Impaired very low density lipoprotein and triglyceride removal in broad beta disease: comparison with endogenous hypertriglyceridemia

Physiological Bases for the Superiority of Apolipoprotein B Over Low-Density Lipoprotein Cholesterol and Non-High-Density Lipoprotein Cholesterol as a Marker of Cardiovascular Risk

In 2019, the European Society of Cardiology/European Atherosclerosis Society stated that apolipoprotein B (apoB) was a more accurate marker of cardiovascular risk than low-density lipoprotein cholesterol (LDL-C) and non-high-density lipoprotein cholesterol. Since then, the evidence has continued to mount in favor of apoB. This review explicates the physiological mechanisms responsible for the superiority of apoB as a marker of the cardiovascular risk attributable to the atherogenic apoB lipoprotein particles chylomicron remnants, very low-density lipoprotein, and low-density lipoprotein particles. First, the nature and relative numbers of these different apoB particles will be outlined. This will make clear why low-density lipoprotein particles are almost always the major determinants of cardiovascular risk and why the concentrations of triglycerides and LDL-C may obscure this relation. Next, the mechanisms that govern the number of very low-density lipoprotein and low-density lipoprotein particles will be outlined because, except for dysbetalipoproteinemia, the total number of apoB particles determines cardiovascular risk, Then, the mechanisms that govern the cholesterol mass within very low-density lipoprotein and low-density lipoprotein particles will be reviewed because these are responsible for the discordance between the mass of cholesterol within apoB particles, measured either as LDL-C or non-high-density lipoprotein cholesterol, and the number of apoB particles measured as apoB, which creates the superior predictive power of apoB over LDL-C and non-high-density lipoprotein cholesterol. Finally, the major apoB dyslipoproteinemias will be briefly outlined. Our objective is to provide a physiological framework for health care givers to understand why apoB is a more accurate marker of cardiovascular risk than LDL-C or non-high-density lipoprotein cholesterol.

APOE2: protective mechanism and therapeutic implications for Alzheimer's disease

Investigations of apolipoprotein E (APOE) gene, the major genetic risk modifier for Alzheimer's disease (AD), have yielded significant insights into the pathogenic mechanism. Among the three common coding variants, APOE*ε4 increases, whereas APOE*ε2 decreases the risk of late-onset AD compared with APOE*ε3. Despite increased understanding of the detrimental effect of APOE*ε4, it remains unclear how APOE*ε2 confers protection against AD. Accumulating evidence suggests that APOE*ε2 protects against AD through both amyloid-β (Aβ)-dependent and independent mechanisms. In addition, APOE*ε2 has been identified as a longevity gene, suggesting a systemic effect of APOE*ε2 on the aging process. However, APOE*ε2 is not entirely benign; APOE*ε2 carriers exhibit increased risk of certain cerebrovascular diseases and neurological disorders. Here, we review evidence from both human and animal studies demonstrating the protective effect of APOE*ε2 against AD and propose a working model depicting potential underlying mechanisms. Finally, we discuss potential therapeutic strategies designed to leverage the protective effect of APOE2 to treat AD.

Remnants of the Triglyceride-Rich Lipoproteins, Diabetes, and Cardiovascular Disease

Diabetes is now a pandemic disease. Moreover, a large number of people with prediabetes are at risk for developing frank diabetes worldwide. Both type 1 and type 2 diabetes increase the risk of atherosclerotic cardiovascular disease (CVD). Even with statin treatment to lower LDL cholesterol, patients with diabetes have a high residual CVD risk. Factors mediating the residual risk are incompletely characterized. An attractive hypothesis is that remnant lipoprotein particles (RLPs), derived by lipolysis from VLDL and chylomicrons, contribute to this residual risk. RLPs constitute a heterogeneous population of lipoprotein particles, varying markedly in size and composition. Although a universally accepted definition is lacking, for the purpose of this review we define RLPs as postlipolytic partially triglyceride-depleted particles derived from chylomicrons and VLDL that are relatively enriched in cholesteryl esters and apolipoprotein (apo)E. RLPs derived from chylomicrons contain apoB48, while those derived from VLDL contain apoB100. Clarity as to the role of RLPs in CVD risk is hampered by lack of a widely accepted definition and a paucity of adequate methods for their accurate and precise quantification. New specific methods for RLP quantification would greatly improve our understanding of their biology and role in promoting atherosclerosis in diabetes and other disorders.

The aminoterminal 1-185 domain of human apolipoprotein E suffices for the de novo biogenesis of apoE-containing HDL-like particles in apoA-I deficient mice

AIMS

Recently we showed that apolipoprotein E promotes the de novo biogenesis of apoE-containing HDL particles in a process that requires the function of the lipid transporter ABCA1. Here, we sought to identify the domain of apoE that is responsible for its functional interactions with ABCA1 and the formation of apoE-rich HDL-like particles.

METHODS AND RESULTS

Recombinant attenuated adenoviruses expressing carboxy-terminal truncated forms of apoE4 (apoE4[1-259], apoE4[1-229], apoE4[1-202], and apoE4[1-185]) were administered to apoA-I-deficient mice at a low dose of 8×10(8) pfu and five days post-infection plasma samples were isolated and analyzed for HDL formation. Fractionation of plasma lipoproteins of the infected mice by density gradient ultracentrifugation and FPLC revealed that all forms were capable of promoting HDL formation. Negative staining electron microscopy analysis of the HDL density fractions confirmed that all C-terminal truncated forms of apoE4 promoted the formation of particles with diameters in the HDL region. Interestingly, apoE4[1-259], apoE4[1-229], and apoE4[1-202] led to the formation of spherical particles while plasma from apoE4[1-185] expressing mice contained a mixture of spherical and discoidal particles.

CONCLUSIONS

Taken together, our data establish that the aminoterminal 1-185 region of apoE suffices for the formation of HDL particles in vivo. Our findings may have important ramifications in the design of new biological drugs for the treatment of dyslipidemia, atherosclerosis and coronary heart disease.

