Isolation and characterization of LRP6, a novel member of the low density lipoprotein receptor gene family

A novel member of the low density lipoprotein receptor (LDLR) gene family has been identified and characterized. This gene, termed LDL receptor-related protein 6 (LRP6), encodes a transmembrane protein which has 71% identity and is structurally similar to the protein encoded by LRP5, a proposed candidate gene for type 1 diabetes located on human chromosome 11q13. LRP6 maps to human chromosome 12p11-p13. Mouse Lrp6 encodes a protein that has 98% identity to human LRP6 and maps to chromosome 6. Unlike other members of the LDLR family, LRP6 and LRP5 display a unique pattern of four epidermal growth factor (EGF) and three LDLR repeats in the extracellular domain. The cytoplasmic domain of LRP6 is not similar to other members of the LDLR family, while comparison with LRP5 reveals proline-rich motifs that may mediate protein-protein interactions. Thus, it is likely that LRP6 and LRP5 comprise a new class of the LDLR family.     

Macrophage oxidative modification of low density lipoprotein occurs independently of its binding to the low density lipoprotein receptor

The oxidative modification of low density lipoproteins (LDL) by arterial wall cells is thought to contribute to atherogenesis. Monocyte/macrophages, among other arterial wall cells, oxidatively modify LDL to a form that is recognized by scavenger/oxidized LDL receptors. It has recently been suggested that LDL binding to the LDL receptor (B/E receptor) is essential for macrophage-mediated oxidation of LDL. In the present study, we compared the ability of resident peritoneal macrophages from LDL-R-deficient (LDLR-/-) mice to oxidize LDL with that of resident peritoneal macrophages from C57B6 mice. The LDLR-/- macrophages oxidized LDL at least as rapidly as did the C57B6 macrophages both in F-10 medium and in Dulbecco's modified Eagle's medium supplemented with 1 microM copper (DMEM-Cu2+). Studies were also conducted to examine the effect of preincubation of LDLR-/- and C57B6 macrophages with 10% lipoprotein-deficient serum (LPDS), which up-regulates LDL receptors, or with acetylated LDL (Ac-LDL), which increases cellular cholesterol and down-regulates LDL receptors. Preincubation with 10% LPDS had no significant effect on subsequent LDL oxidation by either type of cells in F10 medium, but the C57B6 cells did show a small (18%) but significant increase in LDL oxidation in DMEM-Cu2+. Preincubation with 50 micrograms/ml Ac-LDL in F10 medium had no effect on LDL oxidation by either LDLR-/- or C57B6 macrophages. Preincubation with 100 micrograms/ml Ac-LDL had no effect on subsequent LDL oxidation by C57B6 cells but, unexpectedly, caused a modest (26%) fall in LDL oxidation by the receptor-negative cells. Using DMEM-Cu2+ medium, preincubation with Ac-LDL reduced LDL oxidation substantially (50-66%) but the effect was just as great in LDL-R negative cells (59-66%) as in C57B6 cells (50-58%), suggesting that the effect is not due to changes in LDL receptor density. It may be related somehow to the Ac-LDL-induced increase in cell cholesterol content. The data demonstrate that the absence of LDL receptors does not reduce the ability of macrophages to oxidize LDL and that LDL binding to LDL receptors is not an essential requirement for macrophage oxidation of LDL.     

Catalytically inactive lipoprotein lipase expression in muscle of transgenic mice increases very low density lipoprotein uptake: direct evidence that lipoprotein lipase bridging occurs in vivo

