Modulated serum activities and concentrations of paraoxonase in high density lipoprotein deficiency states.

Paraoxonase is a high density lipoprotein (HDL) associated enzyme with a hypothesised role in the protection of low density lipoproteins (LDL) from oxidative stress. The present study examined paraoxonase in several genetically distinct HDL deficiency states. Despite reduction or even absence of detectable HDL, enzyme activity was present in sera from A-I-Pisa, A-I-Helsinki, A-I-Milano and Tangier patients. Both enzyme activities and peptide concentrations were modulated (reduced) but specific activities were broadly similar to controls, suggesting an impact on peptide concentration rather than an inhibition of enzyme activity. Despite the absence of HDL in A-I-Pisa and Tangier subjects, there was no association of paraoxonase with very low density lipoproteins or LDL. Paraoxonase function is maintained in HDL deficient states. It implies that certain HDL-associated anti-atherogenic processes may not be entirely compromised by HDL deficiency. This has important implications for the cardiovascular risk associated with modulated HDL concentrations.

Postprandial responses of plasma lipids and lipoproteins in subjects with apoA-I(Lys107-->0).

Subjects with apoA-I(Lys107-->0) deletion mutation have reduced levels of plasma HDL cholesterol, apoA-I, apoA-II and Lp(AI:AII). In the present study were describe the postprandial responses of apoA-I(Lys107-->0) subjects (n=6) to the ingestion of a fat rich meal compared to the responses of their unaffected family members (n=6). The postprandial plasma triglyceride responses were comparable in the two groups of subjects. Plasma postprandial HDL cholesterol levels fell in both groups; patients (0.89+/-0.05-0.76+/-0.06 mmol/l, P=0.0032) and control subjects (1.32+/-0.25-1.18+/-0.21 mmol/l; P=0.0022). HDL2 cholesterol levels tended to rise, but the changes were not significant. By contrast, in both patients and control subjects, the HDL3 cholesterol levels fell; patients (0.52+/-0.15-0.37+/-0.11 mmol/l, P=0.0068) and control subjects (0.63+/-0.10-0.49+/-0.08 mmol/l, P=0.0078), respectively. In both patients and control subjects the plasma HDL2 mass increased in response to the fat meal; patients (94.7+/-37.3-114.3+/-28.8 mg/dl, P=0.0397) and control subjects (142.1+/-32.8-168.1+/-29.8 mg/dl, P=0.0298), whereas HDL3 mass decreased; patients (162.3+/-36.8-131.4+/-28.9 mg/dl, P=0.0251) and control subjects (185.5+/-34.1-161.1+/-29.0 mg/dl, P=0.0021), respectively. In control subjects the triglyceride levels increased in both HDL2 (0.10+/-0.06-0.17+/-0.06 mmol/l; P=0.0005) and to a lesser extent in HDL3 (0.10+/-0.03-0.12+/-0.02 mmol/l, P=0.0017). In patients, triglyceride levels in both HDL subclasses remained unchanged. Changes in the concentration of Lp(AI) in HDL2 and HDL3 were comparable in the two groups of subjects. The Lp(AI:AII) concentration in HDL2 remained unchanged in the patients, but increased in control subjects (change+27%. P=0.0026). Consequently, the 20% difference at baseline in the concentration of Lp(AI:AII) in HDL2 between the patients and control subjects increased postprandially to 45% (P=0.0240). The Lp(AI:AII) concentration in HDL3 decreased in both groups, but the changes were non-significant. Our findings show that in postprandial state, no accumulation of triglycerides in HDL subclasses occurs in patients with apoA-I(Lys[107]-->0) and that these patients appear to lack the ability to respond to fat feeding by increasing the Lp(AI:AII) concentration in HDL2.

Effects of dietary cholesterol on plasma lipoproteins and their subclasses in IDDM patients.

