Apoproteins of the lipoproteins in a nonrecirculating perfusate of rat liver.

The apoproteins of serum lipoproteins and of lipoproteins present in a nonrecirculating perfusate of rat liver were compared by immunochemical, gel electrophoretic, and solubility techniques. Serum and perfusate very low density lipoprotein apoprotein composition were not different. No evidence for the presence of a lipoprotein resembling serum low density lipoprotein was obtained. However, the apoprotein composition of circulatory high density lipoprotein was quantitatively different from the secretory product in the density 1.06-1.21 range. As measured by stained sodium dodecyl sulfate gel electrophoretic patterns, the arginine-rich protein was the major secretory apoprotein while the A-I protein was the major apoprotein in circulating high density lipoprotein. A very similar pattern was seen in perfusates of orotic acid-fatty livers. It was concluded that although the liver secrets lipoproteins in the high density class, circulatory high density lipoprotein is largely a product of catabolic processes.     

The sites of degradation of purified rat low density lipoprotein and high density lipoprotein in the rat

Low density lipoprotein and high density lipoprotein were isolated from rat serum by sequential ultracentrifugation in the density intervals 1.025-1.050 g/ml and 1.125-1.21 g/ml, respectively. The isolated lipoproteins were radioiodinated using ICl. Low density lipoprotein was further purified by concanavalin A affinity chromatography and concentrated by ultracentrifugation. 95% of the purified low density lipoprotein radioactivity was precipitable by tetramethylurea, while only 4% was associated with lipids. The radioiodinated high density lipoprotein was incubated for 1 h at 4 degrees C with unlabelled very low density lipoprotein, followed by reisolation by sequential ultracentrifugation. Only 3% of the radioactivity was associated with lipids and 90% was present on apolipoprotein A-I. The serum decay curves of labelled and subsequently purified rat low and high density lipoprotein, measured over a period of 28 h, clearly exhibited more than one component, in contrast to the monoexponential decay curves of iodinated human low density lipoprotein. The decay curves were not affected by the methods used to purify the LDL and HDL preparations. The catabolic sites of the labelled rat lipoproteins were analyzed in vivo using leupeptin-treated rats. In vivo treatment of rats with leupeptin did not affect the rate of disappearance from serum of intravenously injected labelled rat low density lipoprotein and high density lipoprotein. Leupeptin-dependent accumulation of radioiodine occurred almost exclusively in the liver after intravenous injection of iodinated low density lipoprotein, while both the liver and the kidneys showed leupeptin-dependent accumulation of radioactivity after injection of iodinated high density lipoprotein.     

Characterization of lipoprotein secreted by cultured eel hepatocytes and its comparison with serum lipoproteins.

The lipoprotein secreted by cultured eel hepatocytes was fractionated by density gradient ultracentrifugation and compared with eel serum lipoproteins. Eel hepatocytes were cultured for 7 to 10 days as a monolayer in Williams' medium E containing 5% fetal bovine serum and 0.16 microM insulin on a dish precoated with fibronectin of horse serum. The only lipoprotein secreted by eel hepatocytes was a very-low-density lipoprotein like one which consisted of 69% triglyceride, 15% phospholipid, 4% cholesterol, and 12% protein. On the other hand, very-low-density lipoprotein and high density lipoprotein were found in eel serum, in which high density lipoprotein was a main lipoprotein. The secreted lipoprotein contained apo B and apo A as the main protein components. Furthermore, the lipoprotein contained proapo A-I in addition to apo A-I, which was proved by comparing the amino acid composition of both proteins. In our discussion, we noted that the lipoprotein secreted by eel hepatocytes was a good material for the study of high-density lipoprotein formation.     

Lipid peroxidation of hyperlipemic rat serum lipoproteins in chronic ethanol and acetaldehyde administration

The levels of lipid peroxides in circulatory lipoproteins increased with chronic administration of ethanol or acetaldehyde. Low density lipoprotein showed a greater increase in its content of lipid peroxides than very low density lipoprotein or high density lipoprotein. However, very low density lipoprotein was more prone to lipid peroxidationin vitro than low density lipoprotein or high density lipoprotein. The effect of acetaldehyde was more marked than that of ethanol. Lipoproteins of control and hyperlipemic groups were partially protected against peroxidation by butyrated hydroxytoluene and serum high density lipoprotein of normal rats.     