Lipoprotein lipase (LPL) is the central enzyme in plasma triglyceride hydrolysis. In vitro studies have shown that LPL also can enhance lipoprotein uptake into cells via pathways that are independent of catalytic activity but require LPL as a molecular bridge between lipoproteins and proteoglycans or receptors. To investigate whether this bridging function occurs in vivo, two transgenic mouse lines were established expressing a muscle creatine kinase promoter-driven human LPL (hLPL) minigene mutated in the catalytic triad (Asp156 to Asn). Mutated hLPL was expressed only in muscle and led to 3,100 and 3,500 ng/ml homodimeric hLPL protein in post-heparin plasma but no hLPL catalytic activity. Less than 5 ng/ml hLPL was found in preheparin plasma, indicating that proteoglycan binding of mutated LPL was not impaired. Expression of inactive LPL did not rescue LPL knock-out mice from neonatal death. On the wild-type (LPL2) background, inactive LPL decreased very low density lipoprotein (VLDL)-triglycerides. On the heterozygote LPL knock-out background (LPL1) background, plasma triglyceride levels were lowered 22 and 33% in the two transgenic lines. After injection of radiolabeled VLDL, increased muscle uptake was observed for triglyceride-derived fatty acids (LPL2, 1.7x; LPL1, 1.8x), core cholesteryl ether (LPL2, 2.3x; LPL1, 2.7x), and apolipoprotein (LPL1, 1.8x; significantly less than cholesteryl ether). Skeletal muscle from transgenic lines had a mitochondriopathy with glycogen accumulation similar to mice expressing active hLPL in muscle. In conclusion, it appears that inactive LPL can act in vivo to mediate VLDL removal from plasma and uptake into tissues in which it is expressed.     

Ligand specificity of LOX-1, a novel endothelial receptor for oxidized low density lipoprotein

Endothelial dysfunction, or activation, elicited by oxidized low density lipoprotein (Ox-LDL) and its lipid constituents has been shown to play a key role in the pathogenesis of atherosclerosis. We recently have identified a novel receptor for Ox-LDL-designated lectin-like Ox-LDL receptor (LOX-1) in vascular endothelial cells. To examine ligand specificity of LOX-1, we established CHO cell lines stably expressing both human and bovine LOX-1 (LOX-1-CHO). LOX-1-CHO bound and degraded 125I-labeled Ox-LDL but did not significantly degrade 125I-labeled acetylated LDL (Ac-LDL). Fucoidin and maleylated BSA (M-BSA), which inhibit 125I-Ox-LDL binding to class A scavenger receptors, did not inhibit 125I-Ox-LDL binding or degradation in LOX-1-CHO. Polyinosinic acid and carrageenan, in contrast, significantly reduced 125I-Ox-LDL binding to LOX-1-CHO by 62% and 60%, respectively. Delipidated and untreated 125I-Ox-LDL were bound and degraded equally in LOX-1-CHO; furthermore, excess amounts of unlabeled, delipidated Ox-LDL inhibited binding and degradation of untreated 125I-Ox-LDL. Taken together, LOX-1 is a receptor for Ox-LDL but not for Ac-LDL. LOX-1 recognizes protein moiety of Ox-LDL, and its ligand specificity is distinct from other receptors for Ox-LDL, including class A and B scavenger receptors.     

The low density lipoprotein receptor gene family. Differential expression of two alpha2-macroglobulin receptors in the brain

LR7/8B is a member of the low density lipoprotein receptor gene family that is specifically synthesized in the brain. Here we have functionally expressed in 293 cells the splice variant harboring eight ligand binding repeats (LR8B). As assessed by confocal microscopy, the expressed receptor is localized to the plasma membrane. Importantly, in cell binding experiments, we demonstrate that this protein is a receptor for activated alpha2-macroglobulin. Because to date low density lipoprotein receptor-related protein (LRP) has been shown to be the only alpha2-macroglobulin receptor in brain, we became interested in the expression pattern of both proteins at the cellular level in the brain. LR7/8B is expressed in large neurons and Purkinje cells of the cerebellum and in cells constituting brain barrier systems such as the epithelial cells of the choroid plexus, the arachnoidea, and the endothelium of penetrating blood vessels. Anti-LR7/8B antibody stains the plasma membrane, dendrites, and vesicular structures close to the cell membrane of neurons, especially of Purkinje cells. In contrast, LRP is present in patchy regions around large neurons and most prominently in the glomeruli of the stratum granulare of the cerebellum. This suggests that, contrary to LR7/8B, LRP is expressed in synaptic regions of the neurons; furthermore, there is a striking difference in the expression patterns of LR7/8B and LRP in the choroid plexus. Whereas LRP shows baso-lateral and apical localization in the epithelial cells, LR7/8B is restricted to the apical cell aspect facing the cerebrospinal fluid. Finally, these studies were extended to cultured primary rat neurons, where double immunofluorescence labeling with anti-LR7/8B and anti-microtubuli-associated protein 2 (MAP2) confirmed the somatodendritic expression of the receptor. Based upon these data, we propose that LR7/8B is involved in the clearance of alpha2-macroglobulin.proteinase complexes and/or of other substrates bound to alpha2-macroglobulin from the cerebrospinal fluid and from the surface of neurons.     

