Localization of human ATP-binding cassette transporter 1 (ABC1) in normal and atherosclerotic tissues.

The present study examines the expression of ATP-binding cassette transporter 1 (ABC1) mRNA in normal and atherosclerotic tissues by using in situ hybridization in an effort to better understand the function of this cholesterol transport protein. Samples of normal baboon tissues as well as human normal and atherosclerotic aortas were hybridized with (35)S-labeled ABC1 sense and antisense riboprobes. Widespread expression of ABC1 was observed generally in tissues containing inflammatory cells and lymphocytes. Other noninflammatory cells that were also sites of ABC1 synthesis included the ductal cells of the kidney medulla, Leydig cells in the testis, and glial cells in the baboon cerebellum. Although normal veins and arteries did not express ABC1 mRNA, it was found to be upregulated in the setting of atherosclerosis, where widespread expression was found in macrophages within atherosclerotic lesions. These results are consistent with the proposed role of ABC1 in cholesterol transport in inflammatory cells. The specific upregulation of ABC1 mRNA in the setting of atherosclerosis probably reflects the response of leukocytes to cholesterol loading. However, the presence of ABC1 in ductal cells of the kidney medulla and in the small intestine suggest a more general role for this protein in cholesterol transport in other cell types.

Membrane lipid domains distinct from cholesterol/sphingomyelin-rich rafts are involved in the ABCA1-mediated lipid secretory pathway.

Efflux of excess cellular cholesterol mediated by lipid-poor apolipoproteins occurs by an active mechanism distinct from passive diffusion and is controlled by the ATP-binding cassette transporter ABCA1. Here we examined whether ABCA1-mediated lipid efflux involves the selective removal of lipids associated with membrane rafts, plasma membrane domains enriched in cholesterol and sphingomyelin. ABCA1 was not associated with cholesterol and sphingolipid-rich membrane raft domains based on detergent solubility and lack of colocalization with marker proteins associated with raft domains. Lipid efflux to apoA-I was accounted for by decreases in cellular lipids not associated with cholesterol/sphingomyelin-rich membranes. Treating cells with filipin, to disrupt raft structure, or with sphingomyelinase, to digest plasma membrane sphingomyelin, did not impair apoA-I-mediated cholesterol or phosphatidylcholine efflux. In contrast, efflux of cholesterol to high density lipoproteins (HDL) or plasma was partially accounted for by depletion of cholesterol from membrane rafts. Additionally, HDL-mediated cholesterol efflux was partially inhibited by filipin and sphingomyelinase treatment. Apo-A-I-mediated cholesterol efflux was absent from fibroblasts with nonfunctional ABCA1 (Tangier disease cells), despite near normal amounts of cholesterol associated with raft domains and normal abilities of plasma and HDL to deplete cholesterol from these domains. Thus, the involvement of membrane rafts in cholesterol efflux applies to lipidated HDL particles but not to lipid-free apoA-I. We conclude that cholesterol and sphingomyelin-rich membrane rafts do not provide lipid for efflux promoted by apolipoproteins through the ABCA1-mediated lipid secretory pathway and that ABCA1 is not associated with these domains.

The effect of peroxisome-proliferator-activated receptor-alpha on the activity of the cholesterol 7 alpha-hydroxylase gene.