Activation of lipoprotein lipase by lipoprotein fractions of human serum

Triglycerides in fat emulsions are hydrolyzed by lipoprotein lipase only when they are "activated" by serum lipoproteins. The contribution of different lipoprotein fractions to hydrolysis of triglycerides in soybean oil emulsion was assessed by determining the quantity of lipoprotein fraction required to give half-maximal hydrolysis. Most of the activator property of whole serum from normolipidemic, postabsorptive subjects was in high density lipoproteins. Low density lipoproteins and serum from which all lipoprotein classes were removed had little or no activity. Also, little activator was present in guinea pig serum or in very low density poor serum from an individual with lecithin:cholesterol acyltransferase deficiency, both of which are deficient in high density lipoproteins. Human very low density lipoproteins are potent activators and are much more active than predicted from their content of high density lipoprotein-protein. Per unit weight of protein, very low density lipoproteins had 13 times the activity of high density lipoproteins. These observations suggest that one or more of the major apoproteins of very low density lipoproteins, present as a minor constituent of high density lipoproteins, may be required for the activation process.     

Effect of phenobarbital upon serum cholesterol lipoprotein fractions of three rodent species

Phenobarbital (PB) in doses previously shown to be optimal for induction of hepatic microsomal enzymes had no effect on the cholesterol content of whole serum or of serum lipoprotein fractions in the guinea pig, but reduced high density lipoprotein cholesterol (with increase in very low density lipoprotein cholesterol) in the rabbit, and increased high density lipoprotein cholesterol (as well as total and low density lipoprotein cholesterol) in the rat. These results, when taken together with previous data demonstrating that PB increases serum triglyceride in the rabbit but lowers it in the rat, suggest that the drug may be atherogenic in the rabbit but not in the rat which, in any case, is highly resistant to atheroma.     

Evidence for high density lipoproteins as the major apolipoprotein A-IV-containing fraction in normal human serum

The distribution of human apolipoprotein A-IV was studied in sera from normolipidemic fasting subjects by high performance gel filtration on a Superose 12 HR column. The major part of apolipoprotein A-IV eluted in the range of the apolipoprotein A-I peak, and distributed mainly in the large-size high density lipoprotein subfractions. Only a small peak or a shoulder on the main fraction appeared in the elution volume of free apolipoprotein A-IV. To investigate the relation of apolipoprotein A-IV with high density lipoprotein particles, serum high density lipoproteins were precipitated by incubating human serum with anti-apolipoprotein A-I immunoglobulins. At optimal concentrations, inducing a precipitation of 90 to 95% of serum apolipoprotein A-I, about 70% of serum apolipoprotein A-IV was precipitated. It was concluded that, in fasting human serum, apolipoprotein A-IV was mainly associated with high density lipoprotein particles. This high degree of association to high density lipoproteins did not result from the known in vitro redistribution of apolipoprotein A-IV induced by lecithin: cholesterol acyltransferase activity since it was observed in sera in the presence of inhibitors of this enzyme. The comparison of gel filtration profiles of total serum and of serum fractions separated by ultracentrifugation showed that the apolipoprotein A-IV-high density lipoprotein association was a weak one, easily dissociated by the ultracentrifugation process. The existence in fasting human serum of a predominant high density lipoprotein-associated form of apolipoprotein A-IV should stimulate more studies of the general function and metabolism of this protein.     

The distribution of J blood-group activity on lipoprotein and protein fractions of bovine serum.