Calcium induces a conformational change in the ligand binding domain of the low density lipoprotein receptor

TNF-alpha may play a role in mediating insulin resistance associated with obesity. This concept is based on studies of obese rodents and humans, and cell culture models. TNF elicits cellular responses via two receptors called p55 and p75. Our purpose was to test the involvement of TNF in glucose homeostasis using mice lacking one or both TNF receptors. C57BL/6 mice lacking p55 (p55(-)/-), p75, (p75(-)/-), or both receptors (p55(-)/-p75(-)/-) were fed a high-fat diet to induce obesity. Marked fasting hyperinsulinemia was seen for p55(-)/-p75(-)/- males between 12 and 16 wk of feeding the high-fat diet. Insulin levels were four times greater than wild-type mice. In contrast, p55(-)/- and p75(-)/- mice exhibited insulin levels that were similar or reduced, respectively, as compared with wild-type mice. In addition, high-fat diet-fed p75(-)/- mice had the lowest body weights and leptin levels, and improved insulin sensitivity. Obese (db/db) mice, which are not responsive to leptin, were used to study the role of p55 in severe obesity. Male p55(-)/-db/db mice exhibited threefold higher insulin levels and twofold lower glucose levels at 20 wk of age than control db/db expressing p55. All db/db mice remained severely insulin resistant based on fasting plasma glucose and insulin levels, and glucose and insulin tolerance tests. Our data do not support the concept that TNF, acting via its receptors, is a major contributor to obesity-associated insulin resistance. In fact, data suggest that the two TNF receptors work in concert to protect against diabetes.     

Effect of low density lipoprotein on adenosine receptor-mediated coronary vasorelaxation in vitro

We investigated the effect of low density lipoprotein (LDL) on vasorelaxations and nitric oxide generation induced by the adenosine analogs, 5'-(N-ethylcarboxamide)adenosine, 2-p-(2-carboxyethyl)phenylethyl-amino-5'N-ethylcarboxamidoadenosine and/or 2-chloroadenosine in porcine coronary artery rings in vitro. Preincubation of tissues with native LDL (100 and 200 microg/ml) for 4 hr in the absence or presence of copper sulfate (5 microM) selectively attenuated the endothelium-dependent relaxations elicited by 5'-(N-ethylcarboxamide)adenosine and 2-p-(2-carboxyethyl)phenylethyl-amino-5'N-ethylcarboxamideoadenosine+ ++ without altering the response to 2-chloroadenosine which produced endothelium-independent relaxation. The 4-hr exposure of tissues to native LDL (100 microg/ml) also inhibited the production of nitrite induced by 5'-(N-ethylcarboxamide)adenosine in endothelium-intact rings. These effects were associated with enhanced oxidation of the lipoprotein. The inhibitory action of LDL on tissue relaxations and nitrite generation as well as the oxidation of the lipoprotein were all prevented by high density lipoprotein (100 microg/ml). In contrast, a relatively short period (20 min) of tissue incubation with native LDL produced no alterations of the relaxations and nitrite production evoked by 5'-(N-ethylcarboxamide)adenosine and 2-p-(2-carboxyethyl)phenylethyl-amino-5'N-ethylcarboxamidoadenosine. Under this condition, the oxidation of LDL was not also significantly altered. In conclusion, the results indicate that in coronary artery LDL, with oxidative modification, causes attenuation of nitric oxide-mediated endothelial responses induced by adenosine receptors activation, and this effect is prevented by high density lipoprotein. Such modulation may be of importance in hypercholesterolemia and in the development of atherosclerosis.     

