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用荧光磷脂底物探测磷脂酶a(2)。

Probing phospholipase a(2) with fluorescent phospholipid substrates.

作者信息

Wichmann Oliver, Gelb Michael H, Schultz Carsten

机构信息

European Molecular Biology Laboratorium, Gene Expression Programme, Meyerhofstrasse 1, 69117 Heidelberg, Germany.

出版信息

Chembiochem. 2007 Sep 3;8(13):1555-69. doi: 10.1002/cbic.200600462.

DOI:10.1002/cbic.200600462
PMID:17661302
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2394861/
Abstract

The Foerster resonance energy transfer-based sensor, PENN, measures intracellular phospholipase A(2) (PLA(2)) activity in living cells and small organisms. In an attempt to modify the probe for the detection of particular isoforms, we altered the sn-2 fatty acid in such a way that either one or three of the Z double bonds in arachidonic acid were present in the sensor molecule. Arachidonic-acid-mimicking fatty acids were prepared by copper-mediated coupling reactions. Probes with a single double bond in the 5-position exhibited favorable substrate properties for secretory PLA(2)s. In vitro experiments with the novel unsaturated doubly labeled phosphatidylethanolamine derivatives showed preferred cleavage of the sensor PENN2 (one double bond) by the physiologically important group V sPLA(2), while the O-methyl-derivative PMNN2 was accepted best by the isoform from hog pancreas. For experiments in living cells, we demonstrated that bioactivation via S-acetylthioethyl (SATE) groups is essential for probe performance. Surprisingly, membrane-permeant versions of the new sensors that contained double bonds, PENN2 and PENN3, were only cleaved to a minor extent in HeLa cells while the saturated form, PENN, was well accepted.

摘要

基于Förster共振能量转移的传感器PENN可测量活细胞和小型生物体中的细胞内磷脂酶A2(PLA2)活性。为了对探针进行修饰以检测特定亚型,我们以这样一种方式改变了sn-2脂肪酸,即传感器分子中存在花生四烯酸中的一个或三个Z双键。通过铜介导的偶联反应制备了模拟花生四烯酸的脂肪酸。在5位具有单个双键的探针表现出对分泌型PLA2有利的底物特性。对新型不饱和双标记磷脂酰乙醇胺衍生物进行的体外实验表明,生理上重要的V组sPLA2对传感器PENN2(一个双键)具有优先切割作用,而O-甲基衍生物PMNN2最易被猪胰腺中的亚型接受。对于活细胞实验,我们证明通过S-乙酰硫代乙基(SATE)基团进行生物活化对于探针性能至关重要。令人惊讶的是,含有双键的新型传感器PENN2和PENN3的膜渗透形式在HeLa细胞中仅被少量切割,而饱和形式的PENN则被很好地接受。

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