Cultured human hepatocytes. Evidence for metabolism of low density lipoproteins by a pathway independent of the classical low density lipoprotein receptor

Studies of low density lipoprotein (LDL) metabolism in nonhuman model systems have indicated that the mammalian liver has dual mechanisms for the uptake and regulation of the concentration of plasma LDL. Heretofore, direct evaluation of lipoprotein uptake mechanisms in human hepatocytes has not been possible. In order to compare hepatocyte LDL uptake with fibroblast LDL metabolism, human hepatocytes were isolated and cultured from small biopsy specimens obtained from normolipidemic and homozygous familial hypercholesterolemic patients. Cells cultured in serum-free culture medium retained the morphological and biochemical characteristics of hepatocytes for at least 7 days. The uptake and degradation of LDL by hepatocytes was compared to that of the cultured human fibroblasts. Like fibroblasts, hepatocytes bound, internalized, and degraded LDL. In both cell types, uptake approached saturation at a concentration of 50 micrograms of LDL protein/ml. Competition for LDL binding by LDL, high density lipoprotein, and modified LD revealed that the hepatocyte binding was specific for LDL. Cellular cholesterol loading by incubation in LDL-enriched culture medium resulted in diminished LDL uptake in both cell types. Chemical modification of LDL by acetoacetylation, acetylation, and reductive methylation abolished LDL uptake and degradation by fibroblasts. However, hepatocytes bound and degraded the modified LDL at 30-50% the level of native LDL. Homozygous familial hypercholesterolemic hepatocytes were devoid of the LDL receptor pathway but metabolized native LDL to the extent observed with modified LDL uptake by normal hepatocytes. In contrast to the classic LDL receptor pathway, the second or alternate pathway does not lead to regulation of 3-hydroxy-3-methylglutaryl-CoA reductase activity. These findings indicate the presence of two separate pathways of LDL uptake in human hepatocytes which have different effects on hepatocytic cholesterol metabolism.     

Oxidized low density lipoprotein suppresses the expression of tumor necrosis factor-alpha mRNA in stimulated murine peritoneal macrophages

In the present report we have examined expression of the gene encoding the inflammatory monokine TNF-alpha in murine peritoneal macrophages treated with different forms of low density lipoprotein (LDL). LDL modified by oxidation in vitro is unable to stimulate inflammatory gene expression in peritoneal macrophages. However, treatment of macrophage cultures with oxidized LDL for 6 h or more resulted in a concentration and time-dependent suppression of TNF-alpha mRNA expression induced in response to stimulation with either LPS or maleylated BSA. This suppression was maximal after 12 h of exposure to oxidized LDL and at a concentration of 100 to 200 micrograms LDL cholesterol/ml of culture medium. The suppressive effect was restricted to oxidatively modified LDL as treatment with native LDL or acetylated LDL did not affect TNF-alpha mRNA expression, despite the fact that both acetylated and oxidized LDL lead to intracellular lipid accumulation. The expression of maleyl albumin-stimulated TNF-alpha mRNA expression could be reproduced by lipid extracts of oxidized LDL provided to macrophages at the same cholesterol concentration as from the intact lipoprotein particle. Extracts from native LDL were ineffective. These results suggest that oxidized lipid accumulation in monocytes infiltrating the arterial wall may lead to the suppression of certain inflammatory functions which, in turn, may influence the development of mature atherosclerotic lesions.     

Low density lipoprotein modification by cholesterol oxidase induces enhanced uptake and cholesterol accumulation in cells.