Cholesterol 7 alpha-hydroxylase (Cyp7a1) plays a central role in the regulation of bile acid and cholesterol metabolism, and transcription of the gene is controlled by bile acids and hormones acting through a complex interaction with a number of potential steroid-hormone-binding sites. Transcriptional activity of the human CYP7A1 gene promoter transfected into HepG2 cells was decreased in a concentration-dependent manner by co-transfection with an expression vector for peroxisome-proliferator-activated receptor-alpha (PPAR alpha). This effect was augmented by 9-cis-retinoic acid receptor-alpha (RXR alpha) and activators of PPAR alpha to give a maximum inhibition of approx. 80%. The region responsible for this inhibition contained a site known to bind hepatocyte nuclear factor 4 (HNF4), and mutation of this site greatly decreased the effect. Co-expression of HNF4 increased promoter activity and decreased the effect of PPAR alpha. Gel-mobility-shift assays failed to detect any binding of PPAR alpha/RXR alpha dimers to any regions of the promoter containing potential binding sites. Also the hepatic abundance of Cyp7a1 mRNA in mice in which the PPAR alpha gene was disrupted was the same as in normal mice, both during the dark phase, when the animals were feeding, and during the light phase, when mRNA abundance was greatly increased. Cholesterol feeding produced the same increase in hepatic Cyp7a1 mRNA abundance in PPAR alpha-null animals as in normals. It is concluded that, whereas PPAR alpha can affect CYP7A1 gene transcription in vitro through an indirect action, probably by competing for co-factors, this is unlikely to be a major influence on Cyp7a1 activity under normal physiological conditions.

Large scale gene expression analysis of cholesterol-loaded macrophages.

We conducted large scale gene expression analysis of the response of macrophages to exposure to oxidized low density lipoprotein (Ox-LDL). Much of the vessel wall lesion of atherosclerosis is composed of macrophages that have become engorged with cholesterol. These resulting "foam cells" contribute to the progression of vascular disease through several pathways. As a potential model of foam cell formation, we treated THP-1 cells with 12-O-tetradecanoylphorbol 13-acetate to differentiate them into a macrophage-like phenotype and subsequently treated them with oxidized low density lipoprotein for various time periods. RNA from Ox-LDL treated and time-matched control untreated cells was hybridized to microarrays containing 9808 human genes. 268 genes were found to be at least 2-fold regulated at one or more time points. These regulation patterns were classified into seven clusters of expression profiles. The data is discussed in terms of the overall pattern of gene expression, the thematic classification of the responding genes, and the clustering of functional groups in distinct expression patterns. The magnitude and the temporal patterns of gene expression identified known and novel molecular components of the cellular response that are implicated in the growth, survival, migratory, inflammatory, and matrix remodeling activity of vessel wall macrophages. In particular, the role of nuclear receptors in mediating the gene expression modulation by Ox-LDL is highlighted.

ABC1 gene expression and ApoA-I-mediated cholesterol efflux are regulated by LXR.

ATP-binding cassette transporter 1 (ABC1) mediates the active efflux of cholesterol from cells to apolipoproteins. To study the mechanisms of regulation of ABC1 gene expression, RAW 264.7 macrophages were transiently transfected with ABC1 promoter-luciferase reporter gene-fusion constructs. Transcription from a 1.64 kb fragment was induced by cholesterol loading but was not responsive to cAMP. Treatment of the cells with 9-cis retinoic acid or 20(S)-hydroxycholesterol, ligands for the nuclear receptors LXR and RXR, resulted in a marked induction of luciferase expression. The responsible control element was mapped to an imperfect direct repeat of the nuclear receptor half-site TGACCT separated by four bases (DR-4) that binds LXR/RXR heterodimers. Endogenous ABC1 gene expression in RAW cells and apolipoprotein A-I mediated cholesterol efflux were also upregulated by both receptor ligands. These findings raise the possibility that ligands that activate the LXR-RXR heterodimer may be useful for the therapeutic modulation of the ABC1 pathway.

ABCA1 is the cAMP-inducible apolipoprotein receptor that mediates cholesterol secretion from macrophages.

Lipid-poor high density lipoprotein apolipoproteins remove cholesterol and phospholipids from cells by an active secretory pathway controlled by an ABC transporter called ABCA1. This pathway is induced by cholesterol and cAMP analogs in a cell-specific manner. Here we provide evidence that increased plasma membrane ABCA1 accounts for the enhanced apolipoprotein-mediated lipid secretion from macrophages induced by cAMP analogs. Treatment of RAW264 macrophages with 8-bromo-cAMP caused parallel increases in apoA-I-mediated cholesterol efflux, ABCA1 mRNA and protein levels, incorporation of ABCA1 into the plasma membrane, and binding of apoA-I to cell-surface ABCA1. All of these parameters declined to near base-line values within 6 h after removal of 8-bromo-cAMP, indicating that ABCA1 is highly unstable and is degraded rapidly in the absence of inducer. Thus, ABCA1 is likely to be the cAMP-inducible apolipoprotein receptor that promotes removal of cholesterol and phospholipids from macrophages.