Lipoprotein lipase induces catabolism of normal triglyceride-rich lipoproteins via the low density lipoprotein receptor-related protein/alpha 2-macroglobulin receptor in vitro. A process facilitated by cell-surface proteoglycans

Bovine milk lipoprotein lipase (LPL) induced binding, uptake, and degradation of 125I-labeled normal human triglyceride-rich lipoproteins by cultured mutant fibroblasts lacking LDL receptors. The induction was dose-dependent and occurred whether LPL and 125I-lipoproteins were added to incubation media simultaneously or LPL was allowed to bind to cell surfaces, and unbound LPL was removed by washing prior to the assay. Lipolytic modification of lipoproteins did not appear to be necessary for increased catabolism because the effect of LPL was not prevented by inhibitors of LPL's enzymatic activity, p-nitrophenyl N-dodecylcarbamate or phenylmethylsulfonyl fluoride. However, the effect was abolished by boiling LPL prior to the assay suggesting that major structural features of LPL were required. Also, LPL-induced binding to cells was blocked by an anti-LPL monoclonal antibody but not by antibodies that are known to block apolipoprotein E- or B-100-mediated binding to low density lipoprotein (LDL) receptors. This indicates that LPL itself mediated 125I-lipoprotein binding to cells. Cellular degradation of 125I-lipoproteins was partially or completely blocked by two previously described ligands for the LDL receptor-related protein/alpha 2-macroglobulin receptor (LRP): activated alpha 2-macroglobulin (alpha 2M*), and the 39-kDa receptor-associated protein. These data implicated LRP as mediating LPL-induced lipoprotein degradation and were confirmed by showing that LPL's effects were prevented by an immunoaffinity-isolated polyclonal antibody against LRP. Furthermore, LPL promoted binding of 125I-lipoproteins to highly purified LRP in a solid-phase assay. Heparin or heparinase treatment of cells markedly decreased LPL-induced binding, uptake, and degradation of lipoproteins, but had no effect on catabolism of alpha 2M*. Thus, cell-surface proteoglycans were obligatory participants in the effects of LPL but were not required for LRP-mediated catabolism of alpha 2M*. Taken together, these in vitro findings establish that through interaction with cell-surface proteoglycans, LPL induces catabolism of normal human triglyceride-rich lipoproteins via LRP.     

Receptors of the low density lipoprotein (LDL) receptor family in man. Multiple functions of the large family members via interaction with complex ligands

The LDL receptor family members are endocytic receptors composed of repeated protein modules, including clusters of ligand binding LDL receptor class A (LA) repeats. The large (approximately 600 kDa) members LRP and megalin bind numerous structurally unrelated and often complex ligands at different combinations of sites. LRP is expressed in a wide but restricted set of cell types including hepatocytes, macrophages, smooth muscle cells, and neurons of the CNS. Megalin is expressed in various epithelia including proximal kidney tubules, intestine, and ependymal cells. The two receptors share a multitude of ligands, and their function in vivo is therefore to a large extent determined by their expression pattern. For example, both receptors can endocytose lipoproteins, but this function appears mainly relevant for LRP. In addition, LRP helps regulating urokinase receptor expression on the cell surface via ligand-mediated internalization followed by return of the naked urokinase receptor to the cell surface. Both receptors also have specialist functions. LRP is specific for binding of alpha2-macroglobulin-proteinase complexes and provides clearance of the complexes and of peptides, e.g. cytokines, associated with the complex. Megalin has important functions in vitamin B12 homeostasis since it specifically mediates uptake of the vitamin B12-transcobalamin complex and helps building a storage pool for the vitamin in the kidneys. Moreover, megalin binds cubilin, the recently identified receptor for B12-intrinsic factor complex, thus providing a mechanism for uptake of dietary vitamin B12. Finally, megalin specifically mediates uptake of apolipoprotein J/clusterin, a binding protein for the Abeta peptide implicated in Alzheimer's disease. The binding of multiple complex ligands that belong to distinct physiological systems provides a challenge in future studies aiming at elucidating the role of LRP and megalin in disease mechanisms.     