To compare the effects of dietary cholesterol supplementation in insulin-dependent diabetic (IDDM) patients and normal subjects, 10 male IDDM patients in good glycaemic control (HbA1c 7.3+/-0.9%) (mean+/-SD) and normal plasma lipid levels, and 11 control male subjects of similar age, body mass index and lipid plasma levels underwent a double blind, cross-over, sequential study. Cholesterol supplementation of 800 mg/day or placebo were given for consecutive periods of 3 weeks. The concentration of plasma total cholesterol increased significantly with the dietary cholesterol supplementation compared to placebo in IDDM patients by 6% (p < 0.05) and in control subjects by 9% (p < 0.05). No changes were observed in the concentration of plasma triglycerides in either group. The LDL cholesterol level increased by 12% (p < 0.01) in patients and by 7% (p < 0.05) in control subjects. In patients plasma HDL cholesterol concentration remained the same, while in control subjects it tended to increase after cholesterol supplementation (from 1.14+/-0.26 to 1.23+/-0.27 mmol/l, p = 0.06). During the cholesterol intake period the mean concentration of LDL1, LDL2 and LDL3 subclasses in patients showed a significant increase by 21.0 (p < 0.05), 20.4 (p < 0.001) and 11.1% (p < 0.05), respectively, resulting in an 18.0% increase in mean total LDL mass (p < 0.001) without major changes in LDL composition. In the control subjects the changes in the concentrations of LDL subclasses during cholesterol intake were less and not significant. In the IDDM patients the cholesterol intake did not affect the concentration or composition of HDL subclasses or total HDL mass. In contrast, in control subjects cholesterol intake increased the mean concentration of HDL2a by 12.2.% (p < 0.05) and this increase was significantly different if compared to changes obtained in the patients. In conclusion, compared to normal subjects, in IDDM patients, dietary cholesterol intake increased the LDL particle mass significantly and had no positive effect on HDL.

Subjects with ApoA-I(Lys107-->0) exhibit enhanced fractional catabolic rate of ApoA-I in Lp(AI) and ApoA-II in Lp(AI with AII).

Our purpose was to examine HDL metabolism in a Finnish kindred with a 3-bp deletion in the apolipoprotein (apo) A-I gene, resulting in a deletion of Lys107 in the mature apoA-I. Patients with this mutation [apoA-I(Lys107-->0)] have reduced plasma HDL cholesterol and lipoprotein (AI with AII) [Lp(AI w AII)] concentrations, but not Lp(AI) levels, compared with unaffected family members. Using primed constant infusions of [5,5,5-2H3]leucine, we determined the residence time (RT) and absolute production rate (APR) of apoA-I and apoA-II entering plasma in two subpopulations of HDL particles: [Lp(AI) and Lp(AI w AII)] in three patients heterozygous for apoA-I(Lys107-->0) and in seven healthy control subjects. In patients, the mean RT of apoA-I in Lp(AI) (3.75+/-1.68 days) was less than half that observed in control subjects (8.01+/-2.51 days, P<.05). The mean RT of apoA-I in Lp(AI w AII) was also lower in patients than in control subjects, but differences were not statistically significant (4.72+/-2.42 versus 6.50+/-2.19 days). The mean RT of apoA-II in Lp(AI w AII) was significantly lower in patients (5.24+/-1.65 days) than in control subjects (9.64+/-3.57 days, P<.05). The APR of apoA-I into Lp(AI) was twofold higher in patients (5.9+/-2.1 mg x kg(-1) x d(-1)) than in control subjects (2.5+/-0.9, P<.05). The APRs of apoA-I and apoA-II into Lp(AI w AII) were similar in patients and control subjects. Our results are consistent with the concept that patients heterozygous for the apoA-I(Lys107-->0) mutation have enhanced fractional catabolism of apoA-I and apoA-II in both HDL subspecies, especially in Lp(AI), and an increase in apoA-I production only into Lp(AI), which may be compensatory. Therefore, only their Lp(AI w AII) levels are decreased.

Responses of HDL subclasses, Lp(A-I) and Lp(A-I:A-II) levels and lipolytic enzyme activities to continuous oral estrogen-progestin and transdermal estrogen with cyclic progestin regimens in postmenopausal women.

