与人类胞质和线粒体脂肪酸合酶相关的酰基转移酶不同特异性的结构基础。
Structural basis for different specificities of acyltransferases associated with the human cytosolic and mitochondrial fatty acid synthases.
作者信息
Bunkoczi Gabor, Misquitta Stephanie, Wu Xiaoqiu, Lee Wen Hwa, Rojkova Alexandra, Kochan Grazyna, Kavanagh Kathryn L, Oppermann Udo, Smith Stuart
机构信息
Structural Genomics Consortium, University of Oxford, Oxford OX3 7LD, UK.
出版信息
Chem Biol. 2009 Jun 26;16(6):667-75. doi: 10.1016/j.chembiol.2009.04.011.
Abstract
Animals employ two systems for the de novo biosynthesis of fatty acids: a megasynthase complex in the cytosol (type I) that produces mainly palmitate, and an ensemble of freestanding enzymes in the mitochondria (type II) that produces mainly octanoyl moieties. The acyltransferases responsible for initiation of fatty acid biosynthesis in the two compartments are distinguished by their different substrate specificities: the type I enzyme transfers both the acetyl primer and the malonyl chain extender, whereas the type II enzyme is responsible for translocation of only the malonyl substrate. Crystal structures for the type I and II enzymes, supported by in silico substrate docking studies and mutagenesis experiments that alter their respective specificities, reveal that, although the two enzymes adopt a similar overall fold, subtle differences at their catalytic centers account for their different specificities.
摘要
动物利用两种系统进行脂肪酸的从头生物合成
一种是存在于胞质溶胶中的大型合成酶复合体(I型),主要产生棕榈酸;另一种是线粒体中一组独立的酶(II型),主要产生辛酰基部分。负责两个区室中脂肪酸生物合成起始的酰基转移酶因其不同的底物特异性而有所区别:I型酶转移乙酰引物和丙二酰链延长剂,而II型酶仅负责丙二酰底物的转运。I型和II型酶的晶体结构,得到改变其各自特异性的计算机辅助底物对接研究和诱变实验的支持,结果表明,尽管这两种酶具有相似的整体折叠结构,但它们催化中心的细微差异导致了不同的特异性。
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