Discrepancies in Lipemia Interference Between Endogenous Lipemic Samples and Smoflipid®-Supplemented Samples.

Background: Manufacturers evaluate lipemia-induced interference using Intralipid®, but it does not contain all lipoprotein types. The aim of this study was to evaluate lipemiainduced interference in biochemical parameters from endogenous lipemic samples and SMOFlipid® supplemented samples, in order to assess if SMOFlipid® can be used in lipemic interference studies. Methods: Serum pools were supplemented with SMOFlipid® to achieve 800 mg/dL and 1500 mg/dL triglyceride concentration, and analyzed for 25 biochemical parameters both before and after the supplementation. In another independent phase, lipemic serum pools were prepared choosing patient samples of 800 mg/dL and 1500 mg/dL triglyceride concentration. These lipemic serum pools were ultracentrifugated in order to remove lipids. Biochemical parameters were analyzed before and after ultracentrifugation. The bias between SMOFlipid®-supplemented samples and endogenous lipemic samples were compared. The bias between the lipemic and non-lipemic samples were compared with the reference change value. Results: At 800 mg/dL triglyceride concentration, we found that total protein and transferrin had been affected only in endogenous lipemic serum samples. Magnesium and creatinine had been affected only in SMOFlipid®-supplemented samples. At 1500 mg/dL triglyceride concentration, we found that total protein, amylase, ferritin and glucose had lipemic interference only in endogenous lipemic samples, and chloride only in SMOFlipid®-supplemented samples. Conclusions: The use of SMOFlipid®-supplemented samples does not provide suitable data to estimate lipemia-induced interference. Thus, interference studies should be performed using a wide variety of lipemic patient samples that represent the heterogeneity of the lipoprotein particles size.

Hypoxia worsens the impact of intracellular triglyceride accumulation promoted by electronegative low-density lipoprotein in cardiomyocytes by impairing perilipin 5 upregulation.

Plasma lipoproteins are a source of lipids for the heart, and the proportion of electronegative low density lipoprotein [LDL(-)] is elevated in cardiometabolic diseases. Perilipin 5 (Plin5) is a crucial protein for lipid droplet management in the heart. Our aim was to assess the effect of LDL(-) on intracellular lipid content and Plin5 levels in cardiomyocytes and to determine whether these effects were influenced by hypoxia. HL-1 cardiomyocytes were exposed to native LDL [LDL(+)], LDL(-), and LDL(+) enriched in non-esterified fatty acids (NEFA) by phospholipase A2 (PLA2)-mediated lipolysis [PLA2-LDL(+)] or by NEFA loading [NEFA-LDL(+)] under normoxia or hypoxia. LDL(-), PLA2-LDL(+) and NEFA-LDL(+) raised the intracellular NEFA and triglyceride (TG) content of normoxic cardiomyocytes. Plin5 was moderately upregulated by LDL(+) but more highly upregulated by LDL(-), PLA2-LDL(+) and NEFA-LDL(+) in normoxic cardiomyocytes. Hypoxia enhanced the effect of LDL(-), PLA2-LDL(+) and NEFA-LDL(+) on intracellular TG and NEFA concentrations but, in contrast, counteracted the upregulatory effect of these LDLs on Plin5. Fluorescence microscopy experiments showed that hypoxic cardiomyocytes exposed to LDL(-), PLA2-LDL(+) and NEFA-LDL(+) have an increased production of reactive oxygen species (ROS). By treating hypoxic cardiomyocytes with WY-14643 (PPARα agonist), Plin5 remained high. In this situation, LDL(-) failed to enhance intracellular NEFA concentration and ROS production. In conclusion, these results show that Plin5 deficiency in hypoxic cardiomyocytes exposed to LDL(-) dramatically increases the levels of unpacked NEFA and ROS.

Increased concentration of clusterin/apolipoprotein J (apoJ) in hyperlipemic serum is paradoxically associated with decreased apoJ content in lipoproteins.

OBJECTIVE: Clusterin/apolipoprotein J (apoJ) circulates in blood in part associated to lipoproteins or in unbound form. When bound to HDL, apoJ is antiatherogenic by inhibiting endothelial cell apoptosis; thus, any factor modifying apoJ association to HDL would decrease its antiatherogenic function. However, the exact distribution of apoJ in each lipoprotein fraction, or in lipoprotein-non bound form has not been specifically investigated either in normolipemia or in dyslipemia. METHODS: Basic lipid profile and apoJ concentration were determined in sera from 70 subjects, including a wide range of cholesterol and triglyceride concentrations. Lipoproteins were isolated by ultracentrifugation and their lipid and apolipoprotein composition was assessed. RESULTS: In the overall population, serum apoJ positively associated with cholesterol, triglyceride and VLDL-C concentrations, and HDL-C and triglyceride were independent predictors of increased apoJ concentration. Approximately, 20.5% of circulating apoJ was associated with lipoproteins (18.5% HDL, 0.9% LDL and 1.1% VLDL) and 79.5% was not bound to lipoproteins. Serum apoJ concentration was higher in hypercholesterolemic (HC), hypertriglyceridemic (HTG) and combined hyperlipidemic (CHL) sera compared to normolipemic (NL) sera (HC, 98.15 ± 33.6 mg/L; HTG, 103.3 ± 36.8 mg/L; CHL, 131.7 ± 26.8 mg/L; NL, 66.7 ± 33.8 mg/L; P < 0.001). ApoJ distribution was also altered in hyperlipidemia; approximately 30% of circulating apoJ was associated to lipoproteins in the NL group whereas this proportion rounded 15% in hyperlipidemic subjects. CONCLUSIONS: Our findings indicate that hyperlipidemia increases the concentration of apoJ in serum but, in turn, the content of lipoprotein-associated apoJ decreases. The redistribution of apoJ in hyperlipidemia could compromise the antiatherogenic properties of HDL.

Clusterin/apolipoprotein J binds to aggregated LDL in human plasma and plays a protective role against LDL aggregation.

Clusterin/apolipoprotein J (apoJ) is an extracellular chaperone involved in the quality control system against protein aggregation. A minor part of apoJ is transported in blood bound to LDLs, but its function is unknown. Our aim was to determine the role of apoJ bound to LDLs. Total LDL from human plasma was fractionated into native LDL [LDL(+)] and electronegative LDL [LDL(-)]. The latter was separated into nonaggregated [nagLDL(-)] and aggregated LDL(-) [agLDL(-)]. The content of apoJ was 6-fold higher in LDL(-) than in LDL(+) and 7-fold higher in agLDL(-) than in nagLDL(-). The proportion of LDL particles containing apoJ (LDL/J+) was 3-fold lower in LDL(+) than in LDL(-). LDL/J+ particles shared several characteristics with agLDL(-), including increased negative charge and aggregation. apoJ-depleted particles (LDL/J-) showed increased susceptibility to aggregation, whether spontaneous or induced by proteolysis or lipolysis, as was revealed by turbidimetric analysis, gel filtration chromatography, lipoprotein precipitation, native gradient gel electrophoresis, circular dichroism, and transmission electronic microscopy. The addition of purified apoJ to total LDL also prevented its aggregation induced by proteolysis or lipolysis. These findings point to apoJ as a key modulator of LDL aggregation and reveal a putative new therapeutic strategy against atherosclerosis.