Seventy postmenopausal women took part in the study. Subjects received either continuous oral 17 beta-estradiol 2 mg/day combined with norethisterone acetate 1 mg/day (E2/NETA, Kliogest) or transdermal treatment consisting of 28 day cycles with patches delivering 17 beta-estradiol 50 micrograms/day (Estraderm) combined with cyclic medroxyprogesterone acetate 10 mg/day (E2/MPA, Provera), on days 17-28. At baseline the serum lipid and lipoprotein concentrations, composition and concentrations of high density lipoprotein (HDL) subclasses, lipoprotein (Lp)(AI) and Lp(A-I:A-II) levels were comparable in the two groups. In the E2/NETA group, after 12 months hormone replacement therapy (HRT), the HDL2 cholesterol concentration decreased by 17% (P < 0.01) and the HDL3 cholesterol remained unchanged. The concentrations of HDL2b, HDL2a and HDL3a were reduced by 30, 26 and 15%, respectively, P < 0.001, and the cholesterol:triglyceride ratio decreased significantly in all HDL subclasses. Apolipoprotein (apo) A-I concentration decreased by 5% (P < 0.05), but apo A-II, Lp(A-I) and Lp(A-I:A-II) concentrations remained unchanged. In the E2/MPA group the HDL2 and HDL3 cholesterol levels were both reduced by 6% (P < 0.05) and the HDL3a, HDL3b and HDL3c concentrations decreased by 14, 12 and 17% during the E2/MPA phase compared with baseline (P < 0.01). No major changes in the composition of HDL subclasses occurred in the E2 MPA group during treatment. The apo A-I and Lp(A-I) levels were not changed, but apo A-II and Lp(A-I:A-II) concentrations decreased by 8 and 5%, P < 0.001 and P < 0.05, respectively. At 12 months the postheparin plasma hepatic lipase (HL) activity decreased only in the E2/NETA group (by 12%, P < 0.05). The cholesteryl ester transfer protein (CETP) activity was not affected by either HRT regimen. The results of our study show that the 2 HRT regimens have multiple effects on HDL particles and HRT induced changes in HDL are not associated with changes in activities of lipolytic enzymes or CETP.

In vivo metabolism of apo A-I and apo A-II in subjects with apo A-I(Lys107-->0) associated with reduced HDL cholesterol and Lp(AI w AII) deficiency.

Apolipoprotein A-I (apo A-I) and apolipoprotein A-II (apo A-II) represent 80 90% of the protein content of high density lipoproteins (HDL). Previously we have identified a Finnish family with an apo A-I variant (Lys107-->0) associated with reduced plasma HDL cholesterol level and decreased lipoprotein (Lp)(AI w AII) concentration compared to unaffected family members. To determine the in vivo metabolism of apo A-I and apo A-II in the carriers of apo A-I (Lys107-->0) variant we radioiodinated normal apo A-I with 125I and apo A-II with 131I and compared the kinetic data of two heterozygous apo A-I(Lysl07-->0) patients (HDL cholesterol leves 0.31 and 0.69 mmol/l) to that of eight normolipidemic, healthy control subjects. Plasma radioactivity curves of 125I-labelled normal apo A-I of the patients demonstrated accelerated clearance of apo A-I compared to control subjects. In the two patients the fractional catabolic rates (FCR) of apo A-I were 0.347/day and 0.213/day, respectively, while the mean FCR of apo A-I of the control subjects was 0.151 +/- 0.041/day. Similarly, the plasma decay curves of the 131I-labelled apo A-II showed more rapid clearance of apo A-II in the two patients than in control subjects. The FCR of apo A-II in the two patients were 0.470/day and 0.234/day, while the mean FCR of apo A-II in control subjects was 0.154 +/- 0.029/day. The calculated production rates of apo A-I were similar in patients and in control subjects, and the production rates of apo A-II were significantly higher in patients than in control subjects. Our results show that the Lp(AI w AII) deficiency in patients with the apo A-I(Lys107-->0) is associated with increased fractional catabolic rates of normal apo A-I and apo A-II, while the production rates of these apolipoproteins are normal (apo A-I) or slightly increased (apo A-II).

Impact of gender on the metabolism of apolipoprotein A-I in HDL subclasses LpAI and LpAI:AII in older subjects.

