Experimental concerns in tracer kinetic investigations of apolipoprotein metabolism

The complexity of the metabolism of the plasma lipoproteins makes it impossible to integrate the details of the reactions of specific apolipoproteins and their associated lipids without the use of computerized modeling methods. Because apolipoproteins impart specificity in the transport and chemical processing of plasma lipids, they have been the focus of many in vivo kinetic tracer investigations. The analysis of such kinetic data by modeling techniques has provided important advances in understanding lipoprotein metabolism. An example is the Delipidation Chain, an hypothesis explaining VLDL metabolism in terms of a sequential delipidation process. As a consequence of the advance in knowledge of apolipoprotein structure and metabolism, coupled with progress in computerized modeling of large systems, it has become important to refine the design of in vivo tracer kinetic investigations of the apolipoproteins. Considerations of particular importance include the selection of apolipoprotein tracers which can be shown to undergo the same reactions as the apolipoproteins whose metabolism they trace. If the physical and chemical processes which convert apolipoproteins from one metabolic pool to another are to be analyzed correctly, it is necessary to describe precisely and to measure accurately these pools. Current methods for delineating metabolic pools of apolipoproteins in vivo need to be refined. When accomplished, this will provide new opportunities to investigate the metabolic pathways of the apolipoproteins and their associated lipids. A very important challenge is to design experiments which will differentiate transfer processes, which result in net transport of a reactant, from exchange processes, whereby a tracer and a tracee are exchanged between pools without a net transport event occuring. Since both types of processes occur readily with apolipoproteins, it is important to develop methods to examine them separately. Computerized kinetic modeling provides a means for describing and understanding the complexities of lipoprotein metabolism. A major challenge is for the experimentalist to acquire data which accurately reflect the physiological processes involved in lipoprotein metabolism.     

Apolipoproteins in the brain: implications for neurological and psychiatric disorders

The brain is the most lipid-rich organ in the body and, owing to the impermeable nature of the blood-brain barrier, lipid and lipoprotein metabolism within this organ is distinct from the rest of the body. Apolipoproteins play a well-established role in the transport and metabolism of lipids within the CNS; however, evidence is emerging that they also fulfill a number of functions that extend beyond lipid transport and are critical for healthy brain function. The importance of apolipoproteins in brain physiology is highlighted by genetic studies, where apolipoprotein gene polymorphisms have been identified as risk factors for several neurological diseases. Furthermore, the expression of brain apolipoproteins is significantly altered in several brain disorders. The purpose of this article is to provide an up-to-date assessment of the major apolipoproteins found in the brain (ApoE, ApoJ, ApoD and ApoA-I), covering their proposed roles and the factors influencing their level of expression. Particular emphasis is placed on associations with neurological and psychiatric disorders.     

HDL: structure, function and metabolism.

The major advances in our knowledge of the structure, function and metabolism of the plasma lipoproteins have occurred as a result of the rapid increase in our knowledge of the structure and function of the apolipoproteins, lipoproteins, and the heterogeneity of the individual classes of lipoproteins. Over the last decade, there has been a tremendous increase in our knowledge of the structure and molecular properties of ApoA-I and ApoA-II which has permitted an analysis of the functions of these apolipoproteins in lipid and lipoprotein metabolism and the initiation of kinetic studies of HDL metabolism. The elucidation of the structures of the ApoA-I and ApoA-II genes has permitted the determination of genetic defects resulting in decreased levels of HDL and premature cardiovascular disease, as well as the identification of new diseases (e.g. hereditary systemic amyloidosis). The future focus of research on HDL will be the analysis of the individual lipoprotein particles within HDL which have different physiological functions and important roles in reverse cholesterol transport. An improved understanding of the role of HDL in the transport of cellular cholesterol to the liver and the exchange of cholesterol between plasma lipoproteins will provide critical information on cholesterol metabolism in normal subjects and permit the elucidation of the molecular defects of new genetic diseases which may be associated with the development of premature cardiovascular disease.     

