Apo B-containing lipoprotein particles in poorly controlled insulin-dependent diabetes

The goal of this study was to compare the structural and biological characteristics of apolipoprotein (apo) B-100-containing particle subfractions isolated from poorly controlled diabetic patients with insulin-dependent diabetes (IDDM), and healthy controls matched for sex, age and body mass index (BMI). Different apo B-containing particles were isolated by sequential immunochromatography and were free of apo A-I, apo A-II, apo A-IV and apo(a). Particles lipoprotein (Lp) B/C-III contained apo B and apo C-III. They were free of apo E. Particles Lp B/E contained apo B and apo E. They were free of apo C-III. Particles Lp B were devoided of apo C-III and apo E. All these particles could contain other known apolipoproteins not cited here, as for example apo C-II and/or apo C-I. The plasma levels of cholesterol, triglycerides, phospholipids, apo A-I, B-100, C-III, E, total Lp B/C-III. total Lp B/E were not different between patients and controls. The physico-chemical properties of Lp B/C-III and Lp B/E were similar in both groups. Only Lp B from patients exhibited some changes, an increase in the size and a decrease in the cholesterol and cholesteryl ester levels. The conformational properties of the lipoproteins were studied through their immunoreactivity against four different anti-apo B-100 monoclonal antibodies (MAb) for which sequential epitopes have been located on the protein, and one MAb for which the epitope is conformationally expressed. Again, minor changes were observed between patients and controls, and only a slight decrease in the immunoreactivity of the epitope encompassing amino-acid residues 405 to 539 of Lp B and of the conformationally expressed epitope of Lp B/C-III were found in patients. Nevertheless, whatever these conformational and/or physico-chemical modifications may be, they were not sufficient to induce functional alterations in the binding of the particles from the patients to the LDL-receptor of HeLa cells. This study shows that IDDM is not associated with any significant abnormalities in the apo-containing lipoprotein particles. The excessive occurrence of coronary heart disease (CHD) and other atherosclerotic vascular disease in patients with IDDM must have other causes.     

A case of symptomatic hypobetalipoproteinemia with unusual distribution of apolipoprotein E]

A case of symptomatic hypobetalipoproteinemia (hypo-beta LP) with unusual distribution of apolipoprotein E (apo E) in a 68-year-old male patient with chronic heart failure and liver cirrhosis associated with low triiodothyronine (T3) syndrome is reported. There was nothing in the family history to suggest familial hypo-beta LP. In this case, levels of apo B and low-density lipoprotein were very low, and the fraction of beta lipoprotein on polyacrylamide-gel disc electrophoresis (PAGE) was only 7%. However, the triglyceride level was normal due to the presence of chylomicron, in spite of hypocholesterolemia and hypophospholipidemia. The mid-band lipoprotein on PAGE showed that Lp (a) lipoprotein concentration was normal (18.3 mg/dl). The activities of lecithin cholesterol acyltransferase, hepatic triglyceride lipase and lipoprotein lipase (LPL) were low. The concentrations of apo C-II, apo C-III and apo E were low, while those of apo A-I and apo A-II were normal. The author recently reported that the apo C of high-density lipoprotein (HDL-apo C) was detected in alpha lipoprotein, but that HDL-apo E was detected in the near alpha 2-globulin region behind alpha lipoprotein on agarose-gel immunofixation electrophoresis. The author therefore named it alpha 2-apo E, and later found that the fraction percentage of alpha 2-apo E depends on lipolysis and is inversely correlated to the concentration of apo B.(ABSTRACT TRUNCATED AT 250 WORDS)     

Relationship between apolipoprotein C-III concentrations and high-density lipoprotein subclass distribution