Alteration of negatively charged residues in the 89 to 99 domain of apoA-I affects lipid homeostasis and maturation of HDL

In this study, we investigated the role of positively and negatively charged amino acids within the 89-99 region of apolipoprotein A-I (apoA-I), which are highly conserved in mammals, on plasma lipid homeostasis and the biogenesis of HDL. We previously showed that deletion of the 89-99 region of apoA-I increased plasma cholesterol and phospholipids, but it did not affect plasma triglycerides. Functional studies using adenovirus-mediated gene transfer of two apoA-I mutants in apoA-I-deficient mice showed that apoA-I[D89A/E91A/E92A] increased plasma cholesterol and caused severe hypertriglyceridemia. HDL levels were reduced, and approximately 40% of the apoA-I was distributed in VLDL/IDL. The HDL consisted of mostly spherical and a few discoidal particles and contained preβ1 and α4-HDL subpopulations. The lipid, lipoprotein, and HDL profiles generated by the apoA-I[K94A/K96A] mutant were similar to those of wild-type (WT) apoA-I. Coexpression of apoA-I[D89A/E91A/E92A] and human lipoprotein lipase abolished hypertriglyceridemia, restored in part the α1,2,3,4 HDL subpopulations, and redistributed apoA-I in the HDL2/HDL3 regions, but it did not prevent the formation of discoidal HDL particles. Physicochemical studies showed that the apoA-I[D89A/E91A/E92A] mutant had reduced α-helical content and effective enthalpy of thermal denaturation, increased exposure of hydrophobic surfaces, and increased affinity for triglyceride-rich emulsions. We conclude that residues D89, E91, and E92 of apoA-I are important for plasma cholesterol and triglyceride homeostasis as well as for the maturation of HDL.

LDL composition in E2/2 subjects and LDL distribution by Apo E genotype in type 1 diabetes

Apo E plays an important role in chylomicron and VLDL remnant processing, uptake or conversion to LDL. The type of lipoprotein that isolates in the LDL density of E2/2 subjects was investigated and the effect of the apo E isoforms on LDL mass was determined in all genotypes in a large group of Type 1 diabetics. Analysis of the LDL composition of E2/2 homozygotes (n=6) compared to subjects with the common E3/3 isoform (n=6) demonstrated an enrichment in apo E, unesterified cholesterol, phospholipid and triglyceride relative to apo B in E2/2 subjects, more typical of a dense IDL remnant than of LDL. Although diabetics were studied, these findings are considered to reflect those of the general population. Comparison of the lipoprotein distribution of homozygous and heterozygous subjects revealed that, as genotype changed from E4/4 (n=22) to E3/4 (n=262), E3/3 (n=710)=E2/4 (n=30), E2/3 (n=151), E2/2 (n=6), LDL cholesterol decreased significantly in a stepwise manner. The decrease was not in a specific subgroup of LDL. In conclusion, for E2/2 subjects, lipoproteins isolated in the LDL density range appear to be composed mainly of dense IDL remnants and some Lp(a). The apo E isoform also has a significant effect on LDL concentration in both homozygotes and heterozygotes.

Genetics of apolipoprotein B and apolipoprotein AI and premature coronary artery disease

Increased low-density lipoprotein (LDL) and decreased high-density lipoprotein cholesterol (HDL-C) predict premature coronary artery disease, as do elevated levels of apolipoprotein B or reduced levels of apolipoprotein AI. Probands were studied of families with common genetic forms of dyslipidaemia to determine if apo B or apo AI define genetic groups and if apo B or apo AI levels relate to premature coronary artery disease risk. Elevated apo B was characteristic of familial hypercholesterolaemia, familial combined hyperlipidaemia (FCHL), and was seen in individuals with elevated Lp(a). Normal apo B levels were seen in familial hypertriglyceridaemia and in 'coronary artery disease with low-HDL cholesterol'. Apo AI levels tended to be low in FCHL and were decreased in 'coronary disease with low-HDL cholesterol'. In familial hypertriglyceraemia, even though HDL-C levels were low, normal apo AI and apo B levels were seen in the absence of premature coronary artery disease. Therefore, in genetic dyslipidaemias elevated apo B levels and reduced apo AI levels (or increased apo B/AI ratio) differ and predict premature coronary artery disease.

Small, dense LDL and elevated apolipoprotein B are the common characteristics for the three major lipid phenotypes of familial combined hyperlipidemia

OBJECTIVE

Familial combined hyperlipidemia (FCHL) is associated with variable lipid and lipoprotein phenotypes arbitrarily defined as type IIa, IIb, and IV based on plasma total cholesterol and triglyceride levels. This study sought to characterize consistent lipoprotein and lipid abnormalities across the 3 lipoprotein phenotypes in 62 patients with documented FCHL (IIa [n=14], IIb [n=19], and IV [n=29]) and 44 healthy individuals.

METHODS AND RESULTS

The lipoprotein cholesterol distribution was determined over 38 fractions obtained by density gradient ultracentrifugation. As expected, FCHL patients with hypertriglyceridemia (IIb and IV) had higher cholesterol levels in VLDL than IIa, whereas IIa showed higher cholesterol in the big, buoyant LDL and in HDL. LDL cholesterol was higher in IIb than IV; most of the increase in LDL cholesterol was associated with big, buoyant LDL rather than small, dense LDL (sdLDL). The differences in lipoproteins between phenotypes were attributable to changes in VLDL and big, buoyant LDL levels. Comparison of the FCHL patients with healthy individuals showed a significant elevation in plasma apolipoprotein B levels and sdLDL in all 3 FCHL phenotypes.

CONCLUSIONS

Although triglyceride and cholesterol levels are variable by lipoprotein phenotype, sdLDL and elevated plasma apolipoprotein B levels are consistent characteristics of FCHL shared by the 3 different lipoprotein phenotypes.

Domains of apolipoprotein E contributing to triglyceride and cholesterol homeostasis in vivo. Carboxyl-terminal region 203-299 promotes hepatic very low density lipoprotein-triglyceride secretion

Apolipoprotein (apo) E has been implicated in cholesterol and triglyceride homeostasis in humans. At physiological concentration apoE promotes efficient clearance of apoE-containing lipoprotein remnants. However, high apoE plasma levels correlate with high plasma triglyceride levels. We have used adenovirus-mediated gene transfer in apoE-deficient mice (E(-)/-) to define the domains of apoE required for cholesterol and triglyceride homeostasis in vivo. A dose of 2 x 10(9) plaque-forming units of apoE4-expressing adenovirus reduced slightly the cholesterol levels of E(-)/- mice and resulted in severe hypertriglyceridemia, due to accumulation of cholesterol and triglyceride-rich very low density lipoprotein particles in plasma. In contrast, the truncated form apoE4-202 resulted in a 90% reduction in the plasma cholesterol levels but did not alter plasma triglyceride levels in the E(-)/- mice. ApoE secretion by cell cultures, as well as the steady-state hepatic mRNA levels in individual mice expressing apoE4 or apoE4-202, were similar. In contrast, very low density lipoprotein-triglyceride secretion in mice expressing apoE4, but not apoE4-202, was increased 10-fold, as compared with mice infected with a control adenovirus. The findings suggest that the amino-terminal 1-202 region of apoE4 contains the domains required for the in vivo clearance of lipoprotein remnants. Furthermore, the carboxyl-terminal 203-299 residues of apoE promote hepatic very low density lipoprotein-triglyceride secretion and contribute to apoE-induced hypertriglyceridemia.