Isopropanol precipitation method for the determination of apolipoprotein B specific activity and plasma concentrations during metabolic studies of very low density lipoprotein and low density lipoprotein apolipoprotein B

A method has been described for the measurement of apoB concentration and specific activity in very low density lipoprotein (VLDL) and low density lipoprotein (LDL) during metabolic studies. For measurement of specific activity, apoB was separated from other apolipoproteins and lipids by precipitation in, and subsequent washing with, isopropanol. For determination of apoB concentration, equal volumes of lipoprotein and isopropanol were mixed, and the protein content of the apoB precipitate was measured by the difference between total lipoprotein protein and the protein measured in the supernatant. Evidence that there was no apoB solubilization in isopropanol and that precipitated apoB was virtually free of soluble apolipoproteins was obtained by electrophoresis. Lipid contamination of the apoB precipitate was less than 1%. The methods were applicable to VLDL, intermediate density lipoprotein (IDL), and LDL from normolipemic patients with protein concentrations between 187 micrograms/ml and 1898 micrograms/ml. The data obtained using isopropanol were highly correlated with those using tetramethylurea, and recoveries of apoB were similar. Furthermore, the isopropanol method has been demonstrated to yield consistent data for apoB specific activities in a study of VLDL, IDL, and LDL metabolism.     

Concerted actions of cholesteryl ester transfer protein and phospholipid transfer protein in type 2 diabetes: effects of apolipoproteins

PURPOSE OF REVIEW: Type 2 diabetes frequently coincides with dyslipidemia, characterized by elevated plasma triglycerides, low high-density lipoprotein cholesterol levels and the presence of small dense low-density lipoprotein particles. Plasma lipid transfer proteins play an essential role in lipoprotein metabolism. It is thus vital to understand their pathophysiology and determine which factors influence their functioning in type 2 diabetes. RECENT FINDINGS: Cholesteryl ester transfer protein-mediated transfer is increased in diabetic patients and contributes to low plasma high-density lipoprotein cholesterol levels. Apolipoproteins A-I, A-II and E are components of the donor lipoprotein particles that participate in the transfer of cholesteryl esters from high-density lipoprotein to apolipoprotein B-containing lipoproteins. Current evidence for functional roles of apolipoproteins C-I, F and A-IV as modulators of cholesteryl ester transfer is discussed. Phospholipid transfer protein activity is increased in diabetic patients and may contribute to hepatic very low-density lipoprotein synthesis and secretion and vitamin E transfer. Apolipoprotein E could stimulate the phospholipid transfer protein-mediated transfer of surface fragments of triglyceride-rich lipoproteins to high-density lipoprotein, and promote high-density lipoprotein remodelling. SUMMARY: Both phospholipid and cholesteryl ester transfer proteins are important in very low and high-density lipoprotein metabolism and display concerted actions in patients with type 2 diabetes.     

A novel lipoprotein from the hemolymph of the cochineal insect, Dactylopius confusus.

A new type of insect lipoprotein was isolated from the hemolymph of the female cochineal insect Dactylopius confusus. The lipoprotein from the cochineal insect hemolymph was found to have a relative molecular mass of 450 000. It contains 48% lipid, mostly diacylglycerol, phospholipids and hydrocarbons. The protein moiety of the lipoprotein consists of two apoproteins of approximately 25 and 22 kDa, both of which are glycosylated. Both apolipoproteins are also found free in the hemolymph, unassociated with any lipid. Purified cochineal apolipoproteins can combine with Manduca sexta lipophorin, if injected together with adipokinetic hormone into M. sexta. This could indicate that the cochineal lipoprotein can function as a lipid shuttle similar to lipophorins of other insects, and that the cochineal insect apolipoproteins have an overall structure similar to insect apolipophorin-III.     