Oxidation of low density lipoprotein (LDL) by cells of the arterial wall or in the presence of copper ions was shown to result in the peroxidation of its fatty acids as well as its cholesterol moiety. LDL incubation with cholesterol oxidase (CO) resulted in the conversion of up to 85% of the lipoprotein unesterified cholesterol (cholest-5-en-3-ol) to cholestenone (cholest-4-en-3-one) in a dose- and time-dependent pattern. Plasma very low density lipoprotein (VLDL) and high density lipoprotein (HDL) could be similarly modified by CO. In cholesterol oxidase-modified LDL (CO-LDL), unlike copper ion-induced oxidized LDL (Cu-Ox-LDL), there was no fatty acids peroxidation, and lipoprotein size or charge as well as LDL cholesteryl ester, phospholipids, and triglycerides content were not affected. CO-LDL, however, demonstrated enhanced susceptibility to oxidation by copper ions in comparison to native LDL. Upon incubation of CO-LDL with J-774 A.1 macrophage-like cell line, cellular uptake and degradation of the lipoprotein was increased by up to 62% in comparison to native LDL but was 15% lower than that of Cu-Ox-LDL. Similarly, the binding of CO-LDL to macrophages increased by up to 80%, and cellular cholesterol mass was increased 51% more than the mass obtained with native LDL. Several lines of evidence indicate that CO-LDL was taken up via the LDL receptor: 1) Excess amounts of unlabeled LDL, but not acetyl-LDL (Ac-LDL), effectively competed with 125I-CO-LDL for the uptake by cells. 2) The degradation of CO-LDL by various types of macrophages and by fibroblasts could be dissociated from that of Ac-LDL and was always higher than that of native LDL. 3) A monoclonal antibody to the LDL receptor (IgG-C7) and a monoclonal antibody to the LDL receptor binding domains on apoB-100 (B1B6) inhibited macrophage degradation of CO-LDL. The receptor for Cu-Ox-LDL, which is not shared with Ac-LDL, was also partially involved in macrophage uptake of CO-LDL, since Cu-Ox-LDL demonstrated some competition capability with CO-125I-LDL for its cellular degradation. CO-LDL cellular degradation was inhibited by chloroquine, thus implying lysosomal involvement in the cellular processing of the lipoprotein. Incubation of macrophages with LDL in the presence of increasing concentrations of cholestenone resulted in up to 52% enhanced lipoprotein cellular degradation suggesting that the cholestenone in CO-LDL might be involved in the enhanced cellular uptake of the modified lipoprotein.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effect of clonal senescence on low density lipoprotein-receptor activity of bovine arterial endothelial cells

Senescent and young bovine arterial endothelial cells derived from the same parental cell clone were compared to test the effect of in vitro endothelial cell senescence on low density lipoprotein (LDL) and modified LDL-receptor activities. Low density lipoprotein binding and degradation were both increased in cells that underwent a larger number of population doublings, whereas acetyl LDL binding and degradation were unchanged. The increased LDL-receptor activity associated with endothelial cell senescence remained significant after variation of cell number among senescent and young clones was taken into account. Thus, aging endothelial cells seem capable of continuing to process LDL and modified LDL, which could play a role in the arterial wall changes that occur with age in vivo.     

Modification of low density lipoprotein by lipoprotein lipase or hepatic lipase induces enhanced uptake and cholesterol accumulation in cells