There is a diversity of carriers of the J blood-group activity of bovine serum. The qualitative and quantitative distribution of the J activity on different carriers was studied, using various fractionation procedures. Approximately one third of J activity was found in the total lipids extracted from serum, two thirds in the lipid-free residue precipitated by lipid extraction. One third of the lipid J substance was found to be bound to the very low density lipoprotein, two thirds to the low density lipoprotein, while the high density lipoprotein was completely free of J activity. All non-lipidic J substance was present in the lipid-free protein. There was no J activity in the low molecular weight mucoproteins of serum and in the apoproteins of the lipoprotein fractions. The lipoprotein fractions were prepared by ultracentrifugation at different solvent densities. The lipoprotein fractions were characterized by chemical analyses and physical properties. The lower total cholesterol concentration of bovine serum, as compared to human serum, is reflected in a lower concentration of low density lipoprotein. The results obtained by ultracentrifugation coincide with the results obtained by precipitation of "beta-lipoproteins" with dextran sulfate and calcium chloride and with results obtained by gel filtration of bovine serum. The "beta-lipoprotein" fraction contains lipoproteins of very low and low density, and probably chylomicrons and a variety of other proteins, however no high density lipoprotein.     

Radioimmunoassay of apolipoprotein A-I of rat serum.

A double antibody radioimmunoassay technique was developed for quantification of apolipoprotein A-I, the major apoprotein of rat high density lipoprotein. Apo A-I was labeled with 125I by the chloramine-T method. 125I-labeled apo A-I had the same electrophoretic mobility as unlabeled apo A-I and more than 80% of the 125I was precipitated by rabbit anti apo A-I antibodies. The assay is sensitive at the level of 0.5-5 ng, and has intraassay and interassay coefficients of variation of 4.5 and 6.5% respectively. The specificity of the assay was established by competitive displacement of 125I-labeled apo A-I from its antibody by apo A-I and lipoproteins containing apo A-I, but not by rat albumin and other apoproteins. Immunoreactivity of high density lipoprotein and serum was only about 35% of that of their delipidated forms when Veronal buffer was used as a diluent. Inclusion of 5 mM sodium decyl sulfate in the incubation mixture brought out reactivity equivalent to that found after delipidation. Completeness of the reaction was verified by comparison with the amount of apo A-I in chromatographic fractions of the total apoprotein of high density lipoprotein. Content (weight %, mean values +/- S.D.) of immunoassayable apo A-I was: 62.3 +/- 5.9 in high density lipoprotein; 1.7 +/- 0.3 in low density lipoprotein; 0.09 +/- 0.03 in very low density lipoprotein and 25.0 +/- 5.0 in lymp chylomicrons. Concentration in whole serum was 51.4 +/- 8.9 mg/dl and 33.6 +/- 4.1 mg/dl for female and male rats, respectively (p less than 0.002), equivalent to the sex difference in concentration of high density lipoprotein. 95% of the apo A-I in serum was in high density lipoprotein, 5% in proteins of d greater than 1.21 g/ml and less than 1% in lipoproteins of d less than 1.063 g/ml.     

Studies on the composition of pig serum lipoproteins. Isolation and characterization of different apoproteins.

1. Different lipoprotein density fractions from pig serum were isolated by phosphotungstate precipitation followed by purification in the preparative ultra-centrifuge. 2. The protein part of very low density lipoproteins was composed of approximately 52 percent lipoprotein B apoprotein and the rest of lipoprotein C II apoprotein and other as yet unidentified peptides. 3. The protein moiety of low density lipoproteins consisted primarily of lipoprotein B apoprotein (over 95 percent); the amino acid compositions of lipoprotein B apoprotein of very low and low density lipoproteins were practically identical. 4. The predominant polypeptide of pig serum high density lipoproteins exhibited an amino acid composition and a molecular weight very similar to human liprotein A I apoprotein. In contrast to human lipoprotein A I apoprotein, the apoprotein from pigs was found to release leucine first followed by alanine, threonine, and lysine upon incubation with carboxypeptidase A. 5. In pig serum the major lipoprotein C apoprotein was found to be a polypeptide similar in amino acid composition to lipoprotein C II apoprotein from human serum. The molecular weight of this polypeptide is approximately 8000. Incubation experiments with carboxypeptidase A indicate serine to be the most likely C-terminal amino acid.     

Chemical characterization of the serum very low density and high density lipoproteins from bullfrog, Rana catesbeiana.