Apolipoprotein E2 (Lys146-->Gln) causes hypertriglyceridemia due to an apolipoprotein E variant-specific inhibition of lipolysis of very low density lipoproteins-triglycerides

The apolipoprotein E2 (Lys146-->Gln) variant is associated with a dominant form of familial dysbetalipoproteinemia. Heterozygous carriers of this variant have elevated levels of plasma triglycerides, cholesterol, and apolipoprotein E (apoE). It was hypothesized that the high amounts of triglycerides in the very low density lipoprotein (VLDL) fraction are due to a disturbed lipolysis of VLDL. To test this hypothesis, apoE knockout mice were injected with an adenovirus containing the human APOE*2 (Lys146-->Gln) gene, Ad-E2(146), under the control of the cytomegalovirus promoter. ApoE knockout mice injected with an adenovirus vector encoding human apoE3 (Ad-E3) were used as controls. Five days after adenovirus injection, plasma cholesterol levels of mice injected with a high dose of Ad-E2(146) (2x10(9) plaque-forming units) were not changed compared with preinjection levels, whereas in the group who received a low dose of Ad-E2(146) (5x10(8) plaque-forming units) and in the groups injected with a low or a high dose of Ad-E3, plasma cholesterol levels were decreased 5-, 6-, and 12-fold, respectively. Plasma triglycerides were not affected in mice injected with Ad-E3. In contrast, a 7-fold increase in plasma triglycerides was observed in mice injected with the low dose of Ad-E2(146) compared with mice injected with Ad-E3. Injection with the high dose of Ad-E2(146) resulted in a dramatic increase of plasma triglycerides (50-fold compared with Ad-E3 injection). In vitro lipolysis experiments showed that the lipolysis rate of VLDLs containing normal amounts of apoE2 (Lys146-->Gln) was decreased by 54% compared with that of VLDLs containing comparable amounts of apoE3. The in vivo VLDL-triglyceride production rate of Ad-E2(146)-injected mice was not significantly different from that of Ad-E3-injected mice. These results demonstrate that expression of apoE2 (Lys146-->Gln) causes hypertriglyceridemia due to an apoE variant-specific inhibition of the hydrolysis of VLDL-triglycerides.

Apolipoprotein E: from atherosclerosis to Alzheimer's disease and beyond

Apolipoprotein E is a key regulator of plasma lipid levels. Our appreciation of its role continues to expand as additional aspects of its function are discovered. Apolipoprotein E affects the levels of all lipoproteins, either directly or indirectly by modulating their receptor-mediated clearance or lipolytic processing and the production of hepatic very low density lipoproteins. Furthermore, it plays a critical role in neurobiology. The apolipoprotein E4 allele is the major susceptibility gene related to the occurrence and early age of onset of Alzheimer's disease. It is probable that one of the major functions of apolipoprotein E in the central nervous system is to mediate neuronal repair, remodeling, and protection, with apolipoprotein E4 being less effective than the E3 and E2 alleles. The isoform-specific effects of apolipoprotein E are currently being unraveled through detailed structure and function studies of this protein.

Overexpression and accumulation of apolipoprotein E as a cause of hypertriglyceridemia

The molecular mechanisms of hypertriglyceridemia (HTG), a common lipid metabolic disorder in humans, often of genetic origin, are not well understood. In studying the effect of apolipoprotein (apo) E on the metabolism of triglyceride-rich lipoproteins, we found that expressing high plasma levels of human apoE3 in transgenic mice lacking endogenous mouse apoE caused HTG. These transgenic animals had 3-fold higher plasma triglyceride levels, higher very low density lipoproteins (VLDL), and lower high density lipoproteins than did nontransgenics. Removing one or both low density lipoprotein receptor alleles in the apoE3-overexpressing mice caused severe HTG (8-11-fold over nontransgenics) and increased VLDL and decreased low and high density lipoproteins, and apoE3-enriched VLDL were markedly depleted in apoC-II. At least two mechanisms could explain HTG associated with apoE3 overexpression: stimulated VLDL triglyceride production and impaired VLDL lipolysis. The apoE3 mice with HTG had a 50% increase in hepatic VLDL triglyceride production. Furthermore, overexpression of apoE (E2, E3, or E4) in cultured hepatocytes (McA-RH7777 cells) correlated positively with secretion of VLDL into the medium. However, apoE3 overexpression-associated HTG was only partially explained by VLDL overproduction, as lipoprotein lipase-mediated VLDL lipolysis was also decreased 20-86% depending on apoE3 levels, most likely by displacing or masking apoC-II on the particles. In human subjects, HTG correlated positively with increased VLDL triglyceride and plasma and VLDL apoE levels. However, plasma and VLDL apoE correlated negatively with VLDL apoC-II levels and lipoprotein lipase-mediated VLDL lipolysis. Thus, optimal expression of apoE is crucial for normal metabolism of triglyceride-rich lipoproteins, and overexpression and/or accumulation of apoE may contribute to HTG by stimulating VLDL triglyceride production and by impairing VLDL lipolysis. The apoE3-overexpressing mice will be useful for studying the pathophysiology of this disorder.