Incubation of low density lipoprotein(s) (LDL) with either lipoprotein lipase or hepatic lipase led to modification of the core lipid composition of LDL. Both lipases modified LDL by substantially reducing core triglyceride content without producing marked differences in size, charge, or lipid peroxide content in comparison to native LDL. The triglyceride-depleted forms of LDL that result from treatment with these two enzymes were degraded at approximately twice the rate of native LDL by human monocyte-derived macrophages (HMDM). Lipase-modified LDL degradation was inhibited by chloroquine, suggesting lysosomal involvement in LDL cellular processing. The increased degradation by macrophages of the LDL modified by these lipases was accompanied by enhanced cholesterol esterification rates, as well as by an increase in cellular free and esterified cholesterol content. In a patient with hepatic triglyceride lipase deficiency, degradation of the triglyceride-rich LDL by HMDM was approximately half that of normal LDL. Following in vitro incubation of LDL from this patient with either lipoprotein or hepatic lipase, lipoprotein degradation increased to normal. Several lines of evidence indicate that LDL modified by both lipases were taken up by the LDL receptor and not by the scavenger receptor. 1) The degradation of lipase-modified LDL in nonphagocytic cells (human skin fibroblast and arterial smooth muscle cells) as well as in phagocytic cells (HMDM, J-774, HL-60, and U-937 cell lines) could be dissociated from that of acetylated LDL and was always higher than that of native LDL. A similar pattern was found for cellular cholesterol esterification and cholesterol mass. 2) LDL receptor-negative fibroblasts did not degrade lipase-modified LDL. 3) A monoclonal antibody to the LDL receptor inhibited macrophage degradation of the lipase-modified LDL. 4) Excess amounts of unlabeled LDL competed substantially with 125I-labeled lipase-modified LDL for degradation by both macrophages and fibroblasts. Thus, lipase-modified LDL can cause significant cholesterol accumulation in macrophages even though it is taken up by LDL and not by the scavenger receptor. This effect could possibly be related to the reduced triglyceride content in the core of LDL, which may alter presentation of the LDL receptor-binding domain of apolipoprotein B on the particle surface, thereby leading to increased recognition and cellular uptake via the LDL receptor pathway.     

Enhanced binding of phospholipase-A2-modified low density lipoprotein by human adipocytes

Recognition of low density lipoprotein (LDL) by human adipocytes is not dependent on the classical LDL (apoprotein B-E) receptor. To assess whether LDL phospholipids have a role in adipocyte-LDL interactions, binding studies were carried out with human LDL modified with cobra venom phospholipase A2 (PLA2) and freshly isolated adipocytes and purified adipocyte plasma membranes prepared from surgical biopsies. LDL incubated with PLA2 showed increased monoacylphospholipid content, decreased diacylphospholipid content, and increased anodic migration on agarose gel electrophoresis. LDL cholesterol, triglyceride, and protein content remained unchanged. Typically, modification of 16 and 47% of LDL phospholipids enhanced specific binding of 125I-labelled LDL to plasma membranes progressively from 3.1 micrograms LDL bound/mg membrane protein (control) to 5.8 and 28.2 micrograms LDL bound/mg membrane protein, respectively. Nonspecific binding was not altered significantly. Excess unlabelled native LDL and high density lipoprotein (HDL3) effectively inhibited binding of PLA2-modified LDL. Freshly isolated adipocytes also showed enhanced binding and uptake of PLA2-modified LDL (0.1 vs. 0.9 micrograms LDL/10(6) cells x 2 h), control vs. modified). The results demonstrate that alterations of LDL phospholipids significantly enhance LDL binding and suggest a regulatory role for phospholipids in lipoprotein-cell interaction. Furthermore, the results support the view that human adipose tissue may be involved in the metabolism of modified lipoproteins, in vivo.     

Effect of clonal senescence on low density lipoprotein-receptor activity of bovine arterial endothelial cells

Summary Senescent and young bovine arterial endothelial cells derived from the same parental cell clone were compared to test the effect of in vitro endothelial cell senescence on low density lipoprotein (LDL) and modified LDL-receptor activities. Low density lipoprotein binding and degradation were both increased in cells that underwent a larger number of population doublings, whereas acetyl LDL binding and degradation were unchanged. The increased LDL-receptor activity associated with endothelial cell senescence remained significant after variation of cell number among senescent and young clones was taken into account. Thus, aging endothelial cells seem capable of continuing to process LDL and modified LDL, which could play a role in the arterial wall changes that occur with age in vivo. This study was supported by National Institutes of Health Grants AG 02673 and HL 18645. Computational assistance was provided by CLINFO computer system funded under General Clinical Research Center Grant RR-37.     

Lipoprotein (a) is not a metabolic product of other lipoproteins containing apolipoprotein B.

