Hyperthyroidism influences the distribution and apolipoprotein A composition of the high density lipoproteins in man

Hyperthyroidism has a different influence on the major high density lipoprotein (HDL) components cholesterol, apoprotein (apo) A-I, and apo A-II. To characterize in greater detail the alterations induced by hyperthyroidism within the HDL subclasses, we investigated HDL distribution and composition in 11 hyperthyroid women before and during treatment. The plasma concentrations of total cholesterol, HDL cholesterol, phospholipids, apo A-I, and apo B were decreased when the patients were hyperthyroid compared with the values during treatment. Apo A-II and apo C-III levels were only slightly lower in the hyperthyroid state. Triglyceride and apo E concentrations did not change significantly during therapy. Analysis of lipoprotein subclasses separated by isopycnic ultracentrifugation revealed 1) marked decreases in low density lipoprotein (LDL) cholesterol, phospholipids, and apo B; 2) less pronounced reductions in the very low density lipoprotein (VLDL) lipid and apo B concentrations; and 3) a consistent decrease in the HDL2b (density, 1.063-1.100 g/ml) fraction in the hyperthyroid patients. The reduction in HDL2b mass was associated with lower concentrations of HDL2b cholesterol, phospholipids, and apo A-I. The HDL2b apo A-II levels remained constant during treatment. Hyperthyroidism, therefore, modified the apo A composition of the HDL2b particles and resulted in a decreased molar apo A-I to apo A-II ratio within HDL2b. Further analysis of HDL particles differing in their apo A composition; i.e. HDL particles containing apo A-I only [(A-I)HDL] or containing both apo A-I and A-II [(A-I + A-II)HDL], by immunological procedures suggested that hyperthyroidism influenced the apo A content of HDL2b mainly by changing the proportions of (A-I)HDL and (A-I + A-II)HDL and the amount of apo A-I associated with (A-I)HDL. Treatment reversed the preferential decrease in (A-I)HDL within the HDL2b subclass. The particle sizes within HDL subfractions, measured by polyacrylamide gradient gel electrophoresis, were similar in the untreated and treated patients. Consequently, the decreased mass of apo A-I and lipids within HDL2b in the hyperthyroid patients could be attributed to a reduced number of identically sized particles within this fraction. These data demonstrate that the thyroid hormones are important regulators of HDL metabolism through their influence on the concentration and distribution of apo A-I.     

The effect of moderate alcohol intake on serum apolipoprotein A-I-containing lipoproteins and lipoprotein (a).

Two main types of lipoprotein particles are identified within high-density lipoprotein (HDL): those containing both apolipoprotein (apo) A-I and apo A-II (Lp A-I:A-II) and those containing only apo A-I (Lp A-I). To study the effects of prolonged moderate alcohol intake on apo A-I-containing lipoproteins in serum, 60 g/d of ethanol was administered to 10 healthy male volunteers (age, 27 to 45 years) during 3 weeks. The drinking period was preceded and followed by an abstinence period of 3 weeks. The HDL3 cholesterol level increased by 17% (P less than .01) and decreased by 22% (P less than .001) on and off alcohol, respectively. The HDL2 cholesterol increased by 17% (P = NS) during ethanol intake and decreased by 14% during the following abstention (P less than .01). The serum concentration of apo A-I increased by 17% (P less than .001) during drinking and came back to the starting level after 2 weeks of abstention. Ethanol intake caused an increase in the serum levels of both Lp A-I and Lp A-I:A-II, the former explaining one third of the total increase of apo A-I. The Lp (a) concentration decreased by 33% (P less than .05) during the first week of ethanol intake, but increased back to the starting level until the end of drinking. These data suggest that the increment of the antiatherogenic Lp A-I may be one beneficial effect provided by ethanol with respect to coronary heart disease.     

INAUGURAL ARTICLE by a Recently Elected Academy Member:Dramatically decreased high density lipoprotein cholesterol, increased remnant clearance, and insulin hypersensitivity in apolipoprotein A-II knockout mice suggest a complex role for apolipoprotein A-II in atherosclerosis susceptibility