The chemical properties of very low density and high density lipoproteins of adult bullfrog serum were determined. This serum contained extremely low levels of both very low density lipoprotein (10-30 mg/100 ml) and high density lipoprotein (5-10 mg/100 ml). The constituents of very low density lipoprotein, on a weight percentage basis, were found to be 48.1% triglyceride, 17.3% cholesterol ester, 8.8% cholesterol, 11.6% phospholipid, and 12% protein. These constituents were also present in high density lipoprotein with weight percentage values of 3.7%, 19.3%, 11.9%, 25.2%, and 36.8%, respectively. The fatty acid compositions of the triglycerides, cholesterol esters, and phosphatidylcholine were quite similar in the very low density lipoprotein and high density lipoprotein. However, shingomyelin fatty acid composition was appreciably different in the two lipoproteins. Disc gel electrophoresis in sodium dodecyl sulfate-polyacrylamide gels produced patterns with one major (approximate molecular weight, 7,000) and several minor bands for the apoprotein of very low density lipoprotein and one major (approximate molecular weight, 28,000) and several minor bands for that of high density lipoprotein.     

Cigarette smoking and serum lipid and lipoprotein concentrations: an analysis of published data.

To examine the association between cigarette smoking in adults and serum lipid and lipoprotein concentrations the results of 54 published studies were analysed. Overall, smokers had significantly higher serum concentrations of cholesterol (3.0%), triglycerides (9.1%), very low density lipoprotein cholesterol (10.4%), and low density lipoprotein cholesterol (1.7%) and lower serum concentrations of high density lipoprotein cholesterol (-5.7%) and apolipoprotein AI (-4.2%) compared with nonsmokers. Among non-smokers and light, moderate, and heavy smokers a significant dose response effect was present for cholesterol (0, 1.8, 4.3, and 4.5% respectively), triglycerides (0, 10.7, 11.5, and 18.0%), very low density lipoprotein cholesterol (0, 7.2, 44.4, and 39.0%), low density lipoprotein cholesterol (0, -1.1, 1.4, and 11.0%), high density lipoprotein cholesterol (0, -4.6, -6.3, and -8.9%), and apolipoprotein AI (0, -3.7 and -5.7% in non-smokers and light and heavy smokers). These dose response effects may provide new evidence for a causal relation between exposure to cigarette smoke and changes in serum lipid and lipoprotein concentrations whether as a direct result of physiological changes or of dietary changes induced by smoking. Adequate prospective data to estimate the excess risk of coronary artery disease existed only for cholesterol concentration. When that information was combined with data from the present study, and given that smokers as a group face an average overall excess risk of coronary artery disease of 70%, it was estimated that the observed increased serum cholesterol concentration in smokers may account for at least 9% of that excess risk. Furthermore, the dose response effect of smoking on serum cholesterol concentration suggests a gradient of increased absolute risk of coronary artery disease between light and heavy smokers.     

Receptor domains in the plasma membrane of cultured mouse peritoneal macrophages

Using the platinum-carbon surface replication technique, the distribution of receptors for two colloidal gold labeled lipoproteins (acetylated low density lipoprotein and high density lipoprotein), iron-saturated transferrin and bovine serum albumin in the plasma membrane of cultured mouse peritoneal macrophages was mapped. The plasma membrane surface of cultured peritoneal macrophages exhibits three morphologically distinct regions which have shown differences in the distribution, density and dynamics of these receptors. The flat border of the plasma membrane surfaces are the domains that appear to have the highest concentration of transferrin receptors, whereas the intermediate regions contain most of the receptors for acetylated low density lipoprotein and high density lipoprotein. Bovine serum albumin receptors are concentrated at the edge of the cells and had a uniform distribution on the rest of the cell surface. The functional significance and the mechanisms by which these regional differences in the distribution of the receptors are generated and then maintained are not yet known.     

Serum lipoproteins of normal and cholesterol-fed rats

The density distribution of lipoproteins in rats fed chow or chow containing 1% cholesterol and 10% olive oil was studied. Lipoprotein fractions were prepared in the ultra-centrifuge between narrow density bands within the density range of 1.006-1.21 and were analyzed by chemical, electrophoretic, and immunological methods. In serum from normal rats there were three major lipoprotein fractions, with densities less than 1.006, 1.030-1.063, and 1.063-1.21. Almost no lipoprotein was found between d 1.006 and 1.030. Most of the low density lipoprotein appeared between a density of 1.04 and 1.05. In the density range 1.05-1.07, small amounts of both low density and high density lipoprotein were found. Feeding a diet high in cholesterol resulted in a marked increase in the concentration of lipoproteins of density less than 1.006, and a new lipoprotein fraction appeared between d 1.006 and 1.030; this fraction contained immunologically demonstrable low density and high density lipoproteins. In addition, there was a decrease in the high density lipoprotein fraction between d 1.070 and 1.21.     

Relationship between serum lipids, lipoproteins and pseudocholinesterase during organophosphate poisoning in rabbits

The activities of serum pseudocholinesterase, lecithin: cholesterol acyltransferase (LCAT) and gamma-glutamyltransferase in rabbits were investigated before and after dichlorvos administration in vivo. The effects of this organophosphate on some serum lipids and lipoprotein fractions were also determined. LCAT activity remained almost unaffected after organophosphate administration. However, serum gamma-glutamyltransferase and pseudocholinesterase activities markedly decreased. Dichlorvos markedly lowered both serum low density lipoprotein (LDL) and cholesterol contents, whereas high density lipoprotein (HDL) concentration increased and very low density lipoprotein (VLDL) remained unaffected. Triglycerides as well as esterified fatty acids increased significantly but the statistical changes in free fatty acid concentrations were not significant, because individual variations in fatty acid concentrations were high.     

12周高强度间歇训练对不同基因型载脂蛋白E血脂异常人群的调脂作用

目的:观察12周高强度间歇训练(HIIT)对不同载脂蛋白E(ApoE)基因型血脂异常人群的血脂调节作用。方法:通过测试空腹血脂指标,筛选出88例血脂异常患者作为受试对象,采集受试对象口腔粘膜进行载脂蛋白E基因型检测,测定12周高强度间歇训练干预前后的血脂水平。结果:88例血脂异常者中共检测出5种基因型,其分布为ApoE3/3＞ApoE3/4 ＞ApoE2/3＞ApoE2/2＞ApoE2/4,等位基因ε3＞ε2=ε4。运动干预前,血脂异常人群中ε4等位基因组的总胆固醇水平显著高于ε2和ε3基因组(P＜0.01),低密度脂蛋白胆固醇水平显著高于ε2基因组(P＜0.05),其余指标在各组间无显著性差异(P＞0.05)。12周的高强度间歇训练显著降低ε3基因组血清总胆固醇、甘油三酯和低密度脂蛋白胆固醇水平,升高高密度脂蛋白胆固醇水平。ε4基因组在运动干预后血清总胆固醇和低密度脂蛋白胆固醇降低,甘油三酯和高密度脂蛋白胆固醇无显著性改变。ε2基因组在运动干预后血清脂质无明显改善。结论:血脂异常人群载脂蛋白E基因多态性影响运动的调脂效果,12周高强度间歇训练可以作为ε3和ε4等位基因携带者调节血脂的运动干预方式。     

Prolactin, LH, and estradiol-17 beta in utilization of lipoprotein substrate by porcine granulosa cells in vitro

Porcine granulosa cells cultured under serum free conditions responded by increased progesterone secretion to the addition of the leuteotropic hormones, LH, prolactin, and estradiol. Provision of extracellular substrate for steroidogenesis in the form of porcine high density lipoprotein or low density lipoprotein enhanced progesterone accumulation by granulosa cell cultures. Estradiol, LH, and prolactin all greatly increased progesterone accumulation in the presence of either high or low density lipoproteins. Increases in progesterone accumulation following addition of prolactin or LH in combination with estradiol suggested the presence of a synergistic interaction among leuteotropins. Pre-exposure of granulosa cell cultures to estradiol increased the subsequent stimulatory effect of prolactin on lipoprotein utilization. It is concluded that all three leuteotropins function to enhance and may interact in the utilization of extracellular lipoprotein substrate for progesterone synthesis.     