125I-Labeled autologous very low density lipoprotein (VLDL) was injected intravenously into three lipoprotein (a) positive individuals. One other lipoprotein (a) positive subject received 125I-labeled VLDL from a a lipoprotein (a) negative donor. Specific activity of apolipoprotein B in VLDL, low density lipoprotein (LDL) and lipoprotein (a) was measured for 5 days. In the lipoprotein (a) fraction only traces of radioactivity could be detected, which were caused by contamination with labeled LDL. No precursor-product relationship existed between apolipoprotein B in VLDL or LDL and apolipoprotein B in lipoprotein (a). One lipoprotein (a)-positive individual was kept on a fat-free diet for 4 days to prevent chylomicron formation; no change in the serum level of lipoprotein (a) could be detected under these conditions. The data of this study indicate that lipoprotein (a) is not a metabolic product of VLDL or LDL. Also chylomicrons are not likely to play role as a precursor for lipoprotein (a). It is concluded that lipoprotein (a) is synthesized as a separate lipoprotein.     

Identification of macrophages in sections of rabbit lung using acetoacetylated lipoproteins

Macrophages were labeled in sections of rabbit lung with acetoacetylated low density lipoprotein (LDL), a marker internalized by cultured macrophages but not by other connective tissue cells. Using a modified technique, thin slices of fresh rabbit lung were incubated in 3,3'-dioctadecylindocarbocyanine (DiI)-labeled, acetoacetylated LDL, fixed in paraformaldehyde, and sectioned. Alveolar macrophages incorporated the fluorescently labeled, modified LDL, but surrounding stroma and parenchyma did not stain. Our results indicate that DiI-labeled, acetoacetylated LDL may be used to identify mononuclear phagocytes in tissue sections.     

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.     

Very low density lipoprotein binding to cultured aortic endothelium

Because of very low density lipoprotein's (VLDL) potential atherogenicity and the demonstration that VLDL can bind to other cells, we examined the interaction of human VLDL with cultured porcine aortic endothelium. The lipoprotein-cell interaction had many properties similar to those seen with the binding of a ligand to a cell surface receptor. It was time and temperature dependent, saturable, and reversible. Scatchard analysis of competition data suggested that there may be more than one class of binding site. The affinity of the low affinity site was similar to that for low density lipoprotein (LDL). Also, the capacity of endothelial cells to bind VLDL was similar to that for LDL, when related to apo B (i.e., particle) concentration. Not only was unlabelled VLDL able to compete for VLDL binding sites, but so was LDL and high density lipoprotein (HDL). The maximal competition either by LDL or by HDL was less than that by VLDL. The maximal competition by HDL was more than by LDL. The VLDL binding was dependent on Ca2+. It was not changed by the content of lipoprotein in the medium in which cells were grown prior to the binding studies. These observations suggest that VLDL binding to endothelial cells is similar in some respects, but not in all, to the binding of LDL. Comparison of the data with endothelial cells to previous data with adipocytes also indicated differences between the interaction of these two cell types with VLDL. It is possible that this binding process may be involved in the formation of atherogenic remnants of triglyceride-rich lipoproteins on the endothelial surface of large blood vessels.     

Conversion of human low density lipoprotein into a very low density lipoprotein-like particle in vitro.

