An abundant dysfunctional apolipoprotein A1 in human atheroma

Huang, Ying; DiDonato, Joseph A.; Levison, Bruce S.; Schmitt, Dave; Li, Lin; Wu, Yuping; Buffa, Jennifer A.; Kim, Timothy; Gerstenecker, Gary; Gu, Xiaodong; Kadiyala, Chandra S; Wang, Zeneng; Culley, Miranda K.; Hazen, Jennie E; DiDonato, Anthony J.; Fu, Xiaoming; Berisha, Stela Z.; Peng, Daoquan; Nguyen, Trung Ngoc; Liang, Shaohong; Chuang, Chia‐Chi; Cho, Leslie; Plow, Edward F.; Fox, Paul L.; Gogonea, Valentin; Tang, W.H. Wilson; Parks, John S.; Fisher, Edward A.; Smith, Jonathan; Hazen, Stanley L.

doi:10.1038/nm.3459

Cited by 326 publications

(331 citation statements)

References 66 publications

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“…135 Also, apoA-I with oxidative modification of the tryptophan residue Trp-72, a form of apoA-I that is highly prevalent in apoA-I recovered from atheroma and increased in the plasma of patients with cardiovascular disease or CAD, had significantly lower cholesterol acceptor capacity. 131 Mechanistically, MPO-dependent chlorination of apoA-I interfered with the binding of apoA-I to ABCA1 and as a consequence chlorinated apoA-I failed to activate the accompanying JAK2 signaling. 132 However, it must be noted that in plasma less than 200 of 1 million apoA-I molecules contain oxidized Tyr-192 or Trp-72 residues.…”

Section: Myeloperoxidase-mediated Protein Modificationsmentioning

confidence: 99%

“…132 However, it must be noted that in plasma less than 200 of 1 million apoA-I molecules contain oxidized Tyr-192 or Trp-72 residues. 129, 131 In view of their very low quantity it is unlikely that these modifications reduce cholesterol efflux capacity of (apoB-free) plasma or HDL by simple loss-of-function in the interaction with ABCA1. Rather additional gain of dysfunction is necessary to explain reduced ABCA1-mediated cholesterol efflux capacity of plasma by these modifications.…”

Section: Myeloperoxidase-mediated Protein Modificationsmentioning

confidence: 99%

“…41 Likewise, differences in cholesterol efflux capacity have been attributed to differences in HDL particle number, HDL subclass distribution, phospholipid composition, 86 the presence of SAA, 58-61 or posttranslational modifications. [127][128][129][130][131][132] As yet it is not clear whether these findings reflect redundancy or complexity of HDL interactions with endothelial cells or result from confounding.…”

Section: Diagnostics and Biomarker Discoverymentioning

confidence: 99%

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Dysfunctional high-density lipoproteins in coronary heart disease: implications for diagnostics and therapy

Annema

Eckardstein

2016

Translational Research

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Low plasma levels of high-density lipoprotein (HDL) cholesterol are associated with increased risks of coronary heart disease. HDL mediates cholesterol efflux from macrophages for reverse transport to the liver and elicits many anti-inflammatory and anti-oxidative activities which are potentially antiatherogenic. Nevertheless, HDL has not been successfully targeted by drugs for prevention or treatment of cardiovascular diseases. One potential reason is the targeting of HDL cholesterol which does not capture the structural and functional complexity of HDL particles. Hundreds of lipid species and dozens of proteins as well as several microRNAs have been identified in HDL. This physiological heterogeneity is further increased in pathologic conditions due to additional quantitative and qualitative molecular changes of HDL components which have been associated with both loss of physiological function and gain of pathologic dysfunction. This structural and functional complexity of HDL has prevented clear assignments of molecules to the functions of normal HDL and dysfunctions of pathologic HDL. Systematic analyses of structure-function relationships of HDL-associated molecules and their modifications are needed to test the different components and functions of HDL for their relative contribution in the pathogenesis of atherosclerosis. The derived biomarkers and targets may eventually help to exploit HDL for treatment and diagnostics of cardiovascular diseases.

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Section: Myeloperoxidase-mediated Protein Modificationsmentioning

confidence: 99%

Section: Myeloperoxidase-mediated Protein Modificationsmentioning

confidence: 99%

Section: Diagnostics and Biomarker Discoverymentioning

confidence: 99%

See 1 more Smart Citation

Dysfunctional high-density lipoproteins in coronary heart disease: implications for diagnostics and therapy

Annema

Eckardstein

2016

Translational Research

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“…76 MPO-mediated oxidation of Trp 72 leads to the formation of the oxTrp72-ApoA1 variant that is abundantly present (20% of total apoA1 in atherosclerotic vessels) in the plaque and lack an ability to activate ABCA1. 77 MPO-dependent nitration and chlorination of ApoA1 at Tyr 192 along with methionine oxidation results in a loss of ability to activate RCT. 78,79 Modified ApoA1 form HDL with impaired function.…”

Section: Role Of Modified Apoa1 In Atherosclerosismentioning

confidence: 99%

“…The 2-OH-Trp moiety is the immunogenic epitope recognized by a high-affinity monoclonal antibody that is also capable to bind to HDL treated with MPO. 77 Recently, Teixeira et al 83 found two novel immunoreactive peptides recognizable by self-antibodies from MI patients with higher titers of ApoA1 IgG. The first peptide (peptide C) comprises 28 residues (Gln 240 -Gln 267 ) and includes a whole non-polar α-helix involved in lipid solubilization.…”

Section: Apoa1 Epitopesmentioning

confidence: 99%

ApoA1 and ApoA1-specific self-antibodies in cardiovascular disease

Chistiakov

Orekhov

Bobryshev

2016

Laboratory Investigation

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Chromatography of Membrane Proteins and Lipoproteins

Zolla

D’Alessandro

Lana

2016

Encyclopedia of Analytical Chemistry

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The available methods for the separation of membrane proteins and lipoproteins are sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS/PAGE), followed by immunoblotting, isoelectric focusing (IEF), and capillary electrophoresis (CE), along with the recently introduced gel‐based native techniques (blue native (BN) and clear native (CN)), and high‐performance liquid chromatography (HPLC). In this article, it is shown that HPLC techniques, given their wide versatility, relative ease of use, and high resolution, may be considered the most valuable tool for the characterization of virtually any hydrophobic protein. Application examples are described, and comparisons with other methods are discussed. Moreover, HPLC is not a destructive technique, and therefore, proteins, once separated, are available for further analytical investigations. Among these techniques, quantitative and qualitative analyses of the separated fractions can be obtained through other biophysical approaches, such as crystallography or structural spectroscopy. Most of these approaches require preliminary protein purification (90% or higher), which could be rapidly obtained through preliminary HPLC.

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An abundant dysfunctional apolipoprotein A1 in human atheroma

Cited by 326 publications

References 66 publications

Dysfunctional high-density lipoproteins in coronary heart disease: implications for diagnostics and therapy

Dysfunctional high-density lipoproteins in coronary heart disease: implications for diagnostics and therapy

ApoA1 and ApoA1-specific self-antibodies in cardiovascular disease

Chromatography of Membrane Proteins and Lipoproteins

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