The behavior of apolipoprotein (apo) A-I in lipoprotein (Lp) AI and LpAI:AII was studied in 11 postmenopausal females and 11 males matched for plasma triglyceride and total cholesterol levels. Subjects consumed a baseline diet [35% fat (14% saturated, 15% monounsaturated, and 7% polyunsaturated), 15% protein, 49% carbohydrate, and 147 mg cholesterol/1000 kcal] for 6 weeks before the start of the kinetic study. At the end of the diet period, using a primed-constant infusion of [5,5,5-2H3]leucine, residence times (RT) and secretion rates (SR) of apoA-I were determined in 2 subpopulations of high-density lipoprotein (HDL) particles, LpAI and LpAI:AII. Plasma total cholesterol, low-density lipoprotein cholesterol, and triglyceride concentrations were similar in males and females. The mean plasma HDL cholesterol concentration in males (1.14 +/- 0.23 mmol/L; mean +/- SD) was lower than in females (1.42 +/- 0.18 mmol/L; P =. 0034). Similarly, the mean plasma concentration of apoA-I in males (130 +/- 21 mg/dL) was lower than that in females (150 +/- 19 mg/dL; P = .0421). The RT of apoA-I in either LpAI or LpAI:AII was similar between men and women. Despite the higher plasma apo A-I levels in female compared with male subjects, total apoA-I and apoA-I in LpAI and LpAI:AII pool sizes were similar between the two groups, attributable to the lower body weight of the female subjects. The mean SR of total apoA-I in males (8.5 +/- 2.7 mg.kg-1.d-1) was 22% lower than in females (10.9 +/- 2.3 mg.kg-1.d-1; P = .0389). The SR of both apoA-I in LpAI and LpAI:AII was lower in males than females, although the differences did not reach statistical significance. These data suggest that the difference observed in HDL cholesterol concentration between males and females is attributable to SR of apoA-I and not the catabolic rate.

Different effects of continuous oestrogen-progestin and transdermal oestrogen with cyclic progestin regimens on low-density lipoprotein subclasses.

Seventy-five postmenopausal women were randomly allocated to receive either continuous oral 17 beta-oestradiol 2 mg day-1 and norethisterone acetate 1 mg day-1 (E2/NETA) or transdermal treatment consisting of 28-day cycles with patches delivering 17 beta-oestradiol 50 micrograms day-1 combined with oral cyclic medroxyprogesterone acetate 10 mg day-1, on days 17-28 (E2/MPA). At baseline, the plasma lipid and lipoprotein concentrations, composition and concentrations of low-density lipoprotein (LDL) subclasses (LDL1, LDL2 and LDL3) isolated by density-gradient ultracentrifugation were similar in the two groups. The post-heparin plasma hepatic lipase activity (HL) correlated inversely with the percentage of total LDL found in LDL1 (buoyant LDL) and directly with the percentage of LDL found in LDL3 (dense LDL). After 12 months of hormone replacement therapy (HRT), the total and LDL-cholesterol concentration of the E2/ NETA group decreased by 14% and 17% respectively (P < 0.001), while in the E2/MPA group these parameters remained unchanged. The lowering of LDL-cholesterol in the E2/NETA group was a consequence of a significant reduction of the large, buoyant LDL particles (LDL1) from 103 mg dL-1 to 60 mg dl-1 (P < 0.001) and of a decrease of cholesterol content of LDL particles in the major LDL subclass, LDL2. In the E2/MPA group, the concentration of LDL1 decreased, but less than in the oral group. In both groups, a significant increase in the concentration of the LDL3 subclass was observed, indicating an overall shift to denser LDL particles. After 12 months, the post-heparin plasma HL activity decreased only in the E2/NETA group (by 12%). The inverse correlation between post-heparin plasma HL activity and LDL1 persisted in both groups, but the direct correlation between HL and LDL3 vanished in the E2/NETA group and subsided in the E2/MPA group. Our results indicate that HRT has multiple effects on LDL subclasses and suggest that these changes cannot be explained by changes in HL activity.

Hyperinsulinemia and insulin resistance are associated with multiple abnormalities of lipoprotein subclasses in glucose-tolerant relatives of NIDDM patients. Botnia Study Group.

We studied the subclasses of plasma lipoproteins in normolipidemic, glucose-tolerant male relatives of noninsulin dependent diabetic patients (NIDDM), who represented either the lowest (n = 14) or the highest (n = 18) quintiles of fasting plasma insulin. The higher plasma triglyceride level in the high insulin group (1.61 mmol/l vs. 0.87 mmol/l, P < 0.001) was due to multiple differences in triglyceride-rich lipoproteins. The concentrations of larger VLDL1, smaller VLDL2 particles, and IDL particles were 3.8-fold, 2.5-fold, and 1.5-fold higher, respectively, in the high insulin group than in the low insulin group (P < 0.01 or less). In addition, hyperinsulinemic subjects had VLDL1, VLDL2, and IDL particles enriched in lipids and poor in protein. The lower plasma HDL cholesterol level in the high insulin group (1.20 mmol/l vs. 1.44 mmol/l, P < 0.01) compared to the low insulin group was a consequence of a 27% reduction of HDL2a concentration (P < 0.05) and a significantly reduced percentage of cholesterol in HDL3a, HDL3b, and HDL3c subclasses. On the other hand, the percentages of triglycerides in HDL2b, HDL2a, HDL3a, and HDL3b subclasses were 76%, 79%, 61%, and 50% higher, respectively, in the high insulin group than in the low insulin group (P < 0.01 or less). In the combined group, the concentration of VLDL1 and VLDL2 correlated positively with the concentrations of LDL2 and LDL3 and negatively with HDL2b and HDL2a subclasses (P < 0.05 or less). In conclusion, normolipidemic, glucose-tolerant but hyperinsulinemic relatives of NIDDM patients have qualitatively similar lipoprotein abnormalities as NIDDM patients. These abnormalities are not observed in insulin-sensitive relatives, suggesting that they develop in concert with insulin resistance.