Apolipoprotein (apo) A-II is the second most abundant apolipoprotein in high density lipoprotein (HDL). To study its role in lipoprotein metabolism and atherosclerosis susceptibility, apo A-II knockout mice were created. Homozygous knockout mice had 67% and 52% reductions in HDL cholesterol levels in the fasted and fed states, respectively, and HDL particle size was reduced. Metabolic turnover studies revealed the HDL decrease to be due to both decreased HDL cholesterol ester and apo A-I transport rate and increased HDL cholesterol ester and apo A-I fractional catabolic rate. The apo A-II deficiency trait was bred onto the atherosclerosis-prone apo E-deficient background, which resulted in a surprising 66% decrease in cholesterol levels due primarily to decreased atherogenic lipoprotein remnant particles. Metabolic turnover studies indicated increased remnant clearance in the absence of apo A-II. Finally, apo A-II deficiency was associated with lower free fatty acid, glucose, and insulin levels, suggesting an insulin hypersensitivity state. In summary, apo A-II plays a complex role in lipoprotein metabolism, with some antiatherogenic properties such as the maintenance of a stable HDL pool, and other proatherogenic properties such as decreasing clearance of atherogenic lipoprotein remnants and promotion of insulin resistance.     

Dose-dependent regulation of high-density lipoprotein metabolism with rosuvastatin in the metabolic syndrome

BACKGROUND: Low plasma concentration of high-density lipoprotein (HDL) cholesterol is a risk factor for cardiovascular disease and a feature of the metabolic syndrome. Rosuvastatin has been shown to increase HDL cholesterol concentration, but the mechanisms remain unclear. METHODS AND RESULTS: Twelve men with the metabolic syndrome were studied in a randomized, double-blind, crossover trial of 5-wk therapeutic periods with placebo, 10 mg/d rosuvastatin, or 40 mg/d rosuvastatin, with 2-wk placebo washout between each period. Compared with placebo, there was a significant dose-dependent increase in HDL cholesterol, HDL particle size, and concentration of HDL particles that contain apolipoprotein A-I (LpA-I). The increase in LpA-I concentration was associated with significant dose-dependent reductions in triglyceride concentration and LpA-I fractional catabolic rate, with no changes in LpA-I production rate. There was a significant dose-dependent reduction in the fractional catabolic rate of HDL particles containing both apolipoprotein A-I and A-II (LpA-I:A-II), with concomitant reduction in LpA-I:A-II production rate, and hence no change in LpA-I:A-II concentration. CONCLUSIONS: Rosuvastatin dose-dependently increased plasma HDL cholesterol and LpA-I concentrations in the metabolic syndrome. This could relate to reduction in plasma triglycerides with remodeling of HDL particles and reduction in LpA-I fractional catabolism. The findings contribute to understanding mechanisms for the HDL-raising effect of rosuvastatin in the metabolic syndrome with implications for reduction in cardiovascular disease.     

High-density apolipoprotein A-I and A-II kinetics in relation to regional adiposity

High-density lipoprotein (HDL) cholesterol and apolipoprotein (apo) A-I concentrations decrease with increasing central adiposity. The present study investigated possible mechanisms for these effects by examining the relationship between body mass index, regional adiposity, and HDL apo A-I and A-II metabolism. Fifteen sedentary men and 10 male endurance athletes aged 22 to 44 served as subjects. HDL apo A-I and A-II metabolism was examined using 125I-labeled autologous HDL. Chest and thigh skinfold thickness and the ratio of chest to thigh skinfold thickness were used as indices of regional adiposity. The relationship of adiposity to HDL metabolism was examined using correlational and multiple regression analysis. In both subject groups, the fractional catabolic rate of apo A-I and A-II increased with increasing chest skinfold thickness and chest to thigh skinfold ratio (.43 < r2 < .66). This effect was partially independent of triglyceride or HDL cholesterol concentrations. Apo A-I and A-II fractional catabolic rates increased with increasing body mass index only in the sedentary men. Concentrations and synthetic rates (mg.d-1.kg-1) of apo A-I and A-II were not consistently related to body mass index or regional adiposity. Peripheral adiposity assessed by thigh skinfold thickness was not correlated with any parameter of apo metabolism. We conclude that HDL apo A-I and A-II catabolism increases with increasing central adiposity.     

Separation of high density lipoprotein (HDL) using anti-apo A-I, apo A-II immuno-affinity chromatography to evaluate the effects of probucol]

An assessment has been made regarding the changes of the particles of lipoprotein A-I without A-II (Lp A-I) and lipoprotein A-I with A-II (LpA-I/A-II) which correspond to HDL subfraction isolated by the use of anti-apo A-I and A-II antibody affinity columns in order to quantitatively and qualitatively investigate the change of HDL caused by administration of probucol and pravastatin which are therapeutic drugs for hypercholesterolemia. Probucol caused significant decreases of HDL-cholesterol, plasma apo A-I/apo A-II ratio and particles larger in diameter than 10.4 nm. Comparing Lp A-I and A-I/A-II ratios with those in normolipidemic controls and the ratios before and after administration of probucol, the decrease of LpA-I ratio was found to be remarkable after prolonged administration of probucol, and it was presumed that the decrease of HDL cholesterol by prolonged administration reflects the decrease of LpA-I particles more than the decrease of LpA-I/A-II. On the other hand, no significant change was seen in HDL cholesterol, plasma apo A-I/apo A-II ratio or HDL particle size in the pravastatin group. It is considered essential to observe HDL from the aspect of apoprotein, which plays an important role in the metabolism of lipoprotein, in the assessment of the anti-atherogenic activity of HDL cholesterol in future. In other words, it is necessary to analyze the change of HDL from the aspect of Lp A-I and Lp A-I/AII and investigate their respective metabolisms and roles.     

Preliminary report: kinetic studies on the modulation of high-density lipoprotein, apolipoprotein, and subfraction metabolism by sex steroids in a postmenopausal woman

To investigate the effects of estrogens and androgens on the metabolism of high density lipoproteins (HDL) and low density lipoproteins (LDL), a normolipidemic postmenopausal woman was studied under the following conditions: (1) during supplementation with ethinyl estradiol (0.06 mg/d); (2) without sex steroid therapy; (3) during treatment with stanozolol, an androgenic, anabolic steroid (6 mg/d). During these manipulations HDL and LDL cholesterol levels fluctuated widely but reciprocally: during estrogen supplementation HDL increased while LDL decreased; during stanozolol HDL-C decreased while LDL-C increased. Simultaneous changes in post-heparin plasma hepatic triglyceride lipase activity paralleled those of LDL (and opposed those of HDL), decreasing with estrogen and increasing with stanozolol. During all three phases, autologous 125I-HDL turnover studies disclosed similarities between HDL2 and apolipoprotein A-I metabolism and between HDL3 and apolipoprotein A-II metabolism. In the untreated state the residence times of HDL2 and apo A-I were only half those of HDL3 and apo A-II. During estrogen treatment HDL2 and apo A-I, residence times were selectively prolonged, coming to resemble those of HDL3 and apo A-II, which remained unchanged. By contrast, during stanozolol treatment HDL3 and apo A-II residence times were selectively reduced, coming to resemble those of HDL2 and apo A-I, which remained unchanged. Apo A-I levels increased on estrogen and decreased on stanozolol, while apo A-II remained stable. Hence, estrogen increased HDL primarily by retarding the catabolism of the HDL2 subfraction rich in apo A-I, whereas stanozolol decreased HDL by accelerating the catabolism of HDL3, relatively rich in apo A-II.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparison of the effects of triphasic oral contraceptives with desogestrel or levonorgestrel on apolipoprotein A-I-containing high-density lipoprotein particles.

Recent observations suggest that the risk of coronary artery disease (CAD) is associated with both the level and composition of the two major populations of apolipoprotein (apo)-defined high-density lipoprotein (HDL) particles: those containing both apo A-I and apo A-II [Lp(AI,AII)] and those containing apo A-I without apo A-II [Lp(AI)]. While sex hormones are known to affect HDL, their influence on these apo-defined HDL particles is not known. We have determined the effects of two triphasic oral contraceptive (OC) formulations on these HDL particles in healthy normolipidemic women aged 21 to 35 years. The formulations contain comparable quantities of ethinyl estradiol (EE) and either desogestrel (DG), a minimally androgenic progestin, or levonorgestrel (LN), a more androgenic progestin. Lipid and lipoprotein levels were measured during the third week of the normal menstrual cycle and the sixth month of OC use. The DG/EE formulation significantly increased total cholesterol (C) 15%, triglyceride (TG) 99%, phospholipid (PL) 17%, apo A-I 28%, apo A-II 34%, apo B 21%, very-low-density lipoprotein cholesterol (VLDL-C) 238%, HDL-C 20%, and HDL3-C 28% (P < .02 to .005, n = 11), but not low-density lipoprotein cholesterol (LDL-C). The LN/EE formulation also increased total C 15%, TG 33%, apo A-I 15%, HDL3-C 21% (P < .05, n = 10), apo B 30% (P < .005), and, additionally, LDL-C 19% (P < .05). Both formulations increased Lp(AI,AII) (DG/EE, 34%, P < .005; LN/EE, 24%, P < .01). These changes reflected comparable increases of small (7.0 to 8.2 nm) and medium (8.2 to 9.2 nm) particles in the LN/EE group and a predominant increase of medium-sized particles in the DG/EE group. Also, in the LN/EE group but not the DG/EE group, there were fewer large (9.2 to 11.2 nm) particles. Lp(AI) increased only in the DG/EE group (25%, P = .075) and was due to the presence of more large particles. The level of Lp(AI) did not change in the LN/EE group, but the lipid/A-I ratio of these particles was lower (P = .012) and there were more small particles. Thus, triphasic OC formulations with progestins of different androgenicity had different effects on VLDL, LDL, and the level and composition of HDL particles with and without apo A-II, possibly reflecting estrogen/progestin/androgen balance. Estrogen dominance increases both Lp(AI,AII) and Lp(AI) and favors large Lp(AI) particles, while progestin/androgen dominance increases only Lp(AI,AII) and favors small particles. Because of the importance of HDL in the arterial wall physiology, OC formulations with different estrogen and progestin content may affect arterial wall health to a different extent.     