The Tangier disease gene product ABC1 controls the cellular apolipoprotein-mediated lipid removal pathway.

The ABC1 transporter was identified as the defect in Tangier disease by a combined strategy of gene expression microarray analysis, genetic mapping, and biochemical studies. Patients with Tangier disease have a defect in cellular cholesterol removal, which results in near zero plasma levels of HDL and in massive tissue deposition of cholesteryl esters. Blocking the expression or activity of ABC1 reduces apolipoprotein-mediated lipid efflux from cultured cells, and increasing expression of ABC1 enhances it. ABC1 expression is induced by cholesterol loading and cAMP treatment and is reduced upon subsequent cholesterol removal by apolipoproteins. The protein is incorporated into the plasma membrane in proportion to its level of expression. Different mutations were detected in the ABC1 gene of 3 unrelated patients. Thus, ABC1 has the properties of a key protein in the cellular lipid removal pathway, as emphasized by the consequences of its defect in patients with Tangier disease.

Transcription factors CCAAT/enhancer-binding protein beta and nuclear factor-Y bind to discrete regulatory elements in the very low density lipoprotein receptor promoter.

Expression of the very low density lipoprotein receptor (VLDL-R) is barely detectable in liver, but occurs in adipose tissue, skeletal muscle, heart, and placenta, where it is postulated to supply triglyceride to tissues that utilize fatty acids. To investigate its tissue-specific expression, cell lines were transfected with luciferase reporter gene constructs driven by the 5'-flanking region of the VLDL-R gene. Transcriptional activity of a 4.2-kb promoter fragment was 5-fold higher in BeWo placental cells than in Huh-7 hepatoma cells, consistent with relative endogenous expression of the VLDL-R. By deletion analysis, DNase I protection assays and site-directed mutagenesis, two regulatory elements were essential for maximal promoter activity in BeWo cells: footprint site D (-856 to -830) and an inverted CCAAT box (-703 to -707). Mutation of either element reduced promoter activity by 60% in BeWo cells, but had little effect in Huh-7 cells, suggesting that these elements direct cell-type specific transcription. Electrophoretic mobility-shift assays with BeWo nuclear extracts revealed that the inverted CCAAT box binds transcription factor NF-Y, and site D binds CCAAT/enhancer-binding protein b (C/EBPbeta) and minor amounts of C/EBPalpha and C/EBPdelta. Overexpression of a dominant negative NF-YA vector confirmed involvement of NF-Y in the regulation of the VLDL-receptor gene through the CCAAT box. However overexpression of C/EBP could not stimulate transcription from the VLDL-receptor promoter nor from site D fused to a heterologous promoter, suggesting that the simultaneous binding of an accessory factor(s) may be necessary for C/EBP transactivation via the D site.

Characterization of multiple enhancer regions upstream of the apolipoprotein(a) gene.