The lipid substrate specificity of Manduca sexta lipid transfer particle (LTP) was examined in in vitro lipid transfer assays employing high density lipophorin and human low density lipoprotein (LDL) as donor/acceptor substrates. Unesterified cholesterol was found to exchange spontaneously between these substrate lipoproteins, and the extent of transfer/exchange was not affected by LTP. By contrast, transfer of labeled phosphatidylcholine and cholesteryl ester was dependent on LTP in a concentration-dependent manner. Facilitated phosphatidylcholine transfer occurred at a faster rate than facilitated cholesteryl ester transfer; this observation suggests that either LTP may have an inherent preference for polar lipids or the accessibility of specific lipids in the donor substrate particle influences their rate of transfer. The capacity of LDL to accept exogenous lipid from lipophorin was investigated by increasing the high density lipophorin:LDL ratio in transfer assays. At a 3:1 (protein) ratio in the presence of LTP, LDL became turbid (and aggregated LDL were observed by electron microscopy) indicating LDL has a finite capacity to accept exogenous lipid while maintaining an overall stable structure. When either isolated human non B very low density lipoprotein (VLDL) apoproteins or insect apolipophorin III (apoLp-III) were included in transfer experiments, the sample did not become turbid although lipid transfer proceeded to the same extent as in the absence of added apolipoprotein. The reduction in sample turbidity caused by exogenous apolipoprotein occurred in a concentration-dependent manner, suggesting that these proteins associate with the surface of LDL and stabilize the increment of lipid/water interface created by LTP-mediated net lipid transfer. The association of apolipoprotein with the surface of modified LDL was confirmed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis, and scanning densitometry revealed that apoLp-III bound to the surface of LDL in a 1:14 apoB:apoLp-III molar ratio. Electron microscopy showed that apoLp-III-stabilized modified LDL particles have a larger diameter (29.2 +/- 2.6 nm) than that of control LDL (22.7 +/- 1.9 nm), consistent with the observed changes in particle density, lipid, and apolipoprotein content. Thus LTP-catalyzed vectorial lipid transfer can be used to introduce significant modifications into isolated LDL particles and provides a novel mechanism whereby VLDL-LDL interrelationships can be studied.     

Effects of estrogen administration on the lipoproteins and apoproteins of the chicken.

The plasma lipoproteins of estrogen-treated and untreated sexually immature hens have been compared with respect to their concentration in plasma, protein and lipid composition, particle size, and and apoprotein composition. Administration of diethylstilbestrol resulted in a 400-fold rise in the concentration of very low density lipoprotein (VLDL), a 70-fold rise in low density lipoprotein (LDL), and a marked reduction in high density lipoprotein (HDL) protein. It also resulted in the production of LDL and HDL which were enriched in triacylglycerol, while the proportion of cholesterol in all three lipoprotein fractions decreased. In contrast to the lipoproteins from untreated birds, lipoproteins of density less than 1.06 g/ml from estrogen-treated birds were not clearly separable into discrete VLDL and LDL fractions, but appeared to be a single ultracentrifugal class. The apoprotein composition of VLDL and LDL from untreated birds differed from each other; however, the apoprotein patterns of VLDL and LDL from estrogen-treated birds were indistinguishable: both contained a large amount of low molecular weight protein in addition to the high molecular weight component that predominates in the untreated state. The apoprotein composition of HDL was also markedly altered by estrogen administration: the 28,000 mol. wt. protein (apo A-I) decreased in amount from 65% to less than 5% of the total, while a low molecular weight (Mr = 14,000) protein and as yet poorly defined high molecular weight components became predominant. These observations indicate that the hyperlipidemia induced by estrogen administration is accompanied by marked alterations, both qualitative and quantitative, in the plasma lipoproteins.     

芦丁和槲皮素对低密度脂蛋白氧化修饰的抑制作用

以低密度脂蛋白（ＬＤＬ）氧化修饰为模型和以硫代巴比妥酸反应物质（ＴＢＡＳ）生成量以及ＬＤＬ的α－Ｔｏｃｏｐｈｅｒｏｌ和荧光物质含量为指标,以时间效应和浓度效应说明槲皮素和芦丁能明显地抑制Ｃａ＾２＋诱导的ＬＤＬ氧化修饰但其抗氧化修饰的程度无明显差异。它们对已受到Ｃｕ＾２＋氧化修饰的ＬＤＬ的过氧化无明显地终止作用。     

Isolation and characterization of the apolipoprotein E receptor from canine and human liver