A compound heterozygote for hepatic lipase gene mutations Leu334-->Phe and Thr383-->Met: correlation between hepatic lipase activity and phenotypic expression.

We have characterized the molecular basis for familial hepatic lipase (HL) deficiency in a Finnish family. In the propositus, the HL deficiency results from compound heterozygosity for two rare HL gene mutations, a previously unknown missense mutation designated L334F and the previously reported T383M mutation. These mutations were introduced into human HL cDNA by site-directed mutagenesis and the constructs expressed in COS-1 cells. In the homogenate of COS-1 cell transfected with the L334F mutant cDNA, a high amount of inactive protein accumulated. In the media of L334F transfected cells, 30% of the wild type activity and 80% of wild type mass were detected. The lysates of COS-1 cells transfected with the T383M mutant cDNA contained 39% of wild type HL activity and 34% of wild type HL mass. In the media of COS-1 cells transfected with the T383M cDNA construct, 50% of wild type HL mass but only 6% of wild type activity was present. The single amino acid substitutions present in L334F and T383M are therefore sufficient to severely affect the HL enzyme. These defects explain the HL-deficient phenotype of the individual carrying the two mutations. The lipoprotein phenotype associated with compound heterozygosity for L334F and T383M mutations is characterized by a slight increase in the buoyant low density lipoprotein (LDL) fraction and an increase in the light high density lipoprotein (HDL) fractions, HDL2a and HDL2b. These results demonstrate that lipoprotein changes occurring in HL deficiency are difficult to identify and support the hypothesis that HL is important in HDL remodeling and metabolism in vivo.

ApoA-IHelsinki (Lys107-->0) associated with reduced HDL cholesterol and LpA-I:A-II deficiency.

A Finnish kindred with premature coronary heart disease and decreased HDL cholesterol levels was identified as having an apoA-I variant, apoA-I (Lys107-->0), caused by a 3-bp deletion of nucleotides 1396 through 1398 in exon 4 of the apoA-I gene. These subjects (n = 10) were heterozygous for this mutation. The mean serum HDL cholesterol concentration (26.7 +/- 9.7 mg/dL) of affected family members was 36%, lower than that of unaffected family members (P < .05). Mean serum apoA-I and apoA-II concentrations in heterozygotes were reduced by 18% and 22%, respectively, compared with normal family members (P < .05). In heterozygotes the mean concentration of lipoprotein containing both apoA-I and apoA-II (LpA-I:A-II) was 31% lower than in those with normal apoA-I (P < .001), while the mean level of lipoproteins containing apoA-I without apoA-II was similar in the two groups. HDL density-gradient ultracentrifugation showed a lack of HDL2 and small dense HDL3 in heterozygotes compared with unaffected family members. The HDL particle size distribution, as analyzed by nondenaturing gradient gel electrophoresis of heterozygotes, revealed one major peak at 8.0 to 9.7 nm, a minor peak at 7.8 to 8.5 nm, and an absence of HDL2b and HDL2a peaks. These latter peaks were observed in unaffected family members. Serum levels of LDL cholesterol, triglycerides, VLDL, IDL, and LDL subclasses were similar in the two groups. However, in heterozygotes the cholesterol-to-triglyceride ratios in VLDL2, LDL1, LDL3, HDL2b, HDL2a, and HDL3a were 8% to 54% lower than in unaffected family members (P < .05). Cholesteryl ester transfer protein activity in heterozygotes was reduced by 25% compared with unaffected family members (P < .05), while the plasma lecithin:cholesterol acyltransferase (LCAT) activity did not differ between heterozygotes and unaffected family members. The ability of isolated variant apoA-I to serve as a cofactor for LCAT in vitro did not differ from that of normal apoA-I. Our data are consistent with the concept that a low HDL cholesterol level in subjects heterozygous for the apoA-IHelsinki mutation (Lys107-->0) having normal LCAT activity is a consequence of decreased concentration of LpA-I:A-II particles and of a smaller size and reduced cholesterol content of HDL particles.

Hyperlipidemia accelerates allograft arteriosclerosis (chronic rejection) in the rat.

The relevance of hyperlipidemia in allograft arteriosclerosis (chronic rejection) is controversial. Isolated hypercholesterolemia induced with cholesterol-cholic acid-diet (CC-diet) or hypertriglyceridemia induced with glycerol-diet (G-diet) had no or only a protective effect on aortic allograft arteriosclerosis in the rat. Combined hyperlipidemia with both diets (CC+G-diet) enhanced allograft arteriosclerosis by doubling intimal thickness and cellularity (P < .05) but had no effect on host arteries. Compared with normolipidemic controls, the CC+G-diet increased the total serum cholesterol concentration 4.8-fold (P < .05). Levels of VLDL2 and IDL increased 4.8- and 18.1-fold (P < .05), and their composition changed from triglyceride-rich to cholesterol-rich lipoproteins in an atherogenic direction. The CC+G-diet had no effect on the structure of inflammation in the vascular wall. Instead, significant lipid deposits were observed, and the expression of epidermal growth factor and insulin-like growth factor-1 was significantly elevated in the vascular wall. Thus, elevations in VLDL and IDL lipoprotein levels and their cholesterol content associate with the generation of allograft arteriosclerosis in rats. Deposition of lipids in the vascular wall seems to induce local synthesis of certain growth factors, which ultimately leads to the induction of smooth muscle cell replication.

LDL subclasses in IDDM patients: relation to diabetic nephropathy.

To answer the question whether the elevation of LDL-cholesterol in IDDM patients with incipient and established diabetic nephropathy is accompanied by changes in LDL size or composition, we studied distribution of LDL particles in 57 normoalbuminuric [AER 7 (1-9) micrograms/min, median and range], in 46 microalbuminuric [AER 50 (20-192) micrograms/min] and in 33 proteinuric [AER 422 (233-1756) micrograms/min] IDDM patients as well as in 49 non-diabetic control subjects with normoalbuminuria. The three diabetic groups were matched for duration of diabetes and glycaemic control. The mean particle diameter of the major LDL peak was determined by nondenaturing gradient gel electrophoresis. Composition and density distribution of LDL were determined in the subgroups of each patient group by density gradient ultracentrifugation. Normoalbuminuric IDDM patients had larger LDL particles than non-diabetic control subjects (260 A vs 254 A, p < 0.05). LDL particle diameter was inversely correlated with serum triglycerides in all groups (p < 0.05 for normoalbuminuric and p < 0.001 for other groups). Triglyceride content of LDL was higher in three IDDM groups compared to control group (p < 0.05). The elevation of LDL mass in microalbuminuric and proteinuric IDDM groups compared to normoalbuminuric IDDM group (p < 0.05 for both) was mainly due to the increment of light LDL (density 1.0212-1.0343 g/ml). There were no significant changes in the density distribution or composition of LDL between the three diabetic groups. In conclusion the increase of LDL mass without major compositional changes suggests that the elevation of LDL in incipient and established diabetic nephropathy is primarily due to the increased number of LDL particles.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of gemfibrozil on high density lipoprotein subspecies in non-insulin dependent diabetes mellitus. Relations to lipolytic enzymes and to the cholesteryl ester transfer protein activity.