Inhibition of human and rat lipoprotein lipase by high-density lipoprotein

The hydrolysis in vitro of preactivated Intralipid (an artificial triacylglycerol-phospholipid emulsion) by rat adipose tissue lipoprotein lipase is inhibited by rat high-density lipoprotein (HDL). The aim of this work was to investigate whether human lipoprotein lipase was also inhibited, the mechanism of inhibition of the rat enzyme by HDL, and the role of the various individual apolipoproteins. Both human and rat lipoprotein lipase from post-heparin plasma are inhibited by HDL. This inhibition is considerably decreased if the HDL is first made 'apolipoprotein poor' by removal of some transferable apolipoproteins. In contrast, both native and apolipoprotein poor HDL inhibit the hydrolysis of Intralipid by rat hepatic lipase. Apolipoproteins C and E, either free in solution or attached to lipid vesicles, inhibit the hydrolysis of activated Intralipid by rat lipoprotein lipase to a maximum of 85% and 50%, respectively. Apolipoprotein A attached to vesicles gives little inhibition. HDL apolipoprotein and apolipoprotein C compete with the substrate for binding to lipoprotein lipase with apolipoprotein C having a higher affinity for the enzyme than HDL apolipoprotein. The inhibition of lipoprotein lipase by HDL can be explained by the association of the constituent apolipoproteins, in particular apolipoprotein C, with the enzyme so that there is less enzyme available to act on substrate.     

Nascent Astrocyte Particles Differ from Lipoproteins in CSF

Abstract: Little is known about lipid transport and metabolism in the brain. As a further step toward understanding the origin and function of CNS lipoproteins, we have characterized by size and density fractionation lipoprotein particles from human CSF and primary cultures of rat astrocytes. The fractions were analyzed for esterified and free cholesterol, triglyceride, phospholipid, albumin, and apolipoproteins (apo) E, AI, AII, and J. As determined by lipid and apolipoprotein profiles, gel electrophoresis, and electron microscopy, nascent astrocyte particles contain little core lipid, are primarily discoidal in shape, and contain apoE and apoJ. In contrast, CSF lipoproteins are the size and density of plasma high-density lipoprotein, contain the core lipid, esterified cholesterol, and are spherical. CSF lipoproteins were heterogeneous in apolipoprotein content with apoE, the most abundant apolipoprotein, localized to the largest particles, apoAI and apoAII localized to progressively smaller particles, and apoJ distributed relatively evenly across particle size. There was substantial loss of protein from both CSF and astrocyte particles after density centrifugation compared with gel-filtration chromatography. The differences between lipoproteins secreted by astrocytes and present in CSF suggest that in addition to delivery of their constituents to cells, lipoprotein particles secreted within the brain by astrocytes may have the potential to participate in cholesterol clearance, developing a core of esterified cholesterol before reaching the CSF. Study of the functional properties of both astrocyte-secreted and CSF lipoproteins isolated by techniques that preserve native particle structure may also provide insight into the function of apoE in the pathophysiology of specific neurological diseases such as Alzheimer's disease.     

Importance of apolipoproteins in lipid metabolism

Lipids, which serve as a source of energy and are an important constituent of cell membrane structure, are readily stored in the body. By definition they are insoluble in water. Specific proteins called apolipoproteins interact with lipids to form soluble lipid-protein complexes called lipoproteins. It is in this form that the major lipids — cholesterol, triglyceride and phospholipid — circulate in plasma. Unesterified fatty acids, another major lipid group, are bound to albumin in the circulation. The plasma lipoproteins are complex macromolecules composed of lipids, apolipoproteins and carbohydrates. The relative proportions of these components differ markedly between lipoprotein classes.

Hyperlipidemia is a term used for increased concentrations of plasma cholesterol and/or triglycerides. Any one plasma lipid is present in several types of lipoproteins. Thus, hyperlipidemia implies the presence of hyperlipoproteinemia. The latter has important therapeutic implications. Most of the recent attempts at classification have been directed at the lipoprotein level of plasma lipid organization.

Decreased concentrations of lipids in plasma can be achieved by altering the rates of metabolism of lipoproteins. Decrease in lipoprotein synthesis, increased catabolism or impaired release from cells into the blood stream may all result in a decrease of plasma lipids. Drugs which affect one or more of these factors are used to treat hyperlipoproteinemia. In order to elucidate the mechanism of action of hypolipidemic drugs it is necessary to understand the lipoprotein defect at the molecular level. This requires a more detailed knowledge of lipoprotein metabolism than is presently available for most of the hyperlipoproteinemias.