Apolipoprotein E2 reduces the low density lipoprotein level in transgenic mice by impairing lipoprotein lipase-mediated lipolysis of triglyceride-rich lipoproteins

Apolipoprotein (apo) E2 is often associated with low levels of low density lipoprotein (LDL) cholesterol and high levels of plasma triglycerides in humans. Mice expressing apoE2 also have low LDL levels. To evaluate the possible role of the LDL receptor in the cholesterol-lowering effect of apoE2, we bred transgenic mice expressing low levels of apoE2 with LDL receptor-null mice (hE2(+/0), LDLR-/-). Even in the absence of the LDL receptor, plasma total and LDL cholesterol levels decreased progressively with increasing levels of plasma apoE2. At plasma apoE2 levels >20 mg/dl, LDL cholesterol was approximately 45% lower than in LDLR-/- mice. Thus, the LDL cholesterol-lowering effect of apoE2 is independent of the LDL receptor. In contrast, plasma triglyceride levels increased (mostly in very low density lipoproteins (VLDL) and intermediate density lipoproteins (IDL)) progressively as apoE2 levels increased. At plasma apoE2 levels >20 mg/dl, triglycerides were approximately 150% higher than in LDLR-/- mice. Furthermore, in apoE-null mice (hE2(+/0), mE-/-), apoE2 levels also correlated positively with plasma triglyceride levels, suggesting impaired lipolysis in both hE2(+/0),LDLR-/- and hE2(+/0),mE-/- mice. Incubating VLDL or IDL from the hE2(+/0),LDLR-/- or the hE2(+/0),mE-/- mice with mouse postheparin plasma inhibited lipoprotein lipase-mediated lipolysis of apoE2-containing VLDL and IDL by approximately 80 and approximately 70%, respectively, versus normal VLDL and IDL. This observation was confirmed by studies with triglyceride-rich emulsion particles, apoE2, and purified lipoprotein lipase. Furthermore, apoE2-containing VLDL had much less apoC-II than normal VLDL. Adding apoC-II to the incubation partially corrected the apoE2-impaired lipolysis in apoE2-containing VLDL or IDL and corrected it completely in apoE2-containing emulsion particles. Thus, apoE2 lowers LDL cholesterol by impairing lipoprotein lipase-mediated lipolysis of triglyceride-rich lipoproteins (mostly by displacing or masking apoC-II). Furthermore, the effects of apoE2 on both plasma cholesterol and triglyceride levels are dose dependent and act via different mechanisms. The increase in plasma cholesterol caused by apoE2 is due mostly to impaired clearance, whereas the increase in plasma triglycerides is caused mainly by apoE2-impaired lipolysis of triglyceride-rich lipoproteins.

Fish oil supplementation reduces beta-very low density lipoprotein in type III dysbetalipoproteinemia

beta-Very low density lipoproteins (beta-VLDLs) are atherogenic, cholesterol-rich chylomicron and VLDL remnants that accumulate in the plasma of type III dysbetalipoproteinemic subjects. To evaluate the effect of fish oil supplementation on plasma beta-VLDL concentrations, we compared the lipid and lipoprotein responses in nine type III and nine type IV hyperlipidemic subjects. Each individual received 6 g/day omega-3 fatty acids for 12 weeks. Before treatment, the mean total cholesterol, total triglyceride, VLDL triglyceride, low density lipoprotein (LDL) cholesterol, and high density lipoprotein (HDL) cholesterol levels were not different between groups. Conversely, VLDL cholesterol, intermediate density lipoprotein (IDL) cholesterol, and IDL triglycerides were higher in type III than in type IV subjects. Fish oil supplementation was associated with significantly lower levels of cholesterol (-50%), triglycerides (-50%), and apolipoprotein B (-50%) in the d less than 1.006 g/ml ultracentrifugation plasma fraction in both groups, compatible with a reduction in VLDL in type III and type IV subjects, and in beta-VLDL in type III subjects. This finding was confirmed by analysis of the plasma zonal ultracentrifugation profile and the agarose gel electrophoretic pattern of lipoproteins, which showed a reduction in but not a disappearance of remnant particles, suggesting that not all beta-VLDL had been cleared after treatment. The levels of IDL cholesterol and IDL triglycerides (1.006 less than d less than 1.019 g/ml) were not affected in either group. Initially low LDL cholesterol (1.019 less than d less than 1.063 g/ml) and HDL cholesterol levels rose significantly in both groups. In type III hyperlipidemics, all LDL cholesterol values remained below 120 mg/dl, whereas they were higher than 150 mg/dl after treatment in two individuals with type IV hyperlipidemia.(ABSTRACT TRUNCATED AT 250 WORDS)

Lathosterol level in plasma is elevated in type III hyperlipoproteinemia, but not in non-type III subjects with apolipoprotein E2/2 phenotype, nor in type IIa or IIb hyperlipoproteinemia

We measured the serum lathosterol level, a reflection of the rate of whole body cholesterol synthesis, in 15 patients with manifest type III hyperlipoproteinemia (HLP), in 20 subjects with apolipoprotein (apo) E2/2 phenotype, but without type III HLP, in 21 patients with type IIA and 10 patients with type IIB HLP. A group of 100 subjects with apo E3/3 phenotype served as reference. Using ANCOVA, lathosterol was adjusted for serum cholesterol and triglyceride concentrations, since these parameters were found to independently correlate with lathosterol. The adjusted means (+/- SEM), in mumol/L, in these groups were 12.9 +/- 1.1, 8.2 +/- 1.1, 4.8 +/- 0.9, 9.8 +/- 1.4, and 7.8 +/- 0.4, respectively. Type III HLP patients had significantly higher lathosterol levels than all other groups except type IIB HLP. In addition, lathosterol was significantly lower in type IIA patients than in all other groups. The serum levels of plant sterols, used as a reflection of cholesterol absorption, did not differ among the various groups after adjustment for serum cholesterol. These findings suggest that an overproduction of cholesterol is one factor discriminating E2/2 homozygotes with type III HLP from those without the disease.

Different patterns of postprandial lipoprotein metabolism in normal, type IIa, type III, and type IV hyperlipoproteinemic individuals. Effects of treatment with cholestyramine and gemfibrozil

To study exogenous fat metabolism, we used the vitamin A-fat loading test, which specifically labels intestinally derived lipoproteins with retinyl palmitate (RP). Postprandial RP concentrations were followed in total plasma, and chylomicron (Sf greater than 1,000) and nonchylomicron (Sf less than 1,000) fractions. In normal subjects postprandial lipoproteins were present for more than 14 h, and chylomicron levels correlated inversely with lipoprotein lipase activity and fasting high density lipoprotein (HDL) cholesterol levels and nonchylomicron levels correlated inversely with hepatic triglyceride lipase activity. The main abnormality in type IV patients was a 5.6-fold increase in the chylomicron fraction, whereas in type III patients it was a 6.4-fold increase in nonchylomicrons. Type IIa patients had abnormally low chylomicron fractions. In type IV patients gemfibrozil decreased, whereas in type IIa patients cholestyramine increased the chylomicron fraction 66 and 88%, respectively. This study demonstrates an unexpectedly large magnitude and long duration of postprandial lipemia in normal subjects and patients. These particles are potentially atherogenic, and their role in human atherosclerosis warrants further study.