High-density lipoprotein (HDL) subclasses have different antiatherogenic potentials and functional properties. This work presents our findings and discussions on their metabolic implications on apolipoprotein (apo) C-III together with other apolipoprotein levels and HDL subclass distribution profile. Apolipoprotein A-I contents of plasma HDL subclasses were quantitated by 2-dimensional gel electrophoresis coupled with immunodetection in 511 subjects. Concentrations of triglycerides and of apo B-100, C-II, and C-III were higher, whereas those of HDL cholesterol were lower, for subjects in the highest tertile of apo C-III levels group, which presented a typical hypertriglyceridemic lipid profile. Subjects in the middle and highest tertile of apo C-III levels groups had increased preβ₁-HDL, HDL_3c, HDL_3b (only in the highest tertile of apo C-III group), and HDL_3a, but decreased HDL_2a and HDL_2b contents compared with subjects in the lowest tertile of apo C-III levels group. With the elevation of apo C-III together with apo C-II levels, contents of small-sized preβ₁-HDL increased successively and significantly; but those of large-sized HDL_2b reduced successively and significantly. With a rise in apo C-III and apo A-I levels, those of preβ₁-HDL increased significantly. Moreover, subjects with high apo A-I levels showed a substantial increase in HDL_2b; on the contrary, HDL_2b declined progressively and obviously for subjects in the low apo A-I levels with the elevation of apo C-III levels. Correlation analysis illustrated that apo C-III levels were positively associated with preβ₁-HDL, preβ₂-HDL, and HDL_3a. The particle size of HDL shifted toward smaller sizes with the increase of plasma apo C-III levels, and the shift was more remarkable when the elevation of apo C-III and apo C-II was simultaneous; and besides, higher apo A-I concentrations could modify the effect of apo C-III on HDL subclass distribution profile. Large-sized HDL_2b particles decreased greatly for hypertriglyceridemic subjects who were characterized by elevated apo C-III and C-II accompanied with significantly lower apo A-I, which, in turn, blocked the maturation of HDL.     

Relationships between the responses of triglyceride-rich lipoproteins in blood plasma containing apolipoproteins B-48 and B-100 to a fat-containing meal in normolipidemic humans.

The concentration of triglyceride-rich lipoproteins containing apolipoprotein (apo) B-48 (chylomicrons) and apo B-100 (very low density lipoproteins) was measured in blood plasma of healthy young men after an ordinary meal containing one-third of daily energy and fat. Plasma obtained in the postabsorptive state and at intervals up to 12 hr after the meal was subjected to immunoaffinity chromatography against a monoclonal antibody to apo B-100 that does not bind apo B-48 and a minor fraction of apo B-100 rich in apo E. Measurements of the concentrations of components of the total and unbound triglyceride-rich lipoproteins separated from plasma by ultracentrifugation showed that about 80% of the increase in lipoprotein particle number was in very low density lipoproteins containing apo B-100 and only 20% was in chylomicrons containing apo B-48 that carry dietary fat from the intestine. The maximal increments and the average concentrations of apo B-48 and B-100 during the 12 hr were highly correlated (r2 = 0.80), suggesting that preferential clearance of chylomicron triglycerides by lipoprotein lipase leads to accumulation of hepatogenous very low density lipoproteins during the alimentary period. The composition of the bulk of very low density lipoproteins that were bound to the monoclonal antibody changed little and these particles contained about 90% of the cholesterol and most of the apo E that accumulated in triglyceride-rich lipoproteins. The predominant accumulation of very low density lipoprotein rather than chylomicron particles after ingestion of ordinary meals is relevant to the potential atherogenicity of postprandial lipoproteins.     

Defects in the low density lipoprotein receptor gene affect lipoprotein (a) levels: multiplicative interaction of two gene loci associated with premature atherosclerosis.

The lipoprotein (a) [Lp(a)] contains two nonidentical protein species, apolipoprotein (apo) B-100 and a specific high molecular weight glycoprotein, apo(a). Lp(a) represents a continuous quantitative genetic trait, the genetics of which are only poorly understood. Genetic variation at the apo(a) locus affects plasma Lp(a) levels and explains at least 40% of the variability of this trait. Lp(a) levels were found to be elevated 3-fold in the plasma from patients with the heterozygous form of familial hypercholesterolemia who have one mutant low density lipoprotein receptor gene. This elevation was not due to a higher frequency of those apo(a) types that are associated with high Lp(a) levels in familial hypercholesterolemia patients. Rather Lp(a) levels were elevated for each of the apo(a) phenotypes examined. The effects of the apo(a) and low density lipoprotein receptor genes on Lp(a) levels are not additive but multiplicative. This is a situation not commonly considered in quantitative human genetics. We conclude that Lp(a) levels in plasma may be determined by variation at more than one gene locus.     