This paper will review some of the generally accepted properties of the plasma lipoproteins, describe some difficulties which hamper the understanding of lipoprotein metabolism, and identify possible mechanisms by which drugs may affect lipoprotein metabolism.     

On the structural similarity of ApoA-I and ApoA-II of human high density lipoproteins.

The possible evolutionary origin of apolipoproteins was studied by comparing the primary structures of different plasma apolipoproteins and other phospholipid-binding proteins. Apolipoprotein A-I (ApoA-I) and apolipoprotein A-II (ApoA-II) of human high density lipoprotein (HDL) are related. The resemblance of these two HDL apolipoproteins are apparently restricted to the carboxyl terminal regions suggesting that these portions of the molecules are derived from the same ancestor. The homologous carboxyl terminal segments may be involved in the regulation of HDL metabolism or in the interaction with phospholipids.     

Effects of threonine-poor apolipoproteins on post-heparin plasma hepatic triacylglycerol lipase and lipoprotein lipase

Whole-irradiated rabbit pre-heparin plasma had an important inhibitory effect on hepatic triacylglycerol lipase and lipoprotein lipase activities, whereas control rabbit pre-heparin plasma slightly inhibited hepatic triacylglycerol lipase activity at a high concentration and enhanced lipoprotein lipase activity. As some apolipoproteins were known to modulate these two lipolytic enzymes, the inhibitory effects of irradiated rabbit plasma were investigated in apolipoproteins. Three apolipoproteins, with isoelectric points of about 6.58, 6.44 and 6.12, characterized by their low content in threonine (threonine-poor apolipoproteins) were produced in high concentrations in rabbit VLDL and HDL after irradiation. The effects of these apolipoproteins on control rabbit post-heparin plasma hepatic triacylglycerol lipase and extrahepatic lipoprotein lipase were studied. Threonine-poor apolipoproteins substantially inhibited the hepatic triacylglycerol lipase activity and enhanced the apolipoprotein C-II-stimulated activity of lipoprotein lipase. The amounts of these apolipoproteins in triacylglycerol-rich lipoprotein particles may determine the lipolytic activity of lipoprotein lipase and hepatic triacylglycerol lipase in triacylglycerol hydrolysis. The existence of another inhibitor of lipoprotein lipase remains to be determined.     

Organization of the human cholesteryl ester transfer protein gene

The plasma cholesteryl ester transfer protein (CETP) catalyzes the transfer of phospholipids and neutral lipids between the lipoproteins. Thus, this protein may be important in modulating lipoprotein levels in the plasma. We have determined the primary structure and organization of the human CETP gene. Southern blotting of cellular DNA indicated a single copy of the CETP gene exists per haploid genome. Analysis of three overlapping genomic clones showed that the gene spans approximately 25 kbp and contains 16 exons (size range 32-250 bp). Overall, the sequence and organization of the CETP gene do not resemble those of other lipid-metabolizing enzymes or apolipoproteins. However, comparison of the CETP sequence, one exon at a time, with the sequences in the sequence databases revealed a striking identity of a pentapeptide sequence (ValLeuThrLeuAla) within the hydrophobic core of the signal sequences of human CETP, apolipoproteins A-IV and A-I, and lipoprotein lipase. This pentapeptide sequence was not found in the signal sequences of other proteins, suggesting that it may mediate a specialized function related to lipid metabolism or transport.     

Multidimensional profiling of plasma lipoproteins by size exclusion chromatography followed by reverse-phase protein arrays

The composition of lipoproteins and the association of proteins with various particles are of much interest in the context of cardiovascular disease. Here, we describe a technique for the multidimensional analysis of lipoproteins and their associated apolipoproteins. Plasma is separated by size exclusion chromatography (SEC), and fractions are analyzed by reverse-phase arrays. SEC fractions are spotted on nitrocellulose slides and incubated with different antibodies against individual apolipoproteins or antibodies against various apolipoproteins. In this way, tens of analytes can be measured simultaneously in 100 μl of plasma from a single SEC separation. This methodology is particularly suited to simultaneous analysis of multiple proteins that may change their distribution to lipoproteins or alter their conformation, depending on factors that influence circulating lipoprotein size or composition. We observed changes in the distribution of exchangeable apolipoproteins following addition of recombinant apolipoproteins or interaction with exogenous compounds. While the cholesteryl ester transfer protein (CETP)-dependent formation of pre-β-HDL was inhibited by the CETP inhibitors torcetrapib and anacetrapib, it was not reduced by the CETP modulator dalcetrapib. This finding was elucidated using this technique.     