In-vitro carboxymethylation of low density lipoprotein alters its metabolism via the high-affinity receptor

Carboxymethylation of lysine residues has been shown to result from oxidation of glycated proteins in vivo and in vitro leading to an augmentation of proteins' net negative charge. The metabolism of carboxymethylated low density lipoprotein (LDL) was studied in cultured human fibroblasts and mouse peritoneal macrophages. In vitro carboxymethylation was achieved by incubation of LDL with glyoxylic acid in the presence of Na(CN)BH3. Carboxymethylation inhibited metabolism of LDL via the high affinity receptor in fibroblasts as did methylation. The uptake of LDL into mouse peritoneal macrophages via the scavenger receptor, which was stimulated by acetylation, was not affected.     

Hepatic apo E expression is required for remnant lipoprotein clearance in the absence of the low density lipoprotein receptor

According to the secretion-capture model of remnant lipoprotein clearance, apo E secreted by hepatocytes into the space of Disse serves to enrich the remnants with a ligand for receptor-mediated lipoprotein endocytosis. Current evidence supports a two-receptor model of lipoprotein removal, in which apo E-containing remnants bind either the low density lipoprotein receptor (LDLR) or the LDLR-related protein (LRP). Recently, we demonstrated that reconstitution of apo E(-/-) mice with apo E(+/+) marrow results in normalization of plasma lipoprotein levels, indicating that hepatic expression of apo E is not required for remnant clearance and calling into question the relevance of the secretion-capture mechanism. To dissect the relative contributions of LDLR and LRP to the cellular catabolism of remnant lipoproteins by the hepatocyte, bone marrow transplantation (BMT) was used to reconstitute macrophage expression of apo E in mice that were null for expression of both apo E and the LDLR. Reconstitution of macrophage apo E in apo E(-/-)/LDLR(-/-) mice had no effect on serum lipid and lipoprotein concentrations, although it produced plasma apo E levels up to 16-fold higher than in C57BL/6 controls. Immunocytochemistry of hepatic sections revealed abundant staining for apo E in the space of Disse, but no evidence of receptor-mediated endocytosis of remnant lipoproteins. Transient expression of human LDLR in the livers of apo E(+/+)--> apo E(-/-)/LDLR(-/-) mice by adenoviral gene transfer resulted in normalization of serum lipid levels and in the clearance of apo E-containing lipoproteins from the space of Disse. We conclude that whereas the LDLR efficiently clears remnant lipoproteins irrespective of the site of origin of apo E, endocytosis by the chylomicron remnant receptor (LRP) is absolutely dependent on hepatic expression of apo E. These data demonstrate in vivo the physiologic relevance of the apo E secretion-capture mechanism in the liver.     

Regulation of mRNA encoding low density lipoprotein receptor and high density lipoprotein-binding protein in ovine corpora lutea

