镁螯合酶的活性位点。

The active site of magnesium chelatase.

作者信息

Adams Nathan B P, Bisson Claudine, Brindley Amanda A, Farmer David A, Davison Paul A, Reid James D, Hunter C Neil

机构信息

Department of Molecular Biology and Biotechnology, The University of Sheffield, Sheffield, UK.

Centre for Ultrastructural Imaging, New Hunt's House, Guy's Campus, King's College London, London, UK.

出版信息

Nat Plants. 2020 Dec;6(12):1491-1502. doi: 10.1038/s41477-020-00806-9. Epub 2020 Nov 30.

DOI:10.1038/s41477-020-00806-9

PMID:33257858

Abstract

The insertion of magnesium into protoporphyrin initiates the biosynthesis of chlorophyll, the pigment that underpins photosynthesis. This reaction, catalysed by the magnesium chelatase complex, couples ATