高密度脂蛋白亚类蛋白质组学分析及高密度脂蛋白成熟过程中蛋白质动态变化的功能意义。

HDL subclass proteomic analysis and functional implication of protein dynamic change during HDL maturation.

机构信息

Cardiovascular Medicine Department, Sun Yat-sen Memorial Hospital, Sun Yat-sen University, Guangzhou, 510120, China; Centers for Metabolic & Cardiovascular Research, Department of Pharmacology, Temple University School of Medicine, Philadelphia, PA, 19140, USA; Guangdong Province Key Laboratory of Arrhythmia and Electrophysiology, Guangzhou, China.

Cardiopulmonary Branch, NHLBI, National Institutes of Health, Building 10 Room 2C433, Bethesda, MD, 20892, USA; Saha Cardiovascular Research Center, University of Kentucky, Lexington, KY, 40536, USA.

出版信息

Redox Biol. 2019 Jun;24:101222. doi: 10.1016/j.redox.2019.101222. Epub 2019 May 17.

DOI:10.1016/j.redox.2019.101222

PMID:31153037

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6541906/

Abstract

Recent clinical trials reported that increasing high-density lipoprotein-cholesterol (HDL-C) levels does not improve cardiovascular outcomes. We hypothesize that HDL proteome dynamics determine HDL cardioprotective functions. In this study, we characterized proteome profiles in HDL subclasses and established their functional connection. Mouse plasma was fractionized by fast protein liquid chromatography, examined for protein, cholesterial, phospholipid and trigliceride content. Small, medium and large (S/M/L)-HDL subclasseses were collected for proteomic analysis by mass spectrometry. Fifty-one HDL proteins (39 in S-HDL, 27 in M-HDL and 29 in L-HDL) were identified and grouped into 4 functional categories (lipid metabolism, immune response, coagulation, and others). Eleven HDL common proteins were identified in all HDL subclasses. Sixteen, 3 and 7 proteins were found only in S-HDL, M-HDL and L-HDL, respectively. We established HDL protein dynamic distribution in S/M/L-HDL and developed a model of protein composition change during HDL maturation. We found that cholesterol efflux and immune response are essential functions for all HDL particles, and amino acid metabolism is a special function of S-HDL, whereas anti-coagulation is special for M-HDL. Pon1 is recruited into M/L-HDL to provide its antioxidative function. ApoE is incorporated into L-HDL to optimize its cholesterial clearance function. Next, we acquired HDL proteome data from Pubmed and identified 12 replicated proteins in human and mouse HDL particle. Finally, we extracted 3 shared top moleccular pathways (LXR/RXR, FXR/RXR and acute phase response) for all HDL particles and 5 top disease/bio-functions differentially related to S/M/L-HDL subclasses, and presented one top net works for each HDL subclass. We conclude that beside their essencial functions of cholesterol efflux and immune response, HDL aquired antioxidative and cholesterol clearance functions by recruiting Pon1 and ApoE during HDL maturation.

摘要

最近的临床试验报告表明，增加高密度脂蛋白胆固醇（HDL-C）水平并不能改善心血管结局。我们假设 HDL 蛋白质组动力学决定了 HDL 的心脏保护功能。在这项研究中，我们描述了 HDL 亚类中的蛋白质组谱，并建立了它们的功能联系。通过快速蛋白质液相色谱法对小鼠血浆进行分馏，检查蛋白质、胆固醇、磷脂和甘油三酯含量。收集小、中、大（S/M/L）-HDL 亚类进行质谱分析。鉴定了 51 种 HDL 蛋白（39 种在 S-HDL 中，27 种在 M-HDL 中，29 种在 L-HDL 中），并将其分为 4 个功能类别（脂质代谢、免疫反应、凝血和其他）。在所有 HDL 亚类中都鉴定到 11 种 HDL 共同蛋白。分别在 S-HDL、M-HDL 和 L-HDL 中仅发现 16、3 和 7 种蛋白质。我们建立了 S/M/L-HDL 中 HDL 蛋白质的动态分布，并建立了 HDL 成熟过程中蛋白质组成变化的模型。我们发现胆固醇外排和免疫反应是所有 HDL 颗粒的基本功能，而氨基酸代谢是 S-HDL 的特殊功能，而抗凝血则是 M-HDL 的特殊功能。PON1 被募集到 M/L-HDL 中以提供其抗氧化功能。ApoE 被掺入到 L-HDL 中以优化其胆固醇清除功能。接下来，我们从 Pubmed 中获取了 HDL 蛋白质组数据，并在人和小鼠的 HDL 颗粒中鉴定到 12 种复制蛋白。最后，我们提取了所有 HDL 颗粒共有的 3 个主要分子途径（LXR/RXR、FXR/RXR 和急性期反应）和与 S/M/L-HDL 亚类相关的 5 个差异较大的疾病/生物功能，并为每个 HDL 亚类呈现了一个主要网络。我们的结论是，除了胆固醇外排和免疫反应等基本功能外，HDL 在成熟过程中通过募集 PON1 和 ApoE 获得了抗氧化和胆固醇清除功能。

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高密度脂蛋白亚类蛋白质组学分析及高密度脂蛋白成熟过程中蛋白质动态变化的功能意义。

HDL subclass proteomic analysis and functional implication of protein dynamic change during HDL maturation.

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