Plasma concentrations of the atherogenic lipoprotein(a) (Lp(a)) are predominantly determined by inherited sequences within or closely linked to the apolipoprotein(a) gene locus. Much of the interindividual variability in Lp(a) levels is likely to originate at the level of apo(a) gene transcription. However, the liver-specific apo(a) basal promoter is extremely weak and does not exhibit common functional variations that affect plasma Lp(a) concentrations. In a search for additional apo(a) gene control elements, we have identified two fragments with enhancer activity within the 40-kilobase pair apo(a)-plasminogen intergenic region that coincide with DNase I-hypersensitive sites (DHII and DHIII) observed in liver chromatin of mice expressing a human apo(a) transgene. Neither enhancer exhibits tissue specificity. DHIII activity was mapped to a 600-base pair fragment containing nine DNase I-protected elements (footprints) that stimulates luciferase expression from the apo(a) promoter 10-15-fold in HepG2 cells. Binding of the ubiquitous transcription factor Sp1 plays a major role in the function of this enhancer, but no single site was indispensable for activity. DHIII comprises part of the regulatory region of an inactive long interspersed nucleotide element 1 retrotransposon, raising the possibility that retrotransposon insertion can influence the regulation of adjacent genes. DHII enhancer activity was localized to a 180-base pair fragment that stimulates transcription from the apo(a) promoter 4-8-fold in HepG2 cells. Mutations within an Sp1 site or either of two elements composed of direct repeats of the nuclear hormone receptor half-site AGGTCA in this sequence completely abolished enhancer function. Both nuclear hormone receptor elements were shown to bind peroxisome proliferator-activated receptors and other members of the nuclear receptor family, suggesting that this enhancer may mediate drug and hormone responsiveness.

A mutation (T-45C) in the promoter region of the low-density-lipoprotein (LDL)-receptor gene is associated with a mild clinical phenotype in a patient with heterozygous familial hypercholesterolaemia (FH).

We have identified a rare mutation (T-45C) in the low density lipoprotein (LDL)-receptor gene in a Welsh patient with a clinical diagnosis of heterozygous familial hypercholesterolaemia (FH). The mutation is in the proximal Sp1 binding site in repeat 3 of the 42 bp region of the promoter required for sterol-dependent regulation of transcription, but the substituted nucleotide is not a strongly conserved base in the consensus sequence for Sp1 binding. Normal and mutant promoter fragments (from base -600 to -5) were linked to a luciferase reporter gene, and transient expression in COS cells showed that the mutation reduced transcriptional activity to approximately 43% of normal in the presence, and 25% in the absence of sterols in the medium. Competitive gel-shift mobility assays showed that the mutation reduced the binding affinity for transcription factor Sp1. Analysis of a neutral polymorphism in the LDL-receptor mRNA from the patient's lymphoblasts showed that expression of one allele was reduced. Since Southern blotting of genomic DNA and sequencing of the entire coding region of the LDL-R gene did not reveal any other potential defects, we infer that the T-45 C mutation is the underlying cause of hypercholesterolaemia in the proband.

The recurring evolution of lipoprotein(a). Insights from cloning of hedgehog apolipoprotein(a).

The lipoprotein Lp(a), a major inherited risk factor for atherosclerosis, consists of a low density lipoprotein-like particle containing apolipoprotein B-100 plus the distinguishing component apolipoprotein(a) (apo(a)). Human apo(a) contains highly repeated domains related to plasminogen kringle four plus single kringle five and protease-like domains. Apo(a) is virtually confined to primates, and the gene may have arisen during primate evolution. One exception is the occurrence of an Lp(a)-like particle in the hedgehog. Cloning of the hedgehog apo(a)-like gene shows that it is distinctive in form and evolutionary history from human apo(a), but that it has acquired several common features. It appears that the primate and hedgehog apo(a) genes evolved independently by duplication and modification of different domains of the plasminogen gene, providing a novel type of "convergent" molecular evolution.

C/T polymorphism in the 5' untranslated region of the apolipoprotein(a) gene introduces an upstream ATG and reduces in vitro translation.

Elevated plasma levels of lipoprotein(a) [Lp(a)] are a significant-independent risk factor for arteriosclerosis. Interindividual levels of Lp(a) vary nearly 1000-fold and are mainly due to inheritance that is linked to the locus of the apolipoprotein(a) [apo(a)] gene. A search was made for sequence variants in the 5' flanking region of the apo(a) gene that affect its expression. A C to T transition at position +93 from the transcription start site was found with a frequency of 14% in the study population. In transient transfection assays in HepG2 cells, luciferase reporter gene constructs with a T at this position were associated with a 58% reduction in luciferase activity compared with the more common allele. This single base variant had no significant effect on the binding of nuclear regulatory proteins; however, it introduced an additional upstream ATG initiation codon with its own in-frame stop codon. Furthermore, equivalent levels of mRNA were produced in HepG2 cells transfected with reporter gene constructs containing either a T or a C at position +93. In vitro translation experiments using transcripts derived from either variant apo(a) promoter revealed a 60% reduction in translation associated with the T allele. Hence, the additional ATG created by the T at position +93 in the 5' flanking region of the apo(a) gene impairs the efficiency of translation from the bona fide ATG initiation codon.

Apolipoprotein(a) gene transcription is regulated by liver-enriched trans-acting factor hepatocyte nuclear factor 1 alpha.

Elevated levels of lipoprotein(a) (Lp(a)) in the plasma are a risk factor for coronary artery disease and stroke. Plasma Lp(a) concentrations are highly heritable and predominantly determined by the liver-specific apolipoprotein(a) (apo(a)) gene. In this report we show by deletion analysis that sequences from -98 to +130 of the apo(a) gene are sufficient to direct liver-specific transcription. DNase I protection analysis of this region using HepG2 nuclear extracts revealed six major protein-binding sites, designated A to F. A mutation within footprint C, situated in the 5'-untranslated region of the gene, resulted in a marked reduction of luciferase expression from a reporter construct to 12% of wild type. This was not due to a decrease in mRNA stability. Gel mobility shift assays demonstrated that site C binds hepatocyte nuclear factor 1 alpha (HNF-1 alpha), and overexpression of HNF-1 alpha in HepG2 cells resulted in a significant stimulation of transcription from this promoter fragment. Mutation of footprint B resulted in a 2-fold enhancement of transcription. These results show that positive regulation of transcription of the apo(a) gene is dependent on the binding of HNF-1 alpha to a regulatory element situated downstream of the mRNA start site, and suggest that an as yet unidentified protein may negatively regulate apo(a) transcription by binding to a discrete sequence within the 5'-untranslated region.

Proliferation of human smooth muscle cells promoted by lipoprotein(a).

Elevated blood concentrations of lipoprotein(a) [Lp(a)] and its constituent, apolipoprotein(a) [apo(a)], constitute a major risk factor for atherosclerosis, but their physiological activities remain obscure. Lp(a) and purified apo(a) stimulated the growth of human smooth muscle cells in culture. This effect resulted from inhibition of plasminogen activation, and consequently the activation by plasmin of latent transforming growth factor-beta, which is an inhibitor of smooth muscle cell growth. Because smooth muscle proliferation is one of the hallmarks of atherosclerotic lesions, these results point to a plausible mechanism for the atherogenic activity of Lp(a).

5' control regions of the apolipoprotein(a) gene and members of the related plasminogen gene family.

Elevated blood levels of apolipoprotein(a), the component of lipoprotein(a) that distinguishes it from low density lipoprotein, are a major risk factor for atherosclerosis. The apolipoprotein(a) gene is highly similar to the plasminogen gene and to at least four other genes or pseudogenes. The 5' untranslated and flanking sequences of these six genes contain extensive regions of near identity and share sequence elements involved in the initiation of transcription and translation. About 1000 base pairs of flanking DNA of each gene are sufficient to promote transcription in cultured hepatocytes. The apolipoprotein(a) gene promoter contains functional interleukin 6-responsive elements, consistent with the reported acute-phase response of apolipoprotein(a). Flanking genomic fragments of the apoliprotein(a) gene from two individuals with vastly different plasma apolipoprotein(a) concentrations have sequence differences that are reflected in differences in the rate of in vitro transcription.