Metabolism of apolipoproteins B-48 and B-100 of triglyceride-rich lipoproteins in normal and lipoprotein lipase-deficient humans.

The metabolism of apolipoproteins B-48 and B-100 (apo B-48 and B-100) in large triglyceride-rich lipoproteins (300 to 1500 A in diameter) has been compared in three normal subjects and two subjects with genetically determined deficiency of lipoprotein lipase. The triglyceride-rich lipoproteins were obtained from a lipoprotein lipase-deficient donor 4 hr after a fat-rich meal in order to obtain chylomicrons (containing apo B-48) and very low density lipoproteins (VLDL) (containing apo B-100), whose properties had not been modified by the action of this enzyme. The triglyceride-rich lipoproteins were labeled with 125I and injected intravenously into recipients who had fasted overnight. In normal recipients, most of the apo B-48 was removed from the blood within 15 min, and most of the apo B-100 was removed within 30 min. In the lipoprotein lipase-deficient recipients, most of the injected apo B-100 remained in the blood for more than 8 hr; removal of apo B-48 was only slightly more rapid. In all subjects, only trace amounts of either protein were found in lipoproteins more dense than 1.006 g/ml. The results indicate that (i) the removal of the apo B of both chylomicrons and large VLDL from the blood is dependent upon the hydrolysis of their component triglycerides by lipoprotein lipase, and (ii) little or no apo B-48 of chylomicrons or apo B-100 of large VLDL is converted appreciably to low density lipoproteins (LDL). Our results suggest that the reported variability of the conversion of VLDL to LDL may be related to the size and composition of the particles secreted from the liver. The rapid production of remnant particles that are removed efficiently by the liver may minimize the opportunity for further reactions leading to the formation of LDL.     

Apolipoprotein(a) size polymorphism is associated with coronary heart disease in polygenic hypercholesterolemia

BACKGROUND AND AIM: In addition to high serum cholesterol levels, various cardiovascular risk factors may be involved in the development of coronary heart disease (CHD) in hypercholesterolemic subjects. As the levels of lipoprotein(a) [Lp(a)], an important and independent cardiovascular risk factor, are high in polygenic hypercholesterolemia (PH), we investigated plasma Lp(a) levels and apolipoprotein(a) [apo(a)] phenotypes in relation to occurrence of CHD events in PH patients. METHODS AND RESULTS: Lp(a) levels and apo(a) isoforms were determined in 191 PH patients, 83 normocholesterolemic subjects with CHD, and 94 normocholesterolemic controls without CHD. Lp(a) levels were similar in the hypercholesterolemic subjects with (n=100) or without CHD (n=91): 21.4 (range 6.6-59.23) vs 18.5 (range 5.25-57.25) mg/dL (p=NS). Low molecular weight apo(a) isoforms were more prevalent (55%) in the PH patients with CHD, whereas high molecular weight apo(a) isoforms were more prevalent (62.6%) in those without CHD: this difference was significant (p<0.05). A stepwise multiple-discriminant analysis made in order to determine the independence of common cardiovascular risk factors, Lp(a) levels and low molecular weight apo(a) isoforms in predicting CHD among hypercholesterolemic subjects showed that the presence of a positive family history of CHD, smoking, age, and the presence of at least one apo(a) isoform of low molecular weight were independently associated with CHD. CONCLUSIONS: Despite high Lp(a) levels, our findings do not support the hypothesis that Lp(a) plays an independent role in determining clinical CHD in PH subjects. However, the presence of at least one low molecular weight apo(a) isoform is an independent genetic predictor of CHD in hypercholesterolemic subjects. Together with other cardiovascular risk factors, apo(a) phenotypes should be assessed to evaluate the overall CHD risk status of all subjects with high serum cholesterol levels.     