Previous results have demonstrated that liver membranes possess two distinct lipoprotein receptors: a low density lipoprotein (LDL) receptor that binds lipoproteins containing either apolipoprotein (apo-) B or apo-E, and an apo-E-specific receptor that binds apo-E-containing lipoproteins, but not the apo-B-containing LDL. This study reports the isolation and purification of apo-B,E(LDL) and apo-E receptors from canine and human liver membranes. The receptors were solubilized with the zwitterionic detergent 3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonate and were partially purified by DEAE-cellulose chromatography. The apo-B,E(LDL) receptor was isolated by affinity chromatography on LDL-Sepharose. The apo-E receptor, which did not bind to the LDL-Sepharose column, was then purified by using an HDLc (cholesterol-induced high density lipoprotein)-Sepharose affinity column and an immunoaffinity column. Characterization of the receptors revealed that the hepatic apo-B,E(LDL) receptor is similar to the extrahepatic LDL receptor with an apparent Mr = 130,000 on non-reducing sodium dodecyl sulfate-polyacrylamide gels. The apo-E receptor was found to be distinct from the apo-B,E(LDL) receptor, with an apparent Mr = 56,000. The purified apo-E receptor displayed Ca2+-dependent binding to apo-E-containing lipoproteins and did not bind to LDL or chemically modified apo-E HDLc. Antibodies raised against the apo-B,E(LDL) receptor cross-reacted with the apo-E receptor. However, an antibody prepared against the apo-E receptor did not react with the apo-B,E(LDL) receptor. The apo-E receptor also differed from the apo-B,E(LDL) receptor in amino acid composition, indicating that the apo-E receptor and the apo-B,E(LDL) receptor are two distinct proteins. Immunoblot characterization with anti-apo-E receptor immunoglobulin G indicated that the apo-E receptor is present in the hepatic membranes of man, dogs, rats, and mice and is localized to the rat liver parenchymal cells.     

Low density lipoprotein binding, internalization, and degradation in human adipose cells.

Human adipose tissue derives its cholesterol primarily from circulating lipoproteins. To study fat cell-lipoprotein interactions, low density lipoprotein (LDL) uptake and metabolism were examined using isolated human adipocytes. The 125I-labelled LDL (d = 1.025-1.045) was bound and incorporated by human fat cells in a dose-dependent manner with an apparent Km of 6.9 + 0.9 microgram LDL protein/mL and a Vmax of 15-80 microgram LDL protein/mg lipid per 2 h. In time-course studies, LDL uptake was characterized by rapid initial binding followed by a linear accumulation for at least 4 h. The 125I-labelled LDL degradation products (trichloroacetic acid soluble iodopeptides) accumulated in the incubation medium in a progressive manner with time. Azide and F- inhibited LDL internalization and degradation, suggesting that these processes are energy dependent. Binding and cellular internalization of 125I-labelled LDL lacked lipoprotein class specificity in that excess (25-fold) unlabelled very low density lipoprotein (VLDL) (d less than 1.006) and high density lipoprotein (HDL) (d = 1.075-1.21) inhibited binding and internalization of 125I-labelled LDL. On an equivalent protein basis HDL was the most potent. The 125I-labelled LDL binding to an adipocyte plasma membrane preparation was a saturable process and almost completely abolished by a three- to four-fold greater concentration of HDL. The binding, internalization, and degradation of LDL by human adipocytes resembled that reported by other mesenchymal cells and could account for a significant proportion of in vivo LDL catabolism. It is further suggested that adipose tissue is an important site of LDL and HDL interactions.     

Fractionation of human low density lipoprotein by column chromatography.

We have devised a method to fractionate low density lipoprotein (LDL) into subspecies by means of column chromatography. DEAE-agarose columns, 2.6 X 60 cm, were loaded with LDL (25-45 mg LDL protein) and eluted with a 0.045-0.13 M NaCl gradient. The LDL eluted over a volume of 900 ml. Specific portions of the eluted LDL, reapplied to a column identical with the original, reelute at about the same point. Altering the NaCl concentration of the elution fluid changed the elution volume. The cholesterol-protein ratio of the LDL subfractions was progressively lower in fractions eluting at higher NaCl concentrations. These results indicate the LDL is not a homogenous lipoprotein species but consists of subfractions which differ in at least charge and cholesterol content.     