Contributions of domain structure and lipid interaction to the functionality of exchangeable human apolipoproteins

Exchangeable apolipoproteins function in lipid transport as structural components of lipoprotein particles, cofactors for enzymes and ligands for cell-surface receptors. Recent findings with apoA-I and apoE suggest that the tertiary structures of these two members of the human exchangeable apolipoprotein gene family are related. Characteristically, these proteins contain a series of proline-punctuated, 11- or 22-amino acid, amphipathic alpha-helical repeats that can adopt a helix bundle conformation in the lipid-free state. The amino- and carboxyl-terminal regions form separate domains with the latter being primarily responsible for lipid binding. Interaction with lipid induces changes in the conformation of the amino-terminal domain leading to alterations in function; for example, opening of the amino-terminal four-helix bundle in apolipoprotein E upon lipid binding is associated with enhanced receptor-binding activity. The concept of a two-domain structure for the larger exchangeable apolipoproteins is providing new molecular insights into how these apolipoproteins interact with lipids and other proteins, such as receptors. The ways in which structural changes induced by lipid interaction modulate the functionality of these apolipoproteins are reviewed.     

Identification of apolipoproteins involved in the interaction of human high density lipoprotein3 with receptors on cultured cells

Human high density lipoprotein (HDL), devoid of apolipoproteins E or B, binds with high affinity and specificity to cultured cells derived from several tissues. In order to investigate the ligand specificity of the putative receptor, we have performed competitive inhibition studies to identify the components of high density lipoprotein that bind to cell surfaces of rat adrenal cortical cells and human skin fibroblasts. Radiolabeled HDL3 was displaced with unlabeled apolipoprotein-dimyristoylphosphatidylcholine recombinant particles containing AI, AII, CIII-1, and E apolipoproteins, but not by dimyristoylphosphatidylcholine complexed to albumin or by low density lipoprotein. Because exchange may readily occur between apolipoproteins in HDL and in recombinants this observation may not be truly representative of ligand competition. Further experiments using Fab fragments prepared from pure IgG to each apolipoprotein showed that binding of radioiodinated HDL to cells was suppressed following preincubation of HDL with Fab fragments raised against apolipoproteins AI or AII but not against apolipoproteins E or CIII-1 or albumin. In additional studies with apolipoprotein recombinants specific saturable binding was demonstrated between apo-AI or -AII recombinants and adrenocortical cells whereas binding of apo-CIII-2 was characterized by a large nonsaturable component which almost equaled the specific binding. The data, therefore, provide evidence for the involvement of the two major apolipoproteins (AI and AII) in HDL recognition by cellular receptors.     

Hep G2 cells as a resource for metabolic studies: lipoprotein, cholesterol, and bile acids

Hep G2, a liver cell line derived from a human hepatoblastoma that is free of known hepatotropic viral agents, has been found to express a wide variety of liver-specific metabolic functions. Among these functions are those related to cholesterol and triglyceride metabolism. Confluent Hep G2 monolayers express normal low-density lipoprotein (LDL) receptors and continue to internalize and metabolize chylomicrons, very low-density lipoproteins (VLDL), LDL, and high-density lipoproteins. In lipoprotein-free medium, apolipoproteins A-I, A-II, B, C, and E accumulate in the medium together with cholesterol, cholesteryl ester, triglyceride, and all the primary bile acids. The regulation of their synthesis and secretion is not fully known and their interrelationships have not been established. Because Hep G2 cells express these and other components of cholesterol and triglyceride metabolism, they are a microcosm for studying the central role of the liver.