0.05), and this increased proportionately in all groups after the meal at the expense of cholesteryl ester, the increase correlating with total plasma postprandial triglyceride increment (r = 0.51; P less than 0.01). We conclude that moderate fasting hypertriglyceridemia in NIDDM is predictive of a constellation of postprandial changes in lipids and lipoproteins that may potentiate the already unfavorable atherogenic fasting lipid profile in these subjects.

Effects of feeding fish oil on the properties of lipoproteins isolated from rhesus monkeys consuming an atherogenic diet.

This study examined plasma lipids and lipoproteins of rhesus monkeys fed fish oil incorporated into a highly atherogenic diet containing saturated fat and cholesterol. The animals were fed diets containing 2% cholesterol and either 25% coconut oil (group I), 25% fish oil/coconut oil (1:1; group II), or 25% fish oil/coconut oil (3:1; group III) for 12 months (n = 8/group). Adding menhaden fish oil to the diet increased plasma eicosapentaenoic acid and docosahexaenoic acid and decreased plasma linoleic acid in animals fed the fish oil containing diets. Plasma concentrations of all lipoprotein fractions were decreased in the fish oil groups. VLDL isolated from group I animals exhibited beta-mobility on agarose gels but the VLDL from groups II and III animals did not. The group I VLDL was more highly enriched in cholesteryl ester than was VLDL from groups II and III. Group I LDL had a small but significant increase in cholesteryl ester content compared to group III LDL. No differences in HDL composition were observed in the 3 groups. At least 6 times less apo E was recovered in VLDL, IDL, and LDL from group III animals than from group I animals. Assuming 1 molecule of apo B per lipoprotein particle, there were 50% fewer VLDL, IDL, and LDL particles in group III than in group I animals. Group III also had significantly lower molar ratios of apo E/apo B in VLDL, IDL, and LDL than did group I animals. When VLDL from all 3 groups were incubated with J774 macrophages at equal protein concentrations, only the VLDL from the group I animals stimulated cholesterol esterification. Thus, introducing fish oil into an atherogenic diet reduced the number of VLDL, IDL and LDL particles in plasma by as much as 50%, reduced the cholesteryl ester content of the circulating lipoprotein, and reduced the ability of the VLDL to stimulate cholesterol esterification in macrophages.

Apolipoprotein E and apolipoprotein E receptors modulate A beta-induced glial neuroinflammatory responses.

Large numbers of activated glia are a common pathological feature of many neurodegenerative disorders, including Alzheimer's disease (AD). Several different stimuli, including lipopolysaccharide (LPS), dibutyryl (db)cAMP, and aged amyloid-beta 1-42 (A beta), can induce glial activation in vitro, as measured by morphological changes and the production of pro-inflammatory cytokines and oxidative stress molecules. Only A beta-induced activation is attenuated by the addition of exogenous apolipoprotein E (apoE)-containing particles. In addition, only A beta also induces an increase in the amount of endogenous apoE, the primary apolipoprotein expressed by astrocytes in the brain. The functional significance of the increase in apoE appears to be to limit the inflammatory response. Indeed, compared to wild type mice, glial cells cultured from apoE knockout mice exhibit an enhanced production of several pro-inflammatory markers in response to treatment with A beta and other activating stimuli. The mechanism for both the A beta-induced glial activation and the increase in apoE appears to involve apoE receptors, a variety of which are expressed by both neurons and glia. Experiments using receptor associated protein (RAP), an inhibitor of apoE receptors with a differential affinity for the low-density lipoprotein receptor (LDLR) and the LDLR-related protein (LRP), revealed that LRP mediates A beta-induced glial activation, while LDLR mediates the A beta-induced changes in apoE levels. In summary, both an apoE receptor agonist (apoE) and an antagonist (RAP) inhibit A beta-induced glial cell activation. Thus, apoE receptors appear to translate the presence of extracellular A beta into cellular responses, both initiating glial cell activation and limiting its scope by inducing apoE, an anti-inflammatory agent.

Lipoproteins in the central nervous system.

Although the synthesis and metabolism of plasma lipoproteins are well characterized, little is known about lipid delivery and clearance within the central nervous system (CNS). Our work has focused on characterizing the lipoprotein particles present in the cerebrospinal fluid (CSF) and the nascent particles secreted by astrocytes. In addition to carrying lipids, we have found that beta-amyloid (A beta) associates with lipoproteins, including the discoidal particles secreted by cultured astrocytes and the spherical lipoproteins found in CSF. We believe that association with lipoproteins provides a means of transport and clearance for A beta. This process may be further influenced by an interaction between A beta and apoprotein E (apoE), the primary protein component of CNS lipoproteins. Specifically, we have investigated the formation and physiologic relevance of a SDS-stable complex between apoE and A beta. In biochemical assays, native apoE2 and E3 (associated with lipid particles) form an SDS-stable complex with A beta that is 20-fold more abundant than the apoE4:A beta complex. In cell culture, native apoE3 but not E4 prevents A beta-induced neurotoxicity by a mechanism dependent on cell surface apoE receptors. In addition, apoE and the inhibition of apoE receptors prevent A beta-induced astrocyte activation. Therefore, we hypothesize that the protection from A beta-induced neurotoxicity afforded by apoE3 may result from clearance of the peptide by SDS-stable apoE3:A beta complex formation and uptake by apoE receptors.

Production of small high-density lipoprotein particles after stimulation of in vivo lipolysis in hypertriglyceridemic individuals: studies before and after triglyceride-lowering therapy.

In hypertriglyceridemic states, triglyceride enrichment of high-density lipoprotein (HDL) may play an important role in decreasing the HDL cholesterol and apolipoprotein (apo) A-1 plasma concentration. We have shown previously that HDL particles are transformed into small HDLs when lipolysis is stimulated in vivo or in vitro, and this process is more marked if the HDL is triglyceride-rich. The present study was conducted to determine whether the susceptibility of HDL to transformation can be altered by triglyceride-lowering therapy in humans. Seventeen moderately hypertriglyceridemic individuals (nine with type II diabetes mellitus and eight moderately hypertriglyceridemic nondiabetic subjects) were studied before and after 3 months of triglyceride-lowering therapy with gemfibrozil. Since no significant differences in postprandial and postheparin HDL metabolism were detected between type II diabetic and nondiabetic subjects, results are reported for the two groups combined (N = 17). Fasting HDL was triglyceride-rich with a preponderance of HDL3, and became more enriched with triglycerides postprandially. Heparin administration resulted in a rapid decrease in plasma and HDL triglycerides and an increase in plasma and HDL free fatty acids (FFAs). Postheparin, there was a reduction in HDL size and an increase in the proportion of small (HDL3c) HDL particles (HDL3c constituted 7.1% +/- 1.8% of total HDL preheparin and 26.6% +/- 3.8% postheparin, P < .001). Triglyceride-lowering treatment resulted in a decrease in fasting triglycerides (-54%, P < .001) and HDL triglyceride content (-36%, P = .002), an increase in fasting HDL cholesterol (19%, P = .004), and proportionately fewer (13.2% +/- 2.1%, P < .001) HDL3c particles formed postheparin. Postheparin HDL size correlated inversely with the fasting triglyceride level (r = -.55, P < .001) and HDL triglyceride concentration (r = -.34, P = .02). These results show that the postprandial increase in triglyceride levels in hypertriglyceridemic subjects is associated with increased production of small HDL particles when lipolysis is stimulated, and that lipid-lowering therapy can contribute to favorably reduce this postprandial production of small HDL particles. Further studies are needed to clarify how these abnormalities ultimately lead to a decrease of plasma HDL cholesterol and apo A-1 in hypertriglyceridemic states.

Effect of dietary lipids on plasma activity and hepatic mRNA levels of cholesteryl ester transfer protein in high- and low-responding baboons (Papio species).

We compared the effects of dietary cholesterol, type of fat (coconut oil v corn oil), and phenotype (low low-density lipoprotein [LDL] response v high LDL response) on the plasma activity and hepatic mRNA levels of cholesteryl ester transfer protein (CETP). In a crossover design, eight high- and eight low-LDL-responding baboons were fed a series of diets with increasing amounts of cholesterol (0.05, 0.15, 0.45, and 1.35 mg/kcal) with either coconut oil or corn oil. All diets were fed for 7 weeks each. plasma and lipoprotein cholesterol concentrations, plasma lecithin:cholesterol acyltransferase (LCAT) and CETP activity, and hepatic mRNA levels for CETP and apolipoprotein (apo) A-I were measured after 6 weeks on each diet. Data were analyzed in two steps, ie, the effect of the initial change from chow to 0.05 mg cholesterol with each fat and the effect of the stepwise increase in cholesterol from 0.05 to 1.35 mg/kcal with each fat. High-responding baboons, as expected, showed a more pronounced increment in plasma LDL cholesterol at all dietary cholesterol levels, particularly with coconut oil as the dietary fat. Plasma high-density lipoprotein 2 (HDL2) and HDL3 cholesterol increased as dietary cholesterol increased on both the coconut and corn oil diets, with a greater increase in high-responding baboons than in low-responding baboons. The stepwise increase in dietary cholesterol increased plasma LCAT activity in both high- and low-responding baboons fed the coconut oil diet, but not in those fed the corn oil diet. Dietary cholesterol, regardless of type of fat, increased plasma CETP activity.(ABSTRACT TRUNCATED AT 250 WORDS)

Relationships of plasma and hepatic variables with rates of plasma low-density lipoprotein apolipoprotein B metabolism in baboons fed low- and high-fat diets.

These studies were conducted to determine relationships of plasma low-density lipoprotein (LDL) cholesterol concentrations and hepatic mRNA levels for apolipoprotein (apo) B, LDL receptor, and hepatic hydroxymethyl glutaryl coenzyme A (HMG CoA) synthase with plasma LDL apo B production and catabolic rates in baboons maintained on a low-cholesterol, low-fat chow diet and on a high-cholesterol, high-fat (HCHF) diet. Twelve baboons with LDL cholesterol levels ranging from low to high on the HCHF diet but with similar high-density lipoprotein (HDL) cholesterol levels were selected from a colony of selectively bred pedigreed baboons. LDL apo B turnover and hepatic mRNA concentrations for apo B, LDL receptor, and HMG CoA synthase were measured on a chow diet and again on a HCHF diet fed for 14 weeks. LDL apo B fractional catabolic rates decreased and production rates increased on the HCHF diet. Hepatic mRNA concentrations for apo B were not affected by the HCHF diet. Hepatic LDL receptor and HMG CoA synthase mRNA concentrations decreased on the HCHF diet as compared with the chow diet. LDL apo B fractional catabolic rate was negatively correlated with plasma cholesterol, LDL cholesterol, LDL apo B, and LDL apo B production and positively correlated with hepatic LDL receptor and HMG CoA synthase mRNA concentrations and with plasma LDL triglyceride to cholesterol ratio on the chow diet but not on the HCHF diet. LDL apo B production was positively correlated with plasma cholesterol, LDL cholesterol, and LDL apo B on the HCHF diet and negatively correlated with LDL triglyceride to cholesterol ratio on both chow and HCHF diets.(ABSTRACT TRUNCATED AT 250 WORDS)

Atherosclerosis and apoprotein E. An enigmatic relationship.

In this article, we consider the role of apoprotein E in lipoprotein metabolism and especially in the metabolism of potentially atherogenic lipoproteins. Particular consideration has been given to three features of apoprotein E involvement in lipid cell interactions. Evidence implicating free cholesterol as a mediator of apoprotein E biosynthesis in cholesterol-loaded macrophages is presented. Experiments pointing to apoprotein E as the ligand promoting the interaction of beta-very-low-density lipoprotein (beta-VLDL) with macrophages are summarized. Finally, we describe the influence of fat and cholesterol fed to rhesus monkeys and baboons on the generation of hepatogenous (from isolated liver perfusates) VLDL enriched in cholesterol ester and apoprotein E. These hepatic VLDLs, none of which exhibits beta-electrophoretic mobility, promote cholesterol esterification in macrophages in proportion to their apoprotein E content. The complex role of apoprotein E in the genesis and reversal of atherosclerosis is briefly discussed.