Atherogenesis in transgenic mice expressing human apolipoprotein(a)

Elevated plasma levels of the lipoprotein Lp(a) are associated with increased risk for atherosclerosis and its manifestations, myocardial infarction, stroke and restenosis (for reviews, see refs 1-3). Lp(a) differs from low-density lipoprotein by the addition of the glycoprotein apolipoprotein(a), a homologue of plasminogen that contains many tandemly repeated units which resemble the fourth kringle domain of plasminogen, and single homologues of its kringle-5 and protease domain. As plasma Lp(a) concentration is strongly influenced by heritable factors and is refractory to most drug and dietary manipulation, the effects of modulating it are difficult to mimic experimentally. In addition, the absence of apolipoprotein(a) from virtually all species other than primates precludes the use of convenient animal models. Here we show that transgenic mice expressing human apolipoprotein(a) are more susceptible than control mice to the development of lipid-staining lesions in the aorta, and that apolipoprotein(a) co-localizes with lipid deposition in the artery walls.

Detection and quantitation of apolipoprotein(a) mRNA in human liver and its relationship with plasma lipoprotein(a) concentration.

Northern blotting and hybridisation with specific probes was used to detect and quantitate apolipoprotein(a) (apo(a)) mRNA in total RNA isolated from 25 human liver samples. A total of 14 different transcripts were identified suggesting that there are at least 15 different alleles at the apo(a) locus including a probable null allele. Apo(a) mRNA sizes were linearly correlated with the electrophoretic mobility of plasma apo(a) glycoprotein isoforms, and differed, in many cases, by the equivalent of one Kringle 4 unit. To investigate the relationship between apo(a) mRNA size and its concentration in the liver, and between hepatic apo(a) mRNA concentration and plasma lipoprotein(a) (Lp(a)) levels, apo(a) mRNA was quantified by densitometric scanning of autoradiograms of Northern blots. Overall, there was a significant inverse correlation between apo(a) mRNA size and its concentration in the liver, despite a marked interindividual variability in the relative amounts of similar-sized transcripts. In each heterozygous individual, the difference in concentration between the two mRNA species was determined by the difference in size. However, there was not a significant relationship between hepatic apo(a) mRNA concentration and plasma Lp(a) levels in this group. These findings emphasise the importance of mechanisms other than the rate of transcription of the apo(a) gene in the regulation of Lp(a) synthesis.

Catabolism of lipoprotein(a) in familial hypercholesterolaemic subjects.

The in vivo turnover of autologous lipoprotein(a) (Lp(a)) was studied in four heterozygous familial hypercholesterolaemic (FH) subjects and four subjects who were hyperlipidaemic but not FH. Each of the FH subjects exhibited a much lower fractional catabolic rate (FCR) for LDL than each of the non-FH subjects. Lp(a) was purified by sequential density gradient centrifugations and was radio-iodinated. The labelled Lp(a) ran as a single band on electrophoresis in gradient polyacrylamide gels. Less than 5% of the label was in lipid, with about 40% of the remainder on apolipoprotein B (apo B) and 60% on apo(a). Labelled and unlabelled Lp(a) competed equally poorly with LDL for binding to LDL receptors on cultured fibroblasts. The FCR of Lp(a), calculated from the decay of the specific radioactivity of the Lp(a) isolated from the daily blood samples, was the same in FH subjects as in non-FH subjects. There was no consistent relationship between Lp(a) FCR and the plasma Lp(a) concentration or between FCR and the Lp(a) phenotype, at least within this sample of subjects. There was a strong association between Lp(a) concentration and production rate, with values for non-FH and FH subjects falling on the same line. The rate of decline of radioactivity in whole plasma was consistently slower than the fall in specific radioactivity of the isolated Lp(a). This difference was more marked in FH subjects than in non-FH subjects and resulted from the accumulation of radioactivity derived from the injected Lp(a) at a lower density than Lp(a), in the fractions containing LDL. The amount of radioactivity in this fraction increased for the first few days after injection and then fell, the fall being more rapid in non-FH than in FH subjects. These results provide no evidence for the involvement of LDL receptors in the catabolism of Lp(a) itself but suggest that they could be responsible for some of the clearance of the lipid and apo B components after removal of apo(a) in the circulation.