Ascorbic acid supplementation does not lower plasma lipoprotein(a) concentrations

Elevated plasma concentrations of lipoprotein(a) (Lp[a]) are associated with premature coronary heart disease (CHD). Lp(a) is a lipoprotein particle consisting of low-density lipoprotein (LDL) with apolipoprotein (apo) (a) attached to the apo B-100 component of LDL. It has been hypothesized that ascorbic acid supplementation may reduce plasma levels of Lp(a). The purpose of this study was to determine whether ascorbic acid supplementation at a dose of 1 g/day would lower plasma concentrations of Lp(a) when studied in a randomized, placebo-controlled, blinded fashion. One hundred and one healthy men and women ranging in age from 20 to 69 years were studied for 8 months. Lp(a) values at baseline for the placebo group (n = 52) and the ascorbic acid supplemented group (n = 49) were 0.026 and 0.033 g/l, respectively. The 8-month concentrations were 0.027 g/l (placebo) and 0.038 g/l (supplemented group). None of these values were significantly different from each other. In addition, no difference in plasma Lp(a) concentration was seen between the placebo and supplemented groups when only subjects with an initial Lp(a) value of > or = 0.050 g/l were analyzed. Our data indicate that plasma Lp(a) concentrations are not significantly affected by ascorbic acid supplementation in healthy human subjects.     

Lipoprotein(a) levels and apolipoprotein(a) polymorphism in type 1 diabetes mellitus: relationships to microvascular and neurological complications

To investigate plasma concentrations of lipoprotein(a) [Lp(a)] and apolipoprotein(a) [apo(a)] polymorphism in relation to the presence of microvascular and neurological complications in type 1 diabetes mellitus, 118 young diabetic patients and 127 age-matched controls were recruited. Lp(a) levels were higher in patients than in controls, but the apo(a) isoforms distribution did not differ between the two groups [higher prevalence of isoforms of high relative molecular mass (RMM) in both groups]. Microalbuminuric patients had Lp(a) levels significantly greater than normoalbuminuric patients, and normoalbuminuric patients showed higher Lp(a) levels than controls. Patients with retinopathy or neuropathy showed similar Lp(a) levels to those without retinopathy or neuropathy. No differences in apo(a) isoforms frequencies were observed between subgroups with and without complications (higher prevalence of isoforms of high RMM in every subgroup). However, among patients with retinopathy, those with proliferative retinopathy had higher Lp(a) levels and a different apo(a) isoforms distribution (higher prevalence of isoforms of low RMM) than those with non-proliferative and background retinopathy (higher prevalence of isoforms of high RMM). Our data suggest that young type 1 diabetic patients without microalbuminuria have Lp(a) levels higher than healthy subjects of the same age. Lp(a) levels are further increased in microalbuminuric patients. High Lp(a) levels and apo(a) isoforms of low RMM seem to be associated with the presence of proliferative retinopathy, but have no relation to neuropathy. Received: 23 June 1997 / Accepted in revised form: 27 November 1997     

Lipoprotein(a) and atherosclerosis

Lipoprotein(a) [Lp(a)], a lipoprotein variant, was relegated for almost 25 years to the study of a few specialists. During the past 3 to 4 years, however, there has been a tremendous upsurge of interest in Lp(a), primarily because of multidisciplinary efforts in structural and molecular biology. Findings emerging from these efforts include the following: Lp(a) represents a cholesteryl-ester, low-density-lipoprotein (LDL)-like particle with apolipoprotein (apo) B-100 linked to apo(a); apo(a) is a glycoprotein coded by a single gene locus on the long arm of chromosome 6, which has several alleles, accounting for its remarkable size polymorphism (300 to 800 kD); apo(a) size polymorphism relates to plasma levels and density distribution of Lp(a); apo(a) is strikingly similar to plasminogen; and in vitro, Lp(a), in appropriate levels, competes for some physiologic functions of plasminogen in the coagulation and fibrinolytic cascade and may thus be thrombogenic. The LDL-like properties of Lp(a) may also confer atherogenic potential, but the mechanisms underlying this atherogenicity remain to be defined. In epidemiologic studies, high plasma Lp(a) levels have been associated with an increased incidence of atherosclerotic cardiovascular disease, especially in patients less than 60 years of age. Moreover, Lp(a) has been found as an intact particle in the arterial intima, particularly in association with atherosclerotic plaque. This finding suggests that Lp(a) can transverse the endothelium, possibly by a non-receptor-mediated process, and, at the intimal level, acquire thrombogenic and atherogenic potentials. Current information justifies the need to determine plasma Lp(a) levels in patients with a history of atherosclerotic cardiovascular disease. Unfortunately, the available techniques need to be standardized. Apolipoprotein(a) exists in isoforms of different sizes, and the importance of determining apo(a) phenotypes in clinical practice remains to be established.     