Metabolic consequences of genetic heterogeneity of lipoprotein composition (lipoprotein heterogeneity)

Lipoprotein composition varies among different genetic forms of hyperlipidemia. An increase in hepatic triglyceride (TG) synthesis in subjects with familial hypertriglyceridemia (FHTG) is associated with secretion of large, TG-enriched, very low-density lipoproteins (VLDL), which have an increased affinity for lipoprotein lipase (LPL) in vivo as compared with VLDL from subjects with familial combined hyperlipidemia (FCHL) or from normal subjects. Elevated levels of plasma low-density lipoprotein (LDL) apoprotein B in FCHL are associated with high apoprotein B production rates. The LDL in FCHL is heterogeneous, with a preponderance of an LDL subfraction, which is denser, smaller, and lipid poor as compared with LDL from normal subjects. The more buoyant LDL subfraction in FCHL seems to be catabolized more rapidly than this dense LDL subfraction.

Metabolism of apolipoproteins B-48 and B-100 of triglyceride-rich lipoproteins in patients with familial dysbetalipoproteinemia

The metabolism of apolipoproteins B-48 and B-100 (apo B-48 and B-100) in large triglyceride-rich lipoproteins was studied in three adults with familial dysbetalipoproteinemia (F. dys.) and compared to that of normolipidemic subjects. One Caucasian F. dys. subject was apparently homozygous for the common form of apo E-2, (Arg158----Cys), whereas the two Black subjects were homozygous for a different apo E-2 mutant (Arg145----Cys), which displays much less defective binding to cells than apo E-2 (Arg158----Cys). The lipoproteins were labeled with 125I and injected intravenously into fasted recipients. The results indicate that the terminal catabolism of triglyceride-rich lipoproteins of intestinal and hepatic origin is markedly impaired in apo E2/2 homozygotes with alleles Arg158----Cys and Arg145----Cys; despite long residence times, apo B-48 of chylomicrons and apo B-100 of large very low density lipoproteins are not converted appreciably to intermediate or low density lipoproteins in apo E2/2 homozygotes.

Genetic polymorphism in human apolipoprotein E

This chapter provides the methodologies employed to study the polymorphism of human apoE. These and other related studies have advanced our understanding of the structure and function of this protein as follows: The complex array of human apoE observed by two-dimensional gel electrophoresis results from genetic variation and posttranslational modification. The genetic polymorphism of apoE is explained by the existence of three common alleles (epsilon 4, epsilon 3, epsilon 2) at a single structural gene locus. Combinations of above alleles can generate three homozygous (E4/4, E3/3, E2/2) and three heterozygous (E4/3, E3/2, E4/2) apoE phenotypes. The apoE phenotype E2/2 is found in 91% of patients with type III hyperlipoproteinemia and can be used as a molecular marker for the diagnosis of this disease. However, other rare or common apoE phenotypes have been observed in patients with type III HLP. ApoE originating from E2/2 phenotype (Arg 158 to Cys 158 substitution) has reduced affinity for the LDL receptor. This property of apoE2 can account partially for the accumulation of apoE-rich lipoprotein remnants in the plasma of patients with type III HLP. However, other genetic or environmental factors are necessary for the phenotypic expression of the disease.

Compositional and metabolic heterogeneity of alpha 2- and beta-very-low-density lipoproteins in subjects with broad beta disease and endogenous hypertriglyceridemia

The catabolism of alpha 2- and beta-very-low-density lipoproteins (VLDL) was studied in normolipidemic and hyperlipidemic subjects to determine whether differences in the catabolism of these subfractions are due to their composition. alpha 2-VLDL (cholesterol/triglyceride ratio, 00.18 +/- 0.06; and apoprotein E/C ratio, 0.27 +/- 0.22, n = 4) and beta-VLDL (cholesterol/triglyceride ratio, 0.67 +/- 0.13; and apoprotein E/C ratio, 1.05 +/- 0.52, n = 4) were isolated from subjects with broad beta disease, iodinated, and injected in five normolipidemic subjects, six with broad beta disease, and five with endogenous hypertriglyceridemia. VLDL, intermediate (IDL) and low-density lipoprotein (LDL) apoprotein (apo)-B radioactivity (tetramethylurea insoluble) following injection of 125I-labeled alpha 2- and beta-VLDL decayed biphasically in all subjects, and this decay in normolipidemic subjects was more rapid than in subjects with broad beta disease (P = 0.004) or endogenous hypertriglyceridemia (P = 0.004 for alpha 2- and P = 0.010 for beta-VLDL). The residence times, however, for the delipidation chain in alpha 2-VLDL were similar in all the subjects and varied from three to six hours. The decay of radioactivity in beta-VLDL in subjects with broad beta disease was much slower (residence time, 36.9 +/- 24.4 hr, n = 7) than in normolipidemic subjects (residence time, 7.56 +/- 4.6 hr, n = 5) or in subjects with endogenous hypertriglyceridemia (residence time, 10.6 +/- 4.65, n = 4). The residence time for alpha 2-VLDL was longer than for beta-VLDL in all subjects, suggesting that alpha 2-VLDL is a precursor to beta-VLDL. To test this directly, iodinated alpha 2-VLDL was injected into a subject with broad beta disease and the radioactivity in the subfractions was followed. The radioactivity from alpha 2-VLDL was transferred into beta-VLDL supporting, the notion that alpha 2-VLDL generated some beta-VLDL. Nicotinic acid treatment of a subject with broad beta disease accelerated the catabolism of alpha 2- and beta-VLDL without changing the VLDL composition.