Three experiments were conducted to examine the regulation of steady-state concentrations of mRNA encoding ovine low density lipoprotein receptor (LDL-R) and high density lipoprotein-binding protein (HBP) in corpora lutea. In Experiment 1, corpora lutea were collected from ewes on Days 3, 6, 9, 12 and 15 (Day 0, oestrus) of the oestrous cycle. Enriched preparations of small and large steroidogenic luteal cells were also obtained on Days 6, 9, 12 and 15 of the oestrous cycle. In Experiment 2, 16 ewes were hypophysectomized on Day 5 of the oestrous cycle and received saline, luteinizing hormone (LH), growth hormone (GH) or a combination of LH+GH until collection of luteal tissue on Day 12 of the oestrous cycle. Corpora lutea were also collected from pituitary-intact control ewes on Day 5 and Day 12 of the oestrous cycle. In Experiment 3, 13 ewes on Day 11 or Day 12 of the oestrous cycle were administered prostaglandin F2 alpha (PGF2 alpha) and corpora lutea were collected 4 h, 12 h and 24 h later. Corpora lutea were also collected from 4 non-injected and 4 saline-injected (at 24 h) ewes. Results demonstrated that concentrations of mRNA encoding LDL-R did not differ throughout the oestrous cycle. Luteal tissue collected on Day 3 of the oestrous cycle had higher concentrations of mRNA encoding HBP than luteal tissue collected on any other day of the oestrous cycle. Hypophysectomy increased concentrations of mRNA encoding LDL-R but had no effect on concentrations of mRNA encoding HBP. Twelve hours following PGF2 alpha injection concentrations of mRNA encoding LDL-R were decreased but concentrations of mRNA encoding HBP were increased. Concentrations of both LDL-R and HBP mRNA were decreased 24 h following injection of PGF2 alpha. Thus, long-term positive and acute negative regulation of progesterone secretion from the corpus luteum by luteotrophic and luteolytic hormones was not mediated by changes in steady-state concentrations of mRNA encoding LDL-R or HBP.     

The role of a triplet repeat sequence of the very low density lipoprotein receptor gene in plasma lipid and lipoprotein level variability in humans

The biological role of the very low density lipoprotein receptor (VLDL-R) in humans is not yet elucidated. This cellular receptor binds apolipoprotein E (apoE)-containing lipoparticles and is mainly expressed in peripheral tissues. The VLDL-R gene contains a polymorphic triplet (CGG) repeat located 19 bp upstream of the initiation codon. We explored the allelic distribution of this repeat in 1384 subjects of European Caucasian origin, 609 of them surviving a myocardial infarction. Six alleles corresponding to 5, 6, 7, 8, 9, and 11 repeats were detected in this population. The alleles 5, 8, and 9 were the most frequent, with frequencies of 0.413, 0.275, and 0.292, respectively. No association was found between the VLDL-R polymorphism and myocardial infarction. In controls without lipid lowering treatment, a statistically significant interaction between VLDL-R genotype and apoE phenotype was found for plasma triglycerides (P < .04), suggesting a gene-gene interaction. There was also a main effect of the VLDL-R polymorphism on LpE:B and LpA-I. The VLDL-R 9 allele was associated with lower levels of plasma LpE:B (P < .05) and higher concentrations of plasma LpA-I (P < .01) than the other alleles. These results suggest that VLDL-R has a modest influence on circulating lipoproteins in humans.     

Glycolaldehyde-modified low density lipoprotein leads macrophages to foam cells via the macrophage scavenger receptor

It was shown that proteins modified with advanced glycation end products (AGE) are effectively endocytosed by macrophages or macrophage-derived cells in vitro, and immunohistochemical studies involving anti-AGE antibodies demonstrated the accumulation of AGE-modified proteins (AGE-proteins) in macrophage-derived foam cells in human atherosclerotic lesions in situ, suggesting the involvement of AGE-modified LDL in the atherogenic process in vivo. To examine this suggestion, LDL was modified with glycolaldehyde, a highly reactive intermediate of the Maillard reaction. Physicochemically, glycolaldehyde-modified LDL (GA-LDL) was characterized by increases in negative charge, fluorescence intensity, and reactivity to anti-AGE antibodies, properties highly similar to those of AGE-proteins. The cellular interaction of GA-LDL with mouse peritoneal macrophages showed that GA-LDL was specifically recognized and endocytosed, followed by lysosomal degradation. The endocytic uptake of GA-LDL by these cells was competitively inhibited by acetylated LDL (acetyl-LDL), and the endocytic degradation of acetyl-LDL was also competed for by GA-LDL. Furthermore, incubation of GA-LDL with these macrophages and Chinese hamster ovary cells overexpressing the macrophage scavenger receptor (MSR), but not with peritoneal macrophages from MSR-knockout mice, led to the intracellular accumulation of cholesteryl esters (CE). These results raised the possibility that AGE-modified LDL, if available in situ, is taken up by macrophages mainly via MSR and then contributes to foam cell formation in early atherosclerotic lesions.     