Twenty patients (18 men, 2 women) with non-insulin dependent diabetes mellitus (NIDDM) were randomized to receive either gemfibrozil 1200 mg daily or placebo for 3 months in a double-blind study. The effect of gemfibrozil on plasma HDL subfraction distribution was studied with sequential and density gradient ultracentrifugation and in gradient gel electrophoresis. The concentrations of apo A-I, apo A-II, Lp A-I and Lp A-I:A-II particles were measured. Postheparin plasma lipoprotein lipase (LPL) and hepatic lipase (HL) activities and plasma cholesteryl ester transfer protein (CETP) activities were also determined. Gemfibrozil increased the concentration of HDL cholesterol (P < 0.01), which was due to the rise of HDL3 cholesterol (+16%), while in the placebo group these values remained unchanged. Gemfibrozil increased the concentrations of apo A-I(+12.6%, NS), apo A-II (+28.2%, P < 0.01) and Lp A-I:A-II particles (+21.6%, P < 0.06) but there were no changes in the placebo group. Neither gemfibrozil nor placebo had any effect on the concentration of Lp A-I particles. As determined by density-gradient ultracentrifugation, gemfibrozil increased the concentration of cholesterol in the most dense HDL fractions (mean density 1.193 g/ml, +22%, P < 0.05 and mean density 1.158 g/ml, +19.3%, P < 0.05). In gradient gel electrophoresis, the gemfibrozil-induced elevations of the cholesterol and protein were most pronounced in the HDL3a (8.8-8.2 nm) region. Gemfibrozil increased LPL and HL activities by 14.7% (P < 0.05) and by 18.8% (P < 0.01), respectively, while in the placebo group LPL and HL activities remained unchanged. Plasma CETP activity was also increased during gemfibrozil treatment while in the placebo group it remained unchanged. We conclude that gemfibrozil causes multiple changes in plasma HDL metabolism. The gemfibrozil-induced elevation of HDL3 and dense HDL subpopulations may reflect the concerted action of LPL, HL and CETP on plasma HDL metabolism.

Effects of gemfibrozil on low-density lipoprotein particle size, density distribution, and composition in patients with type II diabetes.

OBJECTIVE: To study the effects of gemfibrozil treatment on LDL particle size, density distribution, and composition in NIDDM patients. RESEARCH DESIGN AND METHODS: We performed LDL analyses on 16 NIDDM patients with stable glycemic control. They were randomly allocated to receive either gemfibrozil (n = 8) or a placebo (n = 8) for 3 mo in a double-blind study. The LDL particle size distribution and the particle diameter of the major LDL peak were measured with nondenaturing polyacrylamide gradient gel electrophoresis. The density distribution and composition of LDL were determined with the density gradient ultracentrifugation method. RESULTS: In the gemfibrozil group the mean serum TG concentration decreased by 38%, HDL cholesterol concentration increased by 10%, and LDL cholesterol concentration by 17% (P < 0.05). During gemfibrozil therapy the mean particle diameter of the major LDL peak increased from 244 to 251 A (P < 0.05), whereas in the placebo group the mean LDL particle diameter remained unchanged. We found an inverse correlation between the changes of serum TG and the particle diameters of the major LDL peak (r = 0.85, P < 0.01). Gemfibrozil produced a shift in the LDL density distribution toward lower density. The mean peak density decreased from 1.0371 to 1.0345 g/ml because of a significant rise in the light LDL concentration from 141.0 to 183.2 mg/dl (P < 0.05), whereas the concentration of dense LDL had a tendency to decrease. In the placebo group the LDL density distribution did not change. Gemfibrozil increased the CE-to-TG ratio in LDL core lipids by 27% (P < 0.05); otherwise, the LDL composition was only slightly affected. CONCLUSIONS: The results indicate gemfibrozil-induced changes in LDL properties in NIDDM patients are similar to those previously reported in nondiabetic individuals and are related to changes in serum TG level.

Effects of lovastatin on high-density lipoprotein subfractions in hypercholesterolemic patients with peripheral vascular disease.

The effects of lovastatin treatment on high-density lipoprotein subfractions (HDL2 and HLD3) were investigated in 34 patients with severe peripheral vascular disease and type IIa or type IIb hyperlipoproteinemia by use of a density gradient ultracentrifugation method. Lovastatin therapy caused greater percentage changes in HDL2 than in HDL3. In HDL2 the increases of cholesterol, total lipid, apolipoprotein AI (apoAI) and apolipoprotein AII (apoAII) concentrations were 23% (p < 0.05), 28% (p < 0.01), 24% (p < 0.01) and 11% (p < 0.01), respectively, in subjects with the type IIa phenotype. In patients with the type IIb phenotype the corresponding increases were 42% (p < 0.01), 44% (p < 0.01), 38% (p < 0.01) and 21% (p < 0.05), respectively. The apoAI/apoAII weight ratio in HDL2 rose by 11% and by 13% in type IIa and type IIb patients, respectively. The present results suggest that during lovastatin treatment the slight increase in serum HDL-cholesterol concentration was due, not to cholesterol enrichment by high-density lipoproteins, but more probably to an increase of the number of HDL particles. The observed changes were more pronounced in type IIb than in type IIa patients.

Effects of lovastatin and gemfibrozil on high-density lipoprotein subfraction density and composition in patients with familial hypercholesterolemia.