Apolipoprotein A-I containing lipoproteins in coronary artery disease

At least 2 main types of lipoprotein particles are identified within HDL. Those which contain apo A-I and apo A-II (LpA-I:A-II) and those which contain apo A-I but not apo A-II (LpA-I). This study was designed to elucidate to what degree the HDL cholesterol decrease observed in coronary artery disease affects these 2 types of lipoprotein particles. Concentrations of LpA-I:A-II and LpA-I were measured in plasma from 100 normolipidemic male subjects with angiographically defined coronary artery disease (CAD(+)) or without CAD (CAD(-)) and from 50 control subjects, matched for age. CAD(+) subjects had significantly lower levels of HDL cholesterol, total apo A-I, and LpA-I than controls. When compared to CAD(-) subjects, only their levels of HDL cholesterol and LpA-I were found lower. In both cases (CAD(+) vs CAD(-) and CAD(+) vs controls), LpA-I levels were decreased while LpA-I:A-II levels were unchanged. Even, when the levels of their total plasma lipids and lipoproteins are normal, atherosclerotic patients are characterized by a different distribution of apo A-I between LpA-I and LpA-I:A-II. These data support the view that LpA-I might represent the "antiatherogenic" fraction of HDL.     

Relationship between plasma phospholipid transfer protein activity and HDL subclasses among patients with low HDL and cardiovascular disease

Low levels of high density lipoproteins (HDL) are associated with an increased risk for premature cardiovascular disease. The plasma phospholipid transfer protein (PLTP) is believed to play a critical role in lipoprotein metabolism and reverse cholesterol transport by remodeling HDL and facilitating the transport of lipid to the liver. Plasma contains two major HDL subclasses, those containing both apolipoproteins (apo) A-I and A-II, Lp(A-I, A-II), and those containing apo A-I but not A-II, Lp(A-I). To examine the potential relationships between PLTP and lipoproteins, plasma PLTP activity, lipoprotein lipids, HDL subclasses and plasma apolipoproteins were measured in 52 patients with documented cardiovascular disease and low HDL levels. Among the patients, plasma PLTP activity was highly correlated with the percentage of plasma apo A-I in Lp(A-I) (r=0.514, p<0.001) and with the apo A-I, phospholipid and cholesterol concentration of Lp(A-I) (r=0.499, 0.478, 0.457, respectively, p≤0.001). Plasma PLTP activity was also significantly correlated with plasma apo A-I (r=0.413, p=0.002), HDL cholesterol (r=0.308, p=0.026), and HDL₂ and HDL₃ cholesterol (r=0.284 and 0.276, respectively, p<0.05), but no significant correlation was observed with Lp(A-I, A-II), plasma cholesterol, triglycerides, or apo B, very low density lipoprotein cholesterol or low density lipoprotein cholesterol. These associations support the hypothesis that PLTP modulates plasma levels of Lp(A-I) particles without significantly affecting the levels of Lp(A-I, A-II) particles.     