Effects of bezafibrate on apolipoprotein B metabolism in type III hyperlipoproteinemic subjects

This study was designed to investigate the response of Type III hyperlipoproteinemic subjects to bezafibrate therapy. The metabolism of apolipoprotein B was examined in four lipoprotein subclasses of Sf 60-400 (large very low density lipoprotein (VLDL)), Sf 20-60 (small VLDL), Sf 12-20 (intermediate density lipoprotein (IDL)), and Sf 0-12 (low density lipoprotein (LDL)) before and during bezafibrate therapy. Treatment reduced the plasma concentration of VLDL and raised high density lipoprotein (HDL) cholesterol. There was no net change in LDL cholesterol or its associated apolipoprotein B. The decrease in plasma VLDL derived mainly from an inhibition of synthesis of both large and small subfractions which reduced the number of particles in the circulation without normalizing their lipid composition. Catabolism of the larger VLDL also increased, presumably as a result of lipoprotein lipase activation. Although the plasma concentration of LDL was unchanged, both its synthesis and catabolism were perturbed. Its fractional catabolic rate fell by 50%, but the impact that this would have had on its steady state level in the circulation was apparently blunted by a decrease in its synthesis from Sf 12-20 IDL. In the control phase of the study, most IDL apolipoprotein B was converted to LDL. Bezafibrate therapy channelled this material towards direct catabolism.     

Effect of low density lipoprotein on DNA integrity of freezing-thawing boar sperm by neutral comet assay

A modified protocol of neutral comet assay was utilized to assess the effect of low density lipoprotein (LDL) on the DNA integrity of boar freezing-thawing semen. The results demonstrated that the method was high sensitive and easier manipulation and LDL significantly protected sperm DNA integrity (p<0.05) from the damage caused by cryopreservation except TD at the concentration of 6%, 7% and TM at 6%, the optimal LDL concentration in diluents was 9%. Moreover, LDL showed better protection in 0.25 ml than in 0.5 ml types of straw (p<0.05) and no difference was observed in the same volume straw at the concentration of 9% and 10%. It was just the same for LDL effect on boar sperm DNA in cryopreservation 0 day and 30 days (p>0.05).     

Increased uptake of alpha-hydroxy aldehyde-modified low density lipoprotein by macrophage scavenger receptors

Reactive aldehydes can be formed during the oxidation of lipids, glucose, and amino acids and during the nonenzymatic glycation of proteins. Low density lipoprotein (LDL) modified with malondialdehyde are taken up by scavenger receptors on macrophages. In the current studies we determined whether alpha-hydroxy aldehydes also modify LDL to a form recognized by macrophage scavenger receptors. LDL modified by incubation with glycolaldehyde, glyceraldehyde, erythrose, arabinose, or glucose (alpha-hydroxy aldehydes that possess two, three, four, five, and six carbon atoms, respectively) exhibited decreased free amino groups and increased mobility on agarose gel electrophoresis. The lower the molecular weight of the aldehyde used for LDL modification, the more rapid and extensive was the derivatization of free amino groups. Approximately 50-75% of free lysine groups in LDL were modified after incubation with glyceraldehyde, glycolaldehyde, or erythrose for 24-48 h. Less extensive reductions in free amino groups were observed when LDL was incubated with arabinose or glucose, even at high concentration for up to 5 days. LDL modified with glycolaldehyde and glyceraldehyde labeled with (125)I was degraded more extensively by human monocyte-derived macrophages than was (125)I-labeled native LDL. Conversely, LDL modified with (125)I-labeled erythrose, arabinose, or glucose was degraded less rapidly than (125)I-labeled native LDL. Competition for the degradation of LDL modified with (125)I-labeled glyceraldehyde was nearly complete with acetyl-, glycolaldehyde-, and glyceraldehyde-modified LDL, fucoidin, and advanced glycation end product-modified bovine serum albumin, and absent with unlabeled native LDL.These results suggest that short-chain alpha-hydroxy aldehydes react with amino groups on LDL to yield moieties that are important determinants of recognition by macrophage scavenger receptors.