Plasma apolipoprotein B metabolism in familial type III dysbetalipoproteinaemia

Lipoprotein metabolism was studied in eleven patients with Type III hyperlipoproteinaemia, one with normolipidaemic dysbetalipoproteinaemia and eight controls. Apolipoprotein B kinetics in very low density, intermediate density and low density lipoproteins (VLDL, IDL and LDL) was investigated. Fractional catabolic rates (FCRs) of VLDL-apo B and IDL-apo B were lower (P less than 0.005 and P less than 0.001) in the patients: 0.064 +/- 0.018 and 0.059 +/- 0.006 h-1 respectively, (mean +/- SEM), compared with 0.219 +/- 0.035 and 0.243 +/- 0.028 h-1. Synthetic rates (SRs) of IDL-apo B varied widely from 1.5 mg kg-1 day-1 in the subject with normolipidaemic dysbetalipoproteinaemia to 2.8-25.2 mg kg-1 day-1 in Type III. The mean time for conversion of IDL-apo B to LDL-apo B was prolonged, 18.7 h compared with 3.8 h in the controls (P less than 0.001). LDL-apo B pool size and SR were lower in the patients (P less than 0.05 for both). Two patients treated with gemfibrozil showed reduced hyperlipidaemia and decreased SR of VLDL-apo B and IDL-apo B. Dysbetalipoproteinaemia is associated with pronounced impairment of IDL and VLDL-remnant catabolism, lipoprotein levels reflecting an interaction between this defect and SR of these lipoproteins.

Apolipoprotein B-48 and B-100 very low density lipoproteins. Comparison in dysbetalipoproteinemia (type III) and familial hypertriglyceridemia (type IV)

A protein band having the same migration as apolipoprotein (apo) B-48 was observed by SDS electrophoresis in the plasma very low density lipoprotein (VLDL) from 14 Type IV and three Type III hyperlipoproteinemic subjects and from six normal fasting subjects. The VLDL from five Type IV, three Type III, and one normal subject were separated into two subfractions, retained and nonretained, by immunoaffinity chromatography on monoclonal anti-apo B-100 Sepharose. Based on results of electrophoresis and radioimmunoassay, we have concluded that these two fractions represent apo B-48 and apo B-100 lipoproteins that we have named apo B-48 and apo B-100 VLDL. When compared to their respective apo B-100 VLDL, the apo B-48 VLDL from either Type III or Type IV was principally enriched in total lipids, in apo E, and had an electrophoretic migration similar to chylomicrons. This suggests that apo B-48 VLDL has the same origin (i.e., intestinal) in the two disorders. Both apo B-48 and apo B-100 VLDL were enriched in cholesteryl ester (CE) and depleted in triglyceride (TG) in Type III; however, both fractions were rich in TG and poor in CE in Type IV and in normal subjects. In addition, compared to their respective apo B-100 VLDL, the apo B-48 fraction was enriched in CE in Type III and in TG in Type IV. We conclude that, despite a possible similar origin for apo B-48 VLDL in Type III and in Type IV subjects, the composition of apo B-48 VLDL is variable and the CE/TG ratio is more characteristic of the type of hyperlipidemia than of the particular VLDL subfractions.

Low-density lipoproteins modified by lipid transfer protein have altered biological activity

Low-density lipoproteins (LDL) were modified by incubation with very-low-density lipoproteins (VLDL) and lipid transfer protein(s) to yield LDL particles that were enriched in triacylglycerol, depleted in cholesteryl esters, and contained apolipoprotein C. The uptake and degradation of these 125I-labeled modified LDL particles by cultured skin fibroblasts was reduced by approx. 30% when compared with LDL that had not been exposed to lipid transfer protein. Incubation of fibroblasts for 24 h in the presence of modified LDL resulted in less inhibition of LDL receptor activity and sterol synthesis than did incubation with control LDL. Both the degradation of 125I-labeled modified LDL and the effect of unlabeled modified LDL on the regulation of LDL binding and sterol synthesis were progressively decreased as the extent of modification of the LDL was increased. Even when identical amounts of modified LDL or control LDL protein were degraded, less inhibition of LDL receptor activity and sterol synthesis was observed with modified LDL than with control LDL, suggesting that the effects of modified LDL on these regulatory events are related to both the reduced degradation of the modified lipoprotein particles and to the alteration in its chemical composition. Uptake and degradation of modified LDL by human monocyte-derived macrophages in culture was reduced in a manner similar to that observed in the cultured fibroblasts, and was considerably less than that observed with acetylated LDL. No differences were observed between modified LDL prepared by exposure to lipid transfer activity in the lipoprotein deficient fraction of serum or when partially purified lipid transfer was used. Modified LDL, with similar composition to that used in the experiments, has been observed in certain diabetic and non-diabetic hypertriglyceridemic states. Thus, it is possible that the cellular metabolism of LDL in vivo might be altered in the presence of hypertriglyceridemia.

Role of apolipoprotein E in the lipolytic conversion of beta-very low density lipoproteins to low density lipoproteins in type III hyperlipoproteinemia

The beta-very low density lipoproteins (beta-VLDL) that accumulate in type III hyperlipoproteinemic subjects can be divided into two fractions (fraction I and fraction II), which differ in size, lipid composition, and the type of apolipoprotein B (apo-B) present in the particles. The apo-B48-containing particles (fraction I) are of intestinal origin, while apo-B100-containing particles (fraction II) are derived from the liver. Both fractions contain a defective form of apo-E referred to as apo-E2. Intravenous infusion of heparin into two subjects with type III hyperlipoproteinemia resulted in the complete removal of fraction II particles from density less than 1.006 g/ml, while fraction I particles remained at this density. In vitro studies confirmed that fraction I particles did not change density when subjected to hydrolysis with lipoprotein lipase, while fraction II particles shifted to the intermediate density lipoprotein range (approximately equal to 1.02 g/ml). When the beta-VLDL were hydrolyzed by lipoprotein lipase in the presence of density greater than 1.21 g/ml lipoprotein-deficient plasma, the addition of normal apo-E (apo-E3), but not apo-E2, resulted in a shift of fraction II particles to the low density lipoprotein (LDL) range (approximately equal to 1.05 g/ml). Fraction I particles did not undergo a shift to this higher density, supporting previous observations that apo-B48-containing particles are not converted to LDL. The demonstration that apo-B100-containing particles in type III hyperlipoproteinemic subjects could be converted to particles with the density of LDL suggests that apo-E plays a role in the normal conversion of VLDL to LDL. The mutant form of apo-E (apo-E2) found in the beta-VLDL from type III hyperlipoproteinemic subjects appears to impede this conversion, whereas the addition of normal apo-E (apo-E3) allows the processing to occur.

