Structure-function relationships of HDL in diabetes and coronary heart disease
Mathias Cardner, Mustafa Yalcinkaya, Sandra Goetze, Edlira Luca, Miroslav Balaz, Monika Hunjadi, Johannes Hartung, Andrej Shemet, Nicolle Kränkel, Silvija Radosavljevic, Michaela Keel, Alaa Othman, Gergely Karsai, Thorsten Hornemann, Manfred Claassen, Gerhard Liebisch, Erick Carreira, Andreas Ritsch, Ulf Landmesser, Jan Krützfeldt, Christian Wolfrum, Bernd Wollscheid, Niko Beerenwinkel, Lucia Rohrer, Arnold von Eckardstein
Mathias Cardner, Mustafa Yalcinkaya, Sandra Goetze, Edlira Luca, Miroslav Balaz, Monika Hunjadi, Johannes Hartung, Andrej Shemet, Nicolle Kränkel, Silvija Radosavljevic, Michaela Keel, Alaa Othman, Gergely Karsai, Thorsten Hornemann, Manfred Claassen, Gerhard Liebisch, Erick Carreira, Andreas Ritsch, Ulf Landmesser, Jan Krützfeldt, Christian Wolfrum, Bernd Wollscheid, Niko Beerenwinkel, Lucia Rohrer, Arnold von Eckardstein
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Research Article Cardiology Metabolism

Structure-function relationships of HDL in diabetes and coronary heart disease

Abstract

High-density lipoproteins (HDL) contain hundreds of lipid species and proteins and exert many potentially vasoprotective and antidiabetogenic activities on cells. To resolve structure-function-disease relationships of HDL, we characterized HDL of 51 healthy subjects and 98 patients with diabetes (T2DM), coronary heart disease (CHD), or both for protein and lipid composition, as well as functionality in 5 cell types. The integration of 40 clinical characteristics, 34 nuclear magnetic resonance (NMR) features, 182 proteins, 227 lipid species, and 12 functional read-outs by high-dimensional statistical modeling revealed, first, that CHD and T2DM are associated with different changes of HDL in size distribution, protein and lipid composition, and function. Second, different cellular functions of HDL are weakly correlated with each other and determined by different structural components. Cholesterol efflux capacity (CEC) was no proxy of other functions. Third, 3 potentially novel determinants of HDL function were identified and validated by the use of artificially reconstituted HDL, namely the sphingadienine-based sphingomyelin SM 42:3 and glycosylphosphatidylinositol-phospholipase D1 for the ability of HDL to inhibit starvation-induced apoptosis of human aortic endothelial cells and apolipoprotein F for the ability of HDL to promote maximal respiration of brown adipocytes.

Authors

Mathias Cardner, Mustafa Yalcinkaya, Sandra Goetze, Edlira Luca, Miroslav Balaz, Monika Hunjadi, Johannes Hartung, Andrej Shemet, Nicolle Kränkel, Silvija Radosavljevic, Michaela Keel, Alaa Othman, Gergely Karsai, Thorsten Hornemann, Manfred Claassen, Gerhard Liebisch, Erick Carreira, Andreas Ritsch, Ulf Landmesser, Jan Krützfeldt, Christian Wolfrum, Bernd Wollscheid, Niko Beerenwinkel, Lucia Rohrer, Arnold von Eckardstein

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Figure 5

Sphingomyelins SM 42:2 and SM 42:3 decrease apoptosis in human aortic endothelial cells (HAECs).

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Sphingomyelins SM 42:2 and SM 42:3 decrease apoptosis in human aortic en...
(A) Reconstituted HDL (rHDL) contain 3 different concentrations of SM 42:2 or SM 42:3, which correspond to the lowest, median, and highest concentration relative to phosphatidylcholine in native HDL. HAECs were starved in the absence or presence of ± 20 μg/mL rHDL for 16 hours. Apoptosis was recorded by using the free nucleosome assay. (B) SM 42:2 and SM 42:3 were reconstituted into unilamellar vesicles with 2 different concentrations. HAECs were starved in absence and presence of unilamellar vesicle ± SM 42:2 or SM 42:3 for 16 hours, and apoptosis was recorded by free nucleosome assay. Data are presented as mean ± SD of 3 independent experiments, each with 4 replicates, and were analyzed by 1-way ANOVA coupled with Dunnett’s test for multiple comparisons against rHDL and no additives. ***P < 0.001; **P < 0.01; *P < 0.05.