Decreased atherosclerosis in heterozygous low density lipoprotein receptor-deficient mice expressing the scavenger receptor BI transgene

Scavenger receptor type B class I (SR-BI), initially identified as a receptor that recognizes low density lipoprotein (LDL), was recently shown to mediate the selective uptake of high density lipoprotein (HDL) cholesteryl esters in liver and steroidogenic tissues. To evaluate effects on atherosclerosis, transgenic mice with liver-specific overexpression of SR-BI (SR-BI Tg mice) have been crossed onto LDL receptor-deficient backgrounds. To induce atherosclerosis in a setting of moderate hypercholesterolemia, heterozygous LDL receptor-deficient mice (LDLR1) were fed a high fat/cholesterol/bile salt diet, and homozygous LDL receptor knock-outs (LDLR0) were fed a high fat/cholesterol diet. LDLR1/SR-BI Tg mice showed decreases in VLDL, LDL, and HDL cholesterol and a significant 80% decrease in mean lesion area in the aortic root compared with LDLR1 mice (female LDLR1 74, 120 micrometers(2) versus LDLR1/SR-BI Tg 12, 667 micrometers(2); male 25, 747 micrometers(2)++ versus 5, 448 micrometers(2), respectively). LDLR0/SR-BI Tg mice showed decreased LDL and HDL cholesterol but increased VLDL cholesterol and no significant difference in extent of atherosclerosis compared with LDLR0 mice. Combined data analysis showed a strong correlation between atherosclerotic lesion area and the VLDL+LDL cholesterol level but no correlation with HDL level. These studies demonstrate a strong anti-atherogenic potential of hepatic SR-BI overexpression. In mice with marked overexpression of SR-BI, the protective effect appears to be primarily related to the lowering of VLDL and LDL cholesterol levels.     

A nonexchangeable apolipoprotein E peptide that mediates binding to the low density lipoprotein receptor

ApoE is a 34-kDa apoprotein that mediates lipoprotein binding to the low density lipoprotein (LDL) receptor and to the LDL receptor-related protein. Receptor binding is mediated by a highly basic, alpha-helical sequence of approximately 15 amino acids that interacts with cysteine-rich repeat regions of the receptor. To determine the relationship between the receptor binding and lipid associating properties of apoE, we have synthesized a series of apoE peptides containing all (residues 129-169) or part (residues 139-169, 144-169, and 148-169) of the receptor-binding domain. The lipophilicity of these peptides was increased by modification of their N termini by acylation with either palmitic acid (C16-apoE peptide) or the N,N-distearyl derivative of glycine (diC18-Gly-apoE peptide). The unmodified peptides demonstrated low affinity for lipid surfaces (Kd > 10(-5) M) and moderate alpha-helicity in the presence of lipid (40%) and had no effect on LDL uptake by fibroblasts. N-Palmitoyl peptides had increased affinity for lipid (Kd approximately 10(-6) M) and increased alpha-helicity (55%) in the presence of lipid. The addition of the C16-apoE-(129-169)-peptide to 125I-LDL enhanced its uptake and degradation by fibroblasts 8-10-fold; however, < 50% of the degradation was mediated by the LDL receptor. By contrast, the diC18-Gly-apoE-(129-169)-peptide was essentially nonexchangeable (Kd < or = 10(-9) M) and highly helical (78%) in the presence of lipid. The addition of the diC18-Gly-apoE-(129-169)-peptide to 125I-LDL enhanced the specific uptake and degradation of LDL by both LDL receptor-mediated and non-LDL receptor-mediated mechanisms. Uptake and degradation of methylated LDL containing diC18-Gly-apoE-(129-169) revealed that the lipoprotein-bound peptide is the active agent. In agreement with this finding, a mutant diC18-Gly-apoE peptide (Arg142-->Gln) was much less effective than the wild-type peptide in potentiating binding, uptake, and degradation of 125I-LDL. Complexes of diC18-Gly-apoE-(129-169), apoA-I, and 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine containing four to six copies of the peptide/particle displayed an affinity for the LDL receptor similar to that of apoE-L-alpha-dimyristoylphosphatidylcholine discs containing four copies of apoE.(ABSTRACT TRUNCATED AT 400 WORDS)     

Identification of a common low density lipoprotein receptor mutation (C163Y) in the west of Scotland

BACKGROUND: The pathological processes by which Helicobacter pylori infection leads to the development of gastroduodenal disease are still incompletely understood. Oxygen-derived free radicals are important mediators of inflammation and potential carcinogens. Furthermore, dietary studies have suggested that antioxidant vitamins may protect against gastric cancer. OBJECTIVE: To determine plasma free radical activity and antioxidant vitamin levels in dyspeptic patients and to correlate the results with H. pylori infection and tobacco smoking. SUBJECTS: Forty-three patients undergoing routine endoscopy for investigation of dyspepsia. METHODS: Plasma free radical activity was determined by measurement of thiobarbituric acid-reactive substances (TBARS). Plasma samples were also assayed for the antioxidant vitamins A, C and E. Gastroduodenal biopsies were obtained from all patients for histological examination. RESULTS: Plasma TBARS levels were significantly higher in H. pylori positive versus negative subjects (P < 0.03), smokers versus non-smokers (P < 0.04) and males versus females (P < 0.01). Multiple regression analysis revealed that after correcting for male sex and smoking there was no significant association between plasma free radical activity and H. pylori infection. Smokers had significantly lower levels of plasma vitamin C than non-smokers (P< 0.05); no differences were seen in vitamin A and E levels. Gender and H. pylori infection did not significantly affect plasma antioxidant vitamin levels. Gastroduodenal disease was present in all of the smokers compared with 67% of the non-smokers (P < 0.05); 69% of the smokers were H. pylori positive versus 53% of the non-smokers. CONCLUSIONS: Tobacco smoking and male sex, both recognized risk factors for gastroduodenal disease, appear to be the major determinants of increased plasma free radical activity in dyspeptic subjects, rather than H. pylori infection. The reason for the higher prevalence of H. pylori infection and gastroduodenal disease in dyspeptic smokers is unclear but may relate to weakened antioxidant defences.     

Linkage of low-density lipoprotein size to the lipoprotein lipase gene in heterozygous lipoprotein lipase deficiency

Small low-density lipoprotein (LDL) particles are a genetically influenced coronary disease risk factor. Lipoprotein lipase (LpL) is a rate-limiting enzyme in the formation of LDL particles. The current study examined genetic linkage of LDL particle size to the LpL gene in five families with structural mutations in the LpL gene. LDL particle size was smaller among the heterozygous subjects, compared with controls. Among heterozygous subjects, 44% were classified as affected by LDL subclass phenotype B, compared with 8% of normal family members. Plasma triglyceride levels were significantly higher, and high-density lipoprotein cholesterol (HDL-C) levels were lower, in heterozygous subjects, compared with normal subjects, after age and sex adjustment. A highly significant LOD score of 6.24 at straight theta=0 was obtained for linkage of LDL particle size to the LpL gene, after adjustment of LDL particle size for within-genotype variance resulting from triglyceride and HDL-C. Failure to adjust for this variance led to only a modest positive LOD score of 1.54 at straight theta=0. Classifying small LDL particles as a qualitative trait (LDL subclass phenotype B) provided only suggestive evidence for linkage to the LpL gene (LOD=1. 65 at straight theta=0). Thus, use of the quantitative trait adjusted for within-genotype variance, resulting from physiologic covariates, was crucial for detection of significant evidence of linkage in this study. These results indicate that heterozygous LpL deficiency may be one cause of small LDL particles and may provide a potential mechanism for the increase in coronary disease seen in heterozygous LpL deficiency. This study also demonstrates a successful strategy of genotypic specific adjustment of complex traits in mapping a quantitative trait locus.