Apolipoprotein A-II,HDL metabolism and atherosclerosis

Apolipoprotein (Apo) A-I and apo A-II are the major apolipoproteins of HDL. It is clearly demonstrated that there are inverse relationships between HDL-cholesterol and apo A-I plasma levels and the risk of coronary heart disease (CHD) in the general population. On the other hand, it is still not clearly demonstrated whether apo A-II plasma levels are associated with CHD risk. A recent prospective epidemiological (PRIME) study suggests that Lp A-I (HDL containing apo A-I but not apo A-II) and Lp A-I:A-II (HDL containing apo A-I and apo A-II) were both reduced in survivors of myocardial infarction, suggesting that both particles are risk markers of CHD. Apo A-II and Lp A-I:A-II plasma levels should be rather related to apo A-II production rate than to apo A-II catabolism. Mice transgenic for both human apo A-I and apo A-II are less protected against atherosclerosis development than mice transgenic for human apo A-I only, but the results of the effects of trangenesis of human apo A-II (in the absence of a co-transgenesis of human apo A-I) are controversial. It is highly suggested that HDL reduce CHD risk by promoting the transfer of peripherical free cholesterol to the liver through the so-called 'reverse cholesterol transfer'. Apo A-II modulates different steps of HDL metabolism and therefore probably alters reverse cholesterol transport. Nevertheless, some effects of apo A-II on intermediate HDL metabolism might improve reverse cholesterol transport and might reduce atherosclerosis development while some other effects might be deleterious. In different in vitro models of cell cultures, Lp A-I:A-II induce either a lower or a similar cellular cholesterol efflux (the first step of reverse cholesterol transport) than Lp A-I. Results depend on numerous factors such as cultured cell types and experimental conditions. Furthermore, the effects of apo A-II on HDL metabolism, beyond cellular cholesterol efflux, are also complex and controversial: apo A-II may inhibit lecithin-cholesterol acyltransferase (LCAT) (potential deleterious effect) and cholesteryl-ester-transfer protein (CETP) (potential beneficial effect) activities, but may increase the hepatic lipase (HL) activity (potential beneficial effect). Apo A-II may also inhibit the hepatic cholesteryl uptake from HDL (potential deleterious effect) probably through the SR-BI depending pathway. Therefore, in terms of atherogenesis, apo A-II alters the intermediate HDL metabolism in opposing ways by increasing (LCAT, SR-BI) or decreasing (HL, CETP) the atherogenicity of lipid metabolism. Effects of apo A-II on atherogenesis are controversial in humans and in transgenic animals and probably depend on the complex effects of apo A-II on these different intermediate metabolic steps which are in weak equilibrium with each other and which can be modified by both endogenous and environmental factors. It can be suggested that apo A-II is not a strong determinant of lipid metabolism, but is rather a modulator of reverse cholesterol transport.     

Effects of switching statins on lipid and apolipoprotein ratios in the MERCURY I study

BACKGROUND: Lipid ratios are clinically useful markers of coronary artery disease (CAD) risk. The effects of rosuvastatin, atorvastatin, simvastatin, and pravastatin on lipid ratios were investigated in the Measuring Effective Reductions in Cholesterol Using Rosuvastatin TherapY (MERCURY) I trial. METHODS: This trial was conducted in 3140 hypercholesterolemic patients with CAD, atherosclerosis, type 2 diabetes mellitus, or a 20% 10-year risk for CAD. Patients were randomized to rosuvastatin 10 mg, atorvastatin 10 or 20 mg, simvastatin 20 mg, or pravastatin 40 mg for 8 weeks; all patients except those receiving rosuvastatin 10 mg either were switched to rosuvastatin 10 or 20 mg or remained on initial treatment for 8 more weeks. RESULTS: At 8 weeks, reductions in total cholesterol (TC):high-density lipoprotein cholesterol (HDL-C), low-density lipoprotein cholesterol:HDL-C, non-HDL-C:HDL-C, and apolipoprotein (apo) B:apo A-I ratios with rosuvastatin 10 mg were significantly greater than those with atorvastatin 10 mg, atorvastatin 20 mg, simvastatin 20 mg, and pravastatin 40 mg (P<0.0001 for all). At week 16, switching to rosuvastatin 10 mg from atorvastatin 10 mg, simvastatin 20 mg, and pravastatin 40 mg and to rosuvastatin 20 mg from atorvastatin 20 mg produced significantly greater reductions in all lipid ratios (P< or =0.0001 for all). Switching to rosuvastatin 10 mg from atorvastatin 20 mg produced significantly greater reductions in TC:HDL-C (P<0.025) and apo B:apo A-I (P<0.01). CONCLUSIONS: Rosuvastatin 10 mg reduces lipid ratios more than equivalent and higher doses of other statins; switching to equal or lower doses of rosuvastatin produces significantly improved reductions in lipid ratios.     