Isolation and characterization of apolipoprotein B-48 and B-100 very low density lipoproteins from type III hyperlipoproteinemic subjects

Two major species of human apolipoprotein (apo) B have been identified, apo B-48 and apo B-100, which are the predominant forms in chylomicrons and very low density lipoproteins (VLDL), respectively. Due to defective hepatic clearance, apo B-48 containing lipoproteins accumulate in the plasma of subjects with type III hyperlipoproteinemia. In the present study, we have used immunoaffinity chromatography to separate type III VLDL into a nonretained (apo B-48 VLDL) and a retained (apo B-100 VLDL) fraction. To achieve complete separation, as determined by electrophoresis and radioimmunoassay, it was necessary to employ two different insolubilized anti-apo B-100 monoclonal antibodies because of immunochemical heterogeneity within the apo B-100 VLDL fraction. The ability to separate apo B-100 VLDL from apo B-48 VLDL shows that the two apo B species are found on different particles. The apo B-48 VLDL had an electrophoretic mobility similar to chylomicrons, whereas the apo B-100 VLDL migrated similarly to total type III VLDL. Both fractions showed a concentration of particles with diameters approximately 100 nm, with apo B-48 VLDL being somewhat more heterogeneous in particle size. The two fractions were qualitatively similar in apolipoprotein composition but apo B-48 VLDL was enriched in apo E, relative to apo B-100 VLDL. Apo B-48 VLDL was enriched in cholesterol esters and deficient in triglycerides and phospholipids when compared with apo B-100 VLDL. The existence of immunochemical heterogeneity in the apo B-100 VLDL may reflect different functional subpopulations of particles within this fraction.

[The apolipoproteins in man ]

Twelve different apolipoproteins have been described in human serum. Apo A-I and apo A-II are essential for the structure of the HDL particles and for the function of LCAT activity. Apo B is the main protein in LDL but does also occur in the triglyceride-rich particles. Apo B represents the binding protein for the LDL-receptor pathway. The C-apolipoproteins are located on the surface of VLDL. They are transferred to HDL throughout the catabolism of VLDL and affect lipoprotein lipase activity. This enzyme is also affected by the E-apolipoproteins which occur in the triglyceride-rich particles as well as in HDL. Apo E is the binding site for another specific cell receptor. The concentration and metabolism of apolipoproteins is affected by diet, drugs, hormones, body weight, alcohol, cigarettes, physical exercises, liver and renal diseases. There is a close relation between apolipoproteins and atherosclerosis.

The independent synthesis of intermediate density lipoproteins in type III hyperlipoproteinemia

The kinetics of VLDL (Sf 60-400) and IDL (Sf 12-60) B apoprotein were examined in five type III hyperlipoproteinemic subjects. The production rates for B apoprotein were significantly greater in the IDL fraction than in VLDL. Precursor-product relationships between VLDL and IDL B apoprotein illustrated that a significant proportion of IDL B apoprotein was derived from some source other than VLDL catabolism. These observations indicated that, in the five individuals studied, an 'unusual' B apoprotein synthetic pathway operated whereby B apoprotein was directly entering the IDL fraction. Furthermore, this second pathway resulted in an overproduction of IDL B apoprotein and possibly was the major defect leading to the development of the type III hyperlipoproteinemia lipid profile. In two subjects who were restudied following hormonal treatment (estrogen or thyroxine replacement) and in whom the type III hyperlipoproteinemia lipid profile no longer existed, it was found that the pathway for direct synthesis of IDL B apoprotein had been abolished. From these studies we have concluded that a pathway for the direct synthesis of IDL B apoprotein operates in type III hyperlipoproteinemics and it is a major causative factor in the development of the IDL accumulation characteristic of this metabolic disorder.

Uptake of chylomicron remnants by the native LDL receptor in human monocyte-derived macrophages

Human chylomicron remnants were taken up by cultured human monocyte-derived macrophages. Competition studies using 125I-labeled and unlabeled lipoproteins demonstrated that the remnant particles were not taken up by the modified LDL (acetyl LDL) receptor in these cells, which also contain a receptor for native LDL. The data thus suggest that the apolipoprotein E- and B-containing remnant particles are mainly taken up through an extra-hepatic E and B receptor (the classical LDL receptor pathway) in macrophages as is the case in cultured human skin fibroblasts.

Integrated regulation of very low density lipoprotein triglyceride and apolipoprotein-B kinetics in man: normolipemic subjects, familial hypertriglyceridemia and familial combined hyperlipidemia

Turnover kinetics of triglycerides (TG) and apolipoprotein-B (apo-B) of plasma very low density lipoprotein (VLDL) and their relationship to plasma VLDL composition and VLDL apo-B conversion to low density lipoprotein (LDL) were determined in age and weight-matched groups of normolipemic (NL) healthy subjects, patients with familial combined hyperlipidemia (FCHL) and patients with familial hypertriglyceridemia (FHTG). In NL subjects, a significant correlation as observed between VLDL TG or VLDL apo-B turnover rate and its circulating mass, suggesting that the plasma level of VLDL was determined by the secretion rate of VLDL TG and apo-B. The positive significant correlation between VLDL TG and apo-B also suggests that the production of these moieties was integrated at the synthetic and/or secretory sites to maintain the ratio of TG to apo-B in plasma VLDL. In moderately obese NL subjects, proportionate increases in VLDL TG and apo-B turnover rates resulted in enhanced secretion of VLDL particles. Both groups with genetic hypertriglyceridemia had increased VLDL TG and VLDL apo-B turnover rates. This increase accounted for the increase in circulating VLDL TG and apo-B mass. In patients with FCHL, turnover rates of VLDL TG and apo-B were equally increased, hence, the ratios between major VLDL constituents were within normal limits. On the other hand, the increase in VLDL TG turnover in patients with FHTG was disproportionately greater than that of apo-B resulting in a higher ratio of TG to other VLDL components. In NL subjects, approximately 72% of VLDL apo-B released into plasma was converted to LDL. This conversion correlated positively with VLDL apo-B turnover rate and inversely with VLDL TG turnover rate. Formation of LDL from VLDL was significantly greater in the obese individuals. In FCHL, conversion of VLDL to LDL represented the major pathway for VLDL apo-B catabolism. The increased VLDL apo-B load was predominantly catabolized to LDL. The greater increase in VLDL TG turnover relative to apo-B in FHTG, on the other hand, resulted in a smaller fraction of VLDL apo-B recovered in LDL, most of the VLDL apo-B being removed via a pathway that did not involve this conversion. We conclude that the composition and metabolic fate of plasma VLDL may be greatly influenced by the secretion rates of VLDL TG and apo-B. If VLDL conversion to LDL and the subsequent catabolism of the latter provides a major route for delivery of cholesterol ester to peripheral tissues, then the increased LDL production in FCHL compared to FHTG may account for a higher cardiovascular risk.