Fish intake, independent of apo(a) size, accounts for lower plasma lipoprotein(a) levels in Bantu fishermen of Tanzania: The Lugalawa Study.

Plasma lipoprotein(a) [Lp(a)] levels are largely genetically determined by sequences linked to the gene encoding apolipoprotein(a) [apo(a)], the distinct protein component of Lp(a). Apo(a) is highly polymorphic in length due to variation in the numbers of a sequence encoding the apo(a) kringle 4 domain, and plasma levels of Lp(a) are inversely correlated with apo(a) size. In 2 racially homogeneous Bantu populations from Tanzania differing in their dietary habits, we found that median plasma levels of Lp(a) were 48% lower in those living on a fish diet than in those living on a vegetarian diet. Considering the relationship between apo(a) size and Lp(a) plasma concentration, we have extensively evaluated apo(a) isoform distribution in the 2 populations to determine the impact of apo(a) size in the determination of Lp(a) values. The majority of individuals (82% of the fishermen and 80% of the vegetarians) had 2 expressed apo(a) alleles. Additionally, the fishermen had a high frequency of large apo(a) isoforms, whereas a higher frequency of small isoforms was found in the vegetarians. When subjects from the 2 groups were matched for apo(a) phenotype, the median Lp(a) value was 40% lower in Bantus on the fish diet than in those on the vegetarian diet. A significant inverse relationship was also found between plasma n-3 polyunsaturated fatty acids and Lp(a) levels (r=-0.24, P=0.01). The results of this study are consistent with the concept that a diet rich in n-3 polyunsaturated fatty acids, and not genetic differences, is responsible for the lower plasma levels of Lp(a) in the fish-eating Bantus and strongly suggest that a sustained fish-based diet is able to lower plasma levels of Lp(a).     

Homozygous hypobetalipoproteinemia with spared chylomicron formation

Thirteen members of a family carrying a gene for pedigree of hypobetalipoproteinemia were analyzed for lipoprotein compositions, apolipoprotein (apo) B levels, and apo B isoforms. Judging from low density lipoprotein (LDL)-cholesterol (Chol) and apo B levels, a 75-year-old proband, a father who died of unknown fever, thrombopenia, and anemia, and his wife were heterozygous for hypobetalipoproteinemia. The proband had ataxic movement of hands and gait disturbance in later life. Three of four living siblings had extremely low levels of LDL-Chol (6 mg/dL) and LDL-apo B (2 mg/dL), and were postulated to have homozygous hypobetalipoproteinemia. Electrophoresis revealed marked deficiency of apo B-100, although trace amounts were noted in LDL. In contrast, apo B-48 was present in chylomicrons obtained after a fatty meal in the two patients with homozygous hypobetalipoproteinemia, indicating a selective deficiency of apo B-100 but not apo B-48. The defect in these patients seemingly is different from abnormal apo B-37 reported recently for a family with hypobetalipoproteinemia. Clinically, acanthocytotic red blood cells (8% to 12%), fatty liver, and low levels of serum lipid-soluble vitamins A and D were noted in homozygotes. One heterozygous sibling had 26 mg/dL LDL-Chol and 5 mg/dL LDL-apo B levels. All seven subjects in the third generation had low levels of Chol (85 to 140 mg/dL), LDL-Chol (40 to 63 mg/dL) and LDL-apo B (10 to 20 mg/dL). They also showed mild acanthocytosis (0.5% to 2%) and a decrease of fat-soluble vitamins in plasma.(ABSTRACT TRUNCATED AT 250 WORDS)     

Correlation of apolipoprotein(a) isoproteins with Lp(a) density and distribution in fasting plasma.