Diverging effects of cholestyramine on apolipoprotein B and lipoprotein Lp(a). A dose-response study of the effects of cholestyramine in hypercholesterolaemia

Nineteen hypercholesterolaemic patients were randomly treated with either 16 or 8 g cholestyramine with a changeover after 6 weeks for a second 6-week period. During a third consecutive 6-week period all patients received 4 g cholestyramine daily. The low density lipoprotein (LDL) cholesterol and triglyceride concentrations decreased significantly (- 11%, - 21% and - 26% for LDL cholesterol on 4, 8 and 16 g, respectively) with a dose-response effect. However, the increase from 8 g to 16 g only caused a modest additional reduction of the lipid levels. The serum concentration of apolipoprotein (apo) B was correlated to the LDL cholesterol and decreased similarly in a dose-response fashion. However, the average reduction of apo B was less pronounced (- 4%, - 13% and - 17% on 4, 8 and 16 g of cholestyramine, respectively) resulting in a significant change of the apo B/LDL cholesterol ratio during treatment. There was a significant increase of the high density lipoprotein (HDL) cholesterol concentration, which was similar at all dose levels. Also, the apo A-I concentration in serum increased significantly but the relative decrease was less pronounced than that of HDL cholesterol, causing a significant decrease of the apo A-I/HDL cholesterol ratio. The apo A-II concentration in serum was unchanged or slightly decreased and the apo A-I/apo A-II ratio increased significantly.     

Plasma apolipoprotein A-I, A-II, B, E and C-III containing particles in men with premature coronary artery disease

Lipoprotein (Lp) cholesterol and apolipoproteins (apo) A-I and B levels have been shown to be better markers for the presence of coronary artery disease than total cholesterol. In this study, we determined the plasma levels of lipoprotein particles containing apo A-I only (LpA-1), apo A-I and A-IL (LpA-I:A-1I), apo B and C-III (LpB:C-III) and apo B and E (LpB:E) in 145 patients with coronary artery disease (mean age ± SD, 51 ± 7 years) and 135 healthy control men (mean age 49 ± 11 years). Patients with CAD had lower high density lipoprotein (HDL) cholesterol and apo A-I levels and higher triglycerides and apo B levels than controls. In patients with CAD, LpA-I (0.341 ± 0.093 vs. 0.461 ± 148 g/1) and LpA-1:A-II (0.694 ± 0.171 vs. 0.899 ± 0.148 g/1) were lower, whereas LpB:E (0.372 ± 0.204 vs. 0.235 ± 0.184 g/1) were higher than in controls (cases vs. controls, all P < 0.005). No significant differences were observed for LpB:C-III (0.098 ± 0.057 vs. 0.107 ± 0.061 g/1, p = 0.235) particles. Discriminant analysis indicates that LpA-II:A-I, LpE:B, LpA-I, and triglycerides best differentiate between cases and controls. Plasma apo C-III (0.027 ± 0.008 vs. 0.036 ± 0.020 g/1) and E (0.040 ± 0.015 vs. 0. 055 ± 0.029 g/1) were lower in the CAD group (P < 0.001). The finding that apo C-III and E levels are lower in the CAD patients relate to the fact that in our patients, HDL particles are the main carriers of apo E and C-III and that in addition to HDL-cholesterol, the protein component of HDL particles are reduced in CAD. We conclude that apo B, LpB:E but not LpB:C-III containing particles are increased in patients with CAD and that apo A-I containing particles, with or without apo A-II are reduced in patients with CAD. In addition, HDL-cholesterol and associated apolipoproteins (A-I, A-11, C-III and E) are reduced in CAD.     

Randomized dose-response study of rosuvastatin in Japanese patients with hypercholesterolemia