Variation and significance of serum leptin,blood lipid level,adiponectin, NO and TNF-α for patients with non-traumatic ischemic necrosis of the femoral head

ObjectiveTo investigate the changes of serum leptin, lipid levels, adiponectin, NO and TNF-α in patients withnon-traumatic ischemic necrosis of the femoral head of the femoral head and its meanings.MethodsA total of 80 patients with ischemic necrosis of the femoral head were selected from January 2015 to January 2016. And 30 healthy volunteers who took the same time were selected as the control group. Both subjects were given venous blood in the morning fasting. Serum leptin levels were measured by radioimmunoassay. Serum lipids, high and low density lipoprotein, cholesterol, triglyceride and apolipoprotein A1 were detected by automatic biochemical analyzer. Apolipoprotein B was measured by radioimmunoassay. The levels of serum adiponectin were measured by radioimmunoassay. The levels of NO and TNF-α in serum were measured by enzyme-linked immunosorbent assay (ELISA).ResultsCompared with the control group, the levels of cholesterol, triglyceride level, middle and low density lipoprotein and apolipoprotein B were significantly increased in INFH serum; the levels of high density lipoprotein and apolipoprotein A1 were significantly decreased The contents of NO and TNF-α were significantly increased, the content of adiponectin was significantly decreased. There was significant difference between the two groups (P < .05).ConclusionThe levels of serum cholesterol, triglyceride level, low density lipoprotein level, apolipoprotein B level, leptin, NO and TNF-α levels in serum of INHF patients were positively correlated with the condition of INHF patients, and high density lipoprotein levels, Apolipoprotein A1 levels and adiponectin levels were negatively correlated with INHF patients.     

On the metabolic function of heparin-releasable liver lipase

Intravenous administration of specific antibody against heparin-releasable liver lipase (liver lipase) induced a 75% inhibition of the enzyme activity $\text{in situ}$. Administration of the antibody resulted in an increase of high density lipoprotein (density range 1.050–1.13 g/ml; HDL₂) phospholipid levels (20% after 1 h; 54% after 4 h). Short-term (1 h) treatment with antibody had no significant effect on any of the other lipoprotein components. After long-term (4 h) treatment the free cholesterol level of HDL₂ and all components in the very low density lipoprotein (VLDL) + intermediate density lipoprotein (IDL) fraction were elevated (1.5–2.0 fold). In the low density lipoprotein (LDL) fraction only the phospholipid level was affected (increased by 72%). All lipid components in the HDL₃ fraction were decreased by the antibody treatment, but this decrease was only statistically significant for the cholesterolesters. The rate of removal of iodine-labeled high density lipoprotein (HDL) and LDL from serum was not affected by the antibody treatment.These results suggest that liver lipase may promote phospholipid removal $\text{in vivo}$ and show that a lowering of liver lipase $\text{in situ}$ has profound consequences for serum lipoprotein metabolism.     

A simple and sensitive method for lipoprotein and lipids profiles analysis of individual micro-liter scale serum samples

A simple and sensitive method to determine lipoprotein and lipids profiles in micro-liter scale individual serum sample is not presently available. Traditional lipoprotein separation techniques either by ultra-centrifugation or by liquid chromatography methods have their disadvantages in both lipoprotein separation and lipids component quantification. In this study we used small volume needing size-exclusion fast protein liquid chromatography to separate different lipoprotein subclasses in 50μL serum. And lipids contents, such as cholesterol, cholesterol ester and triacylglycerol, were measured by using two different fluorescence-based lipid detection methods. With this method, very low density lipoprotein, low density lipoprotein and high density lipoprotein could be easily separated, and follow-up lipid detection was completed by simple kinds of reactions. Serum lipoprotein and lipids profiling from C57BL/6 mice (n=5) and human (n=5) were analyzed. The elution profiles of five individuals were highly reproducible, and there were lipoprotein and lipids distribution variations between C57BL/6 mice and human beings. In conclusion, this method which combined small volume needing size-exclusion fast protein liquid chromatography and fluorescence-based lipids measurement, provided a simple, efficient, integrity and reproducible procedure for determining serum lipoprotein and lipids profiles in micro-liter scale levels. It becomes possible that determination of lipoprotein profiles and gaining information of lipids in different lipoproteins can be accomplished simultaneously.