Lp(a) is an LDL-like lipoprotein which contains an additional apolipoprotein called apo(a). Apo(a) exhibits a significant size polymorphism and its size is inversely correlated with plasma Lp(a) levels. We investigated the distribution of different apo(a) isoproteins in lipoprotein density fractions. Fasting plasma samples were subjected to non-equilibrium density gradient ultracentrifugation. After SDS-PAGE and anti-apo(a) immunoblotting, apo(a) concentrations in individual density fractions were evaluated by densitometry. In series I, analysis of selected density fractions from 35 coronary heart disease (CHD) patients demonstrated that although most of the apo(a) was present in the Lp(a) density range, apo(a) was consistently found in both the VLDL and IDL fractions as well. In series II, density fractions from 9 normolipidemic subjects with 6 different apo(a) isoproteins were evaluated. A strong association between the size of the apo(a) isoprotein and the density of the associated Lp(a) particle was established (r = 0.976, P less than 0.001). Lp(a) densities ranged from 1.057 g/ml for the B isoprotein to 1.09 g/ml for the S5 isoprotein. Overall, 75% of the total apo(a) was detected in the Lp(a) density range (d = 1.05-1.12 g/ml), with 9% and 10% in the LDL (d = 1.019-1.05 g/ml) and HDL (d = 1.12-1.21 g/ml) fractions, respectively. VLDL contained an average of 4% of the total apo(a) in fasting normolipidemic plasma. Two hypertriglyceridemic subjects had substantially greater amounts of apo(a) in the fasting triglyceride-rich fraction. The results of this study indicate that the size of the apo(a) isoprotein strongly influences the density of its associated Lp(a) particle and that apo(a) is consistently found in the triglyceride-rich lipoproteins of fasting plasma.     

Molecular analysis of apo(a) fragmentation in polygenic hypercholesterolemia: characterization of a new plasma fragment pattern

Hypercholesterolemia is frequently associated with elevated Lp(a) levels, an independent risk factor for coronary, cerebrovascular, and peripheral vascular disease. A portion of apolipoprotein(a) [apo(a)] circulates as a series of fragments derived from the N-terminal region of apo(a). The relationship of elevated lipoprotein(a) [Lp(a)] levels to those of circulating apo(a) fragments in polygenic hypercholesterolemia is indeterminate. Therefore, plasma Lp(a) and plasma and urinary apo(a) fragment levels were measured by ELISA in 82 patients with polygenic type IIa hypercholesterolemia (low density lipoprotein cholesterol >/=4.13 mmol/L and triglycerides <2.24 mmol/L) and in 90 normolipidemic subjects. Lp(a) levels were significantly elevated in patients compared with control subjects (0.35+/-0.4 and 0.24+/-0.31 mg/mL, respectively; median 0.13 and 0.11 mg/mL, respectively; P=0.039), although apo(a) isoform distribution did not differ. Patients displayed significantly higher plasma and urinary apo(a) fragment levels than did control subjects (respective values were as follows: 4.97+/-5.51 and 2.15+/-2.57 [median 2.85 and 1.17] microg/mL in plasma, P<0.0001; 75+/-86 and 40+/-57 [median 38 and 17] ng/mg urinary creatinine in urine, P<0.0001). The ratio of plasma apo(a) fragments to Lp(a) levels was also significantly higher in patients than in control subjects (1.93+/-1.5% and 1.75+/-2.36%, respectively; P<0.0001). We conclude that increased plasma Lp(a) levels in polygenic hypercholesterolemia are associated with elevated circulating levels of apo(a) fragments but that this increase is not due to decreased renal clearance of apo(a) fragments. Furthermore, we identified a new pattern of apo(a) fragmentation characterized by the predominance of a fragment band whose size was related to that of the parent apo(a) isoform and that was superimposed on the series of fragments described previously by Mooser et al (J Clin Invest. 1996; 98:2414-2424). This new pattern was associated with small apo(a) isoforms and did not discriminate between hypercholesterolemic and normal subjects. However, this new apo(a) fragment pattern may constitute a novel marker for cardiovascular risk.     