The effects of gemfibrozil and lovastatin treatment on composition and hydrated density distribution of high-density lipoprotein (HDL) were studied in 21 patients with heterozygous familial hypercholesterolemia with the use of HDL density gradient ultracentrifugation. At baseline the patients with familial hypercholesterolemia had a markedly reduced or missing HDL2 subfraction and their HDL3 was more dense with reduced content of cholesteryl ester and increased content of triglyceride compared with HDL of control subjects with normal lipid values. Gemfibrozil and lovastatin caused primarily similar alterations in HDL components in HDL2 and HDL3 subfractions. Both agents increased apolipoprotein AI and apolipoprotein AII concentrations significantly in HDL2, whereas the apolipoprotein changes in HDL3 were relatively smaller. The difference between the effects of these two agents was related to the HDL lipid composition. Gemfibrozil increased the cholesterol concentrations of HDL2 and HDL3 (p less than 0.05 for both), and lovastatin caused significant increases in HDL2 (p less than 0.05) and HDL3 phospholipids (p less than 0.01). The observed similarity of qualitative alterations in HDL subfractions produced by these two agents in patients with familial hypercholesterolemia differs from those reported in other types of hyperlipidemia and is probably a consequence of the basic abnormalities in HDL that are characteristic of familial hypercholesterolemia.

Abnormalities of low density lipoproteins in normolipidemic type II diabetic and nondiabetic patients with coronary artery disease.

The characteristics of low density lipoproteins (LDL) of ten non-insulin-dependent diabetic (NIDDM) and ten nondiabetic patients with coronary artery disease (CAD) were investigated and compared to LDL of ten NIDDM patients without CAD and ten healthy persons. All subjects had LDL cholesterol below 160 mg/dl and serum triglycerides below 200 mg/dl. The mean LDL particle size and particle distribution profiles were analyzed by using nondenaturing polyacrylamide gradient gel electrophoresis. The LDL composition and hydrated density distribution were investigated by using density gradient ultracentrifugation. Both NIDDM and nondiabetic CAD patients tended to have larger LDL particles than NIDDM patients without CAD and healthy subjects. The increase of LDL particle size of CAD patients was due to marked enrichment of triglycerides (TG) in their LDL. The percentage content of TG in LDL of NIDDM patients with CAD was 14.5% and in LDL of nondiabetic CAD patients 13.4% compared with 7.9% in LDL of NIDDM patients without CAD and 7.2% in normal-LDL (P less than 0.05 or less between either CAD group and NIDDM without CAD or normals). The LDL TG/apolipoprotein (apo) B weight ratio was significantly higher in both CAD groups compared with LDL of the two groups without CAD (0.70 and 0.68 vs. 0.38 and 0.34, respectively, P less than 0.05, P less than 0.05 and P less than 0.01, P less than 0.01). The LDL total lipid to apoB weight ratio was similar in all four groups. Consistent with this, the hydrated density distributions of LDL in the four groups were similar, the average peak densities being 1.0346 g/ml, 1.0331 g/ml, 1.0331 g/ml, and 1.0331 g/ml, respectively. The findings of this study demonstrate that normolipidemic patients with CAD may have marked abnormalities in th eir LDL composition and these anomalies are present in both diabetic and nondiabetic patients.

Differential low density lipoprotein hydrated density distribution in female and male patients with familial hypercholesterolemia.

The low density lipoprotein (LDL) hydrated density distribution and composition was studied by using density gradient ultracentrifugation in 26 heterozygous familial hypercholesterolemia patients (FH) (13 females and 13 males) and 28 normolipidemic subjects (14 females and 14 males). The average peak hydrated density of LDL mass in female FH patients was 1.0301 g/ml as compared with 1.0333 g/ml in male FH patients (P less than 0.01) indicating less dense LDL particles in females. A similar difference in the average peak density was observed between normolipidemic females and males (1.0315 g/ml and 1.0342 g/ml, respectively; P less than 0.001). The FH males had a significantly lower mean triglyceride (Tg) content in their LDL (4.8%), lower Tg to apolipoprotein B (Apo B) weight ratio (0.24) and higher cholesteryl ester (CE) to triglyceride weight ratio (9.11) in comparison to FH females (Tg 6.2%; Tg/Apo B 0.31; CE/Tg 5.99), P less than 0.05 in all. Similar LDL composition differences were also observed between normolipidemic males and females.