Rosuvastatin is a novel statin that has been shown to produce large dose-dependent reductions in low-density lipoprotein cholesterol (LDL-C) in Western hypercholesterolemic patients. Rosuvastatin dose response was assessed in a randomized, double-blind phase II trial in which 112 Japanese patients with fasting LDL-C > 160 and < 220 mg/dl and triglycerides < 300 mg/dl received placebo or rosuvastatin 1, 2.5, 5, 10, 20, or 40 mg once daily for 6 weeks. LDL-C change from baseline showed a linear dose response (p < 0.0001 for slope of regression line) over the rosuvastatin dose range, with each doubling of dose producing an additional 5.12% reduction. Mean reductions (least-squares mean percentage change from baseline from ANOVA) in LDL-C were 35.8% to 66.0% and significantly different from placebo at all doses (p < 0.0001). Linear dose response was also observed for total cholesterol (TC) and apolipoprotein (apo) B, but not for triglycerides (TG), high-density lipoprotein cholesterol (HDL-C), or apo A-I or A-II. Mean changes at 6 weeks were - 25.5 to - 45.1% for TC, - 16.0 to - 26.2% for TG, + 7.5 to + 12.8% for HDL-C, - 31.9 to - 57.8% for apo B, + 5.5 to + 10.0% for apo A-I, and + 0.4 to + 8.1% for apo A-II. Rosuvastatin was well tolerated. Although there was some suggestion of increased frequency of treatment-related adverse events at higher doses, there were no clear dose relationships in safety parameters. Only one patient withdrew from the study because of a treatment-related adverse event. No patients had clinically significant elevations in liver transaminases or creatine kinase. Rosuvastatin produces good dose-related reductions in LDL-C and beneficial changes in other lipid fractions in Japanese hypercholesterolemic patients and is well tolerated.     

Opposite effects of plasma from human apolipoprotein A-II transgenic mice on cholesterol efflux from J774 macrophages and Fu5AH hepatoma cells

Overexpression of human apolipoprotein A-II (hapo A-II) in transgenic mice (hAIItg mice) induced marked hypertriglyceridemia and low levels of plasma high density lipoprotein (HDL) with a high hapo A-II content. We sought to determine whether cholesterol efflux to plasma and HDL from these mice would be affected. In the Fu5AH cell system, plasma from hAIItg mice induced a markedly lower cholesterol efflux than did control plasma, in accordance with the dependence of efflux on HDL concentration. Moreover, HDLs from hAIItg mice were less effective acceptors than were control HDLs. In the J774 macrophage cell system, pretreatment with cAMP, which upregulates ATP binding cassette transporter 1, induced a marked increase in the efflux to hAIItg plasma as well as to purified hapo A-I and hapo A-II, whereas it had no effect on cholesterol efflux to control plasma. A strong positive correlation was established between percent cAMP stimulation of efflux and plasma hapo A-II concentration. The cAMP stimulation of efflux to hAIItg mouse plasma may be linked to the presence of pre-beta migrating HDL containing hapo A-II. Thus, despite lower HDL and apolipoprotein A-I contents, the increased ability of plasma from hAIItg mice to extract cholesterol from macrophage-like cells may have an antiatherogenic influence.     

Metabolic effects of a biphasic oral contraceptive preparation containing ethinyloestradiol and desogestrel on serum lipoproteins and apolipoproteins

The effect of the administration of a biphasic oral contraceptive containing ethinyloestradiol and desogestrel on the distribution and composition of serum lipoproteins was studied in a group of 17 healthy female volunteers. The women were treated for a period of 6 months and compared with a control group of ten untreated volunteers. The serum lipoproteins were fractionated by density gradient ultracentrifugation into very low density lipoproteins (VLDL), low density lipoproteins (LDL), and into the high density lipoprotein (HDL) subfractions 2 and 3 (HDL2, HDL3). Lipids and apolipoproteins were assayed in the various fractions. No modification of either the lipid or apolipoprotein concentrations was observed in the control group. In the treated group, sex hormone-binding globulin (SHBG) and cortisol-binding globulin (CBG), and the serum content of cholesterol, triglycerides, HDL-cholesterol, apolipoprotein A-I (apo A-I) and apolipoprotein A-II (apo A-II) increased significantly after 3 and 6 months. The cholesterol and apolipoprotein B (apo B) content of VLDL increased significantly after 3 and 6 months, but remained unchanged in LDL. High density lipoprotein subfraction 2 (HDL2)-cholesterol was significantly increased after 3 and 6 months but apo A-I only after 6 months. Since apo A-II did not change, the apo A-I/A-II ratio increased significantly after 6 months of treatment. In the HDL3 fraction, the apo A-I increase was significant after 3 and 6 months, while the increase of apo A-II was significant after 6 months. The apo A-I/A-II ratio remained constant.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vivo metabolism of HDL, apo A-I, and lp A-I, and function of HDL--a clinical perspective.