The metabolism of apolipoproteins (a) and B-100 within plasma lipoprotein (a) in human beings

The metabolism of apolipoproteins (apo) (a) and B-100 within plasma lipoprotein (a) [Lp(a)] was examined in the fed state in 23 subjects aged 41 to 79 years who received a primed-constant infusion of [5,5,5-2H3] leucine over 15 hours. Lipoprotein (a) was isolated from the whole plasma using a lectin affinity-based method. Apolipoprotein (a) and apoB-100 were separated by gel electrophoresis, and tracer enrichment of each apolipoprotein was measured using gas chromatography/mass spectrometry. Data were fit to a multicompartmental model to determine fractional catabolic rates (FCRs) and secretion rates (SRs). The FCRs of apo(a) and apoB-100 (mean +/- SEM) within plasma Lp(a) were significantly different (0.220 +/- 0.030 pool/d and 0.416 +/- 0.040 pool/d, respectively; P < .001). Apolipoprotein (a) SR (0.50 +/- 0.08 mg/[kg per d]) was significantly lower than that of apoB-100 SR (1.53 +/- 0.22 mg/[kg per d]; P < .001) of Lp(a). Plasma concentrations of Lp(a) were correlated significantly with both apo(a) SR and apoB-100 SR (r = 0.837 and r = 0.789, respectively; P < .001) and negatively with apo(a) FCR and Lp(a) apoB-100 FCR (r = -0.547 and r = -0.717, respectively; P < .01). These data implicate different metabolic fates for apo(a) and apoB-100 within Lp(a) in the fed state. We therefore hypothesize that apo(a) does not remain covalently linked to a single apoB-100 lipoprotein but that it rather reassociates at least once with another apoB-100 particle, probably newly synthesized, during its plasma metabolism.     

Elevated triglyceride-rich lipoproteins in diabetes

The role of the intestine in cholesterol metabolism in human diabetes in unclear, although abnormalities have been demonstrated in cholesterol synthesis and absorption in diabetic animals. This study examines the relationship between fasting and post-prandial apolipoprotein B-48 in type 2 (non-insulin-dependent) diabetic and non-diabetic subjects. Eight type 2 diabetic patients and ten healthy non-diabetic control subjects were given a high-fat meal (1300 kcal), and the triglyceride-rich lipoprotein fraction was isolated by ultracentrifugation (d<1.006 g/ml) from fasting and post-prandial plasma. Apolipoprotein B-48 and apo B-100 were separated on 4%–15% gradient gels and quantified by densitometric scanning with reference to a purified low-density lipoprotein (LDL) apo B-100 preparation. Diabetic patients had significantly higher concentrations of apo B-48 and apo B-100 in both the fasting (P<0.05) and post-prandial (P<0.001) triglyceride-rich lipoprotein samples compared with non-diabetic subjects. The diabetic patients also exhibited a significantly different post-prandial profile for apo B-48 and apo B-100, with a prolonged increase and a later post-prandial peak, than the non-diabetic subjects (P<0.01). These results suggest that the raised fasting triglyceride-rich lipoproteins, often found in diabetes, are associated with apo B-48 and may be derived from increased intestinal chylomicron production. The post-prandial pattern suggests an abnormality in intestinal production as well as hepatic clearance of apo B-48 in type 2 diabetes.     

Serum lipoprotein(a) concentration and Apo(a) isoform under the condition of renal dysfunction

A serum lipoprotein(a) (Lp(a)) is an independent risk factor for cardiac events. It is well known that the patients with chronic renal failure (CRF) have a high concentration of serum Lp(a). The purpose of this study was to indicate the relationship between serum Lp(a) concentration and apoprotein(a) (apo(a)) isoforms under the condition of renal dysfunction. One-hundred thirty patients having hypertension, hyperlipidemia, diabetes mellitus and/or CRF were selected in this study. All patients were divided into two groups according to the level of serum creatinine. Serum Lp(a) concentration in the CRF patients (Cr > 2.0 mg/dl) was significantly higher than that in the controls (Cr < 1.2 mg/dl). Many CRF patients had high molecular weight (HMW)-apo(a). This study showed that the increase in HMW-apo(a) was closely accompanied by the increase in serum creatinine levels, and the serum Lp(a) concentration with HMW-apo(a) was higher according to their creatinine levels.     