Type III hyperlipoproteinemia: defective metabolism of an abnormal apolipoprotein E

The apolipoprotein E isolated from plasma of individuals with type III hyperlipoproteinemia (HLP) shows an abnormal pattern when it is examined by isoelectric focusing. Compared to apolipoprotein E from normal subjects, apolipoprotein E isolated from subjects with type III HLP had a decreased fractional catabolic rate in vivo in both type III HLP patients and normal individuals. The delayed catabolism of apolipoprotein E in type III HLP patients may be responsible for the lipid and lipoprotein abnormalities characteristic of these patients.

Kinetic bases of the primary hyperlipidaemias: studies of apolipoprotein B turnover in genetically defined subjects

Autologous 131I-labelled very low density lipoprotein (VLDL) and 125I-labelled low density lipoprotein (LDL) were injected into seven normal subjects and into forty-three hyperlipidaemic patients, classified into groups on the basis of family studies and clinical findings, to quantitate VLDL and LDL apolipoprotein B kinetics. In normal subjects, mean VLDL-B peptide synthetic rate was 15 . 1 mg kg-1 day-1, mean LDL-B peptide synthetic rate 7 . 7 mg kg-1 day-1 and mean LDL-B fractional catabolic rate (FCR) 0 . 31 day-1. In heterozygous familial hypercholesterolaemia (n = 14) VLDL-B peptide production was normal in patients with normal triglyceride levels; in those with high triglyceride levels there was either VLDL overproduction or a catabolic defect. LDL-B peptide synthetic rates ranged from high normal to increased (8 . 5--18 . 0 mg kg-1 day-1) and LDL-B peptide FCR values were markedly reduced (0 . 14--0 . 28 day-1) confirming the presence of a defect in LDL catabolism but indicating over-production as well. In familial combined hyperlipidaemia (n = 11) VLDL-B peptide production ranged from normal to elevated (13 . 9--44 . 4 mg kg-1 day-1, mean 23 . 8 mg kg-1 day-1) correlating with the VLDl triglyceride level (i.e. with the phenotypic expression of the disorder). LDL-B peptide production ranged from high normal to markedly increased (8 . 9--19 . 5 mg kg-1 day-1, mean 12 . 2 mg kg-1 day-1) and correlated with LDL cholesterol levels (i.e. the phenotype), (r = +0 . 66, P < 0 . 05). Three patients with unclassified hypercholesterolaemia had increased LDL-B peptide synthetic rates. One patient with remnant hyperlipoproteinaemia (type III) had a high normal VLDL-B peptide synthetic rate, 17 . 3 mg kg-1 day-1, and a strikingly low FCR of VLDL-B. In familial hypertriglyceridaemia (three patients) there was a low VLDL-B peptide FCR. In unclassified hypertriglyceridaemia VLDL over-production was the finding in seven patients but four patients appeared to have catabolic defects only. Overall there were significant hyperbolic relationships between VLCL-B peptide FCR and VLDL-B peptide concentration (r = -0 . 78, P < 0 . 001, for the log/log relationship) and between LDL-B peptide FCR and LDL cholesterol (r = -0 . 88, P < 0 . 001 for the log/log relationship.)

Adipose tissue lipoprotein lipase activity in type III hyperlipoproteinemia

An impairment in the catabolism of chylomicron and very low density lipoprotein remnants appears to cause the lipid abnormalities in type III hyperlipoproteinemia. A reduction in the activity of lipoprotein lipase (LPL) has been suggested as the catabolic defect. Results in this study indicate that the activity of adipose tissue LPL measured in the fasted and fed states are in the normal range in type III hyperlipoproteinemia (fasted: type III = 2.7 +/- 1.8 mU/10(6) cells, N = 8; normals = 3.4 +/- 2.5, N = 23, p, not significant; fed: type III = 3.6 +/- 2.1, N = 7; normals = 4.8 +/- 1.8, N = 12, p, not significant). This suggests that perhaps another mechanism, such as the interaction between LPL and its lipid substrate, is abnormal, or that the activity of LPL derived from another tissue source is deficient.

Atherogenesis: a postprandial phenomenon

The hypothesis that plasma chylomicrons in persons who ingest a cholesterol-rich diet are atherogenic is evaluated. Evidence is presented that in humans, and experimental animals, chylomicron remnants as well as low-density lipoproteins are taken up by arterial cells. In persons who do not have familial hyperlipoproteinemia, atherogenesis may occur during the postprandial period. Research directions that may contribute to the evaluation of chylomicron remnants as a risk factor for atherogenesis are discussed. Lipoprotein studies after administration of a test meal containing fat and cholesterol are urgently needed.

Reduction of plasma triglyceride concentration by acute stress in man

Three different forms of stress all resulted in acute reduction of plasma triglyceride concentrations. Pyrogen reactions in two hypertriglyceridemic men resulted in the lowering of very-low-density lipoprotein (VLDL) triglyceride levels by 93% and 73% due to decreased secretion of this lipoprotein into plasma. More modest reductions in plasma triglycerides were observed after 2-deoxyglucose-induced intracellular glucopenia and insulin-induced hypoglycemia. With hypoglycemia, the lowering of plasma triglyceride concentration correlated significantly with the stimulation of urinary epinephrine output (r = 0.86) but with neither the urinary norepinephrine response nor with the increase in plasma immunoreactive glucagon levels. To further test whether these changes in plasma triglyceride levels were mediated via the sympathetic nervous system, hypoglycemia was evoked by insulin in subjects with traumatic spinal cord transactions. Two such subjects, who demonstrated sympathetic stimulation in response to hypoglycemia, had evidence of reduced VLDL secretion into plasma, while in two who had no evidence of an adrenergic response. VLDL secretion was not inhibited. Thus, acute lowering of plasma triglyceride concentrations by certain forms of stress appears to be mediated via the sympathetic nervous system.