Serum levels of high density lipoprotein cholesterol (HDL-C) are inversely correlated with coronary heart disease (CHD). Kinetic studies indicate that the mechanism for the variation in HDL levels associated with various pathophysiologic states includes changes in the fractional catabolic rate (FCR) and/or the synthesis rate of HDL and its major proteins apolipoprotein (apo) A-I and apo A-II. The antiatherogenic effects of HDL are thought to be mainly due to its role in reverse cholesterol transport. HDL is an assembly of heterogeneous particles. HDL enlarges when it takes up cellular cholesterol, and shrinks when HDL cholesterol ester (CE) is transfered to low density lipoprotein (LDL) and very low density lipoprotein (VLDL) particles. The functional ability of HDL (to remove cellular cholesterol) has drawn considerable attention. The fractional esterification rate of cholesterol in HDL (FER(HDL)) has been established as a functional assay of HDL, and reflects the size of HDL particles. We investigated the clinical significance of FER(HDL) and its relationship to the quantity of HDL. FER(HDL) values were inversely correlated with levels of HDL-C and large lipoprotein containing apo A-I (LpA-I). The association between FER(HDL) and CHD changed with serum HDL-C levels: increased FER(HDL) values significantly increased the risk of CHD when serum HDL-C levels were low, while there was no such relationship when HDL-C levels were high. We concluded that the combination of HDL-C levels and FER(HDL) is a stronger indicator of CHD than either the HDL-C level (quantitative measure of HDL) or FER(HDL) (functional measure of HDL) alone.     

High-density lipoprotein particles in octogenarians

High-density lipoprotein (HDL) particles exhibit considerable heterogeneity, specifically in apolipoprotein (apo) composition. Thus, apo A-I, the major protein of HDL, is present in two types of particles: one species contains both apo A-I and apo A-II (Lp A-I/A-II) while in the other (Lp A-I), apo A-II is absent. We used the hypothesis that octogenarians, who survived periods in life when the incidence of coronary heart disease (CHD) is very high, have several protective factors. We compared HDL-cholesterol (HDL-C), HDL2-cholesterol (HDL2-C), HDL3-cholesterol (HDL3-C), apo A-I, and apo A-II in octogenarians and younger control subjects smoking less than 10 cigarettes/d and not taking drugs known to affect lipid metabolism. Using a new procedure, we also compared the levels of Lp A-I and Lp A-I/A-II. The cholesterol content of total HDL was similar in octogenarian and control (38 +/- 8 years) men while HDL2-C was higher and HDL3-C, apo A-I, and A-II were lower in octogenarian than in control men. In women, the level of HDL-C and apo A-I was similar in premenopausal and octogenarian subjects but higher in postmenopausal women than in octogenarians, while HDL2-C and apo A-II were similar in the three groups. In contrast, HDL3-C was higher in the two groups of control women (premenopausal and postmenopausal) than in octogenarians. However, Lp A-I was significantly elevated in octogenarian men and women (men: 61 +/- 14 mg/dL; women: 70 +/- 14 mg/dL) by comparison with younger control subjects (men: 48 +/- 12 mg/dL; premenopausal women: 53 +/- 11 mg/dL; postmenopausal women: 63 +/- 19 mg/dL).(ABSTRACT TRUNCATED AT 250 WORDS)     

Characteristics of human lipoproteins isolated by selected-affinity immunosorption of apolipoprotein A-I.

We have isolated high density lipoproteins (HDL) from human serum by a new strategy, selected-affinity immunosorption, avoiding perturbation from ultracentrifugation or polyanion precipitation. The principle of this strategy is to utilize a subpopulation of monospecific antibodies directed against apolipoprotein A-I (apo A-I), which was preselected for dissociation under mild conditions of elution. Particles containing more than 90% of the apo A-I contained in serum were isolated uncontaminated by any other serum proteins. The immunoaffinity columns have been cycled over 300 times without apparent diminution in capacity. The apo A-I-containing particles sequestered from serum by immunosorption were more polydisperse in diameter and contained more protein than in ultracentrifugally isolated HDL. They also contained minor apolipoproteins that were not observed in ultracentrifuged HDL. Furthermore, the apo A-I-containing particles had different electrophoretic mobilities from those of ultracentrifugally isolated HDL when run under nondenaturing conditions in polyacrylamide gels. The apo A-I-containing particles isolated by our procedure separate into discrete bands similar to the subspecies visualized when whole serum is subjected to electrophoresis, whereas ultracentrifuged HDL migrate as two broad featureless zones. This suggests that selected affinity immunosorption does not subject the lipoproteins to structural disruption like that which occurs during ultracentrifugation. The principle of selected-affinity immunosorption should be of widespread utility in the isolation of fragile biological complexes.