Predictors of plasma lipoprotein(a) concentration in the West of Scotland Coronary Prevention Study cohort

An elevated plasma lipoprotein(a) (Lp(a)) concentration is an independent risk factor for coronary heart disease (CHD). Plasma Lp(a) levels are believed to be predominantly controlled by the APO(a) gene, which encodes the apo(a) glycoprotein moiety of the Lp(a) particle. However, other parameters in the lipoprotein profile as well as co-existing disease states or personal traits have been proposed as co-varieties. In order to examine these potential controlling factors in greater detail than previously possible, 1760 unrelated Caucasian subjects were studied, from which were identified 907 with a single expressing APO(a) allele. This strategy was followed to obviate the difficulty in dealing with the co-expression of different apo(a) isoforms and the resulting compound plasma Lp(a) level. After cube-root transformation of the plasma Lp(a) levels to normalise their distribution, a series of correlates were computed. There was no good correlation between Lp(a) concentration and any other measured lipid or lipoprotein in the lipid profile or with any other variable examined, with the important exception of the length of the expressed apo(a) isoform (r = -0.491, P = 0.0001). We conclude that in this population the plasma Lp(a) concentration is not predicted by the plasma lipid profile, alcohol intake, or smoking status but is predicted, albeit incompletely, by the length polymorphism of the APO(a) gene.     

A multicenter comparison of the effects of simvastatin and fenofibrate therapy in severe primary hypercholesterolemia, with particular emphasis on lipoproteins defined by their apolipoprotein composition.

This multicenter, double-blind, randomized study was designed to compare the effects of simvastatin (20 mg/d and 40 mg/d) and fenofibrate (400 mg/d) on plasma lipids, lipoproteins, apolipoproteins (apo), and lipoprotein particles defined by their apo composition (Lp A-I, Lp A-II:A-I, Lp E:B, Lp C-III:B) in primary hypercholesterolemia. After 6 and 10 weeks of therapy, both drugs lowered plasma cholesterol, low-density lipoprotein (LDL) cholesterol, and apo B. The effect on LDL and apo B was significantly more pronounced for simvastatin (P = .01). Simvastatin increased Lp A-I, but did not change Lp A-II:A-I, while fenofibrate decreased Lp A-I and increased Lp A-II:A-I. Lp E:B and Lp C-III:B were decreased with both drugs, but fenofibrate was significantly more effective in reducing these particles than simvastatin. This study demonstrates that both drugs have beneficial effects on the parameters positively or negatively correlated with the atherosclerotic risk, with simvastatin being more effective in reducing some of them. These results suggest that the drugs led to different structural modifications of the lipoproteins, which would not be revealed by examination of lipoprotein density classes. These differences are probably related to the different mechanisms of action of the agents.     

Corticotropin-induced reduction of plasma lipoprotein(a) concentrations in healthy individuals and hemodialysis patients: relation to apolipoprotein(a) size polymorphism

Lipoprotein(a) [Lp(a)], a strong independent cardiovascular risk factor, consists of the unique apolipoprotein(a) [apo(a)] covalently linked to a low-density lipoprotein particle. Apo(a) contains a widely differing number of the plasminogen-like kringle IV, a size polymorphism that is codominantly inherited. In addition to powerful genetic control, renal failure is known to influence the plasma Lp(a) concentration. There is still a lot to be learned about the mode and site of catabolism of Lp(a), and there is no readily applicable Lp(a)-lowering treatment available. Therefore, it was of interest to study further the Lp(a)-lowering effect of corticotropin (ACTH) that has been demonstrated in small studies. The main purpose of the present study was to investigate the influence of ACTH on different apo(a) isoforms. Short-term treatment with ACTH decreased the plasma Lp(a) concentration in all 26 study participants. The two study groups (12 healthy individuals and 14 hemodialysis patients) responded similarly, with a median decrease in plasma Lp(a) of 39% and 49%, respectively. In subjects with two clearly separable apo(a) bands, apo(a) phenotyping and densitometric scanning of the bands before and after treatment with ACTH revealed a change in the proportion of apo(a) isoforms, ie, a shift toward the isoform with lower molecular weight. This was observed in seven of nine investigated subjects (four of five healthy individuals and three of four hemodialysis patients).