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用于高密度脂蛋白蛋白质组的无偏倚和靶向质谱分析

Unbiased and targeted mass spectrometry for the HDL proteome.

作者信息

Singh Sasha A, Aikawa Masanori

机构信息

aCenter for Interdisciplinary Cardiovascular Sciences, Cardiovascular Division bCenter for Excellence in Vascular Biology, Cardiovascular Division, Department of Medicine cChanning Division of Network Medicine, Brigham and Women's Hospital, Harvard Medical School, Boston, Massachusetts, USA.

出版信息

Curr Opin Lipidol. 2017 Feb;28(1):68-77. doi: 10.1097/MOL.0000000000000374.

DOI:10.1097/MOL.0000000000000374
PMID:28002079
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6211176/
Abstract

PURPOSE OF REVIEW

Mass spectrometry is an ever evolving technology that is equipped with a variety of tools for protein research. Some lipoprotein studies, especially those pertaining to HDL biology, have been exploiting the versatility of mass spectrometry to understand HDL function through its proteome. Despite the role of mass spectrometry in advancing research as a whole, however, the technology remains obscure to those without hands on experience, but still wishing to understand it. In this review, we walk the reader through the coevolution of common mass spectrometry workflows and HDL research, starting from the basic unbiased mass spectrometry methods used to profile the HDL proteome to the most recent targeted methods that have enabled an unprecedented view of HDL metabolism.

RECENT FINDINGS

Unbiased global proteomics have demonstrated that the HDL proteome is organized into subgroups across the HDL size fractions providing further evidence that HDL functional heterogeneity is in part governed by its varying protein constituents. Parallel reaction monitoring, a novel targeted mass spectrometry method, was used to monitor the metabolism of HDL apolipoproteins in humans and revealed that apolipoproteins contained within the same HDL size fraction exhibit diverse metabolic properties.

SUMMARY

Mass spectrometry provides a variety of tools and strategies to facilitate understanding, through its proteins, the complex biology of HDL.

摘要

综述目的

质谱技术是一项不断发展的技术,具备多种用于蛋白质研究的工具。一些脂蛋白研究,尤其是那些与高密度脂蛋白(HDL)生物学相关的研究,一直在利用质谱技术的多功能性,通过其蛋白质组来了解HDL的功能。然而,尽管质谱技术在推动整体研究方面发挥了作用,但对于那些没有实际操作经验却仍希望了解该技术的人来说,它仍然晦涩难懂。在本综述中,我们将引导读者了解常见质谱工作流程与HDL研究的共同发展历程,从用于描绘HDL蛋白质组的基本无偏向质谱方法,到能够以前所未有的视角观察HDL代谢的最新靶向方法。

最新发现

无偏向的全蛋白质组学研究表明,HDL蛋白质组在HDL大小分级中被组织成亚组,这进一步证明了HDL功能异质性部分受其不同蛋白质成分的影响。平行反应监测是一种新型靶向质谱方法,用于监测人类HDL载脂蛋白的代谢,结果显示同一HDL大小分级中所含的载脂蛋白具有不同的代谢特性。

总结

质谱技术提供了多种工具和策略,有助于通过其蛋白质来理解HDL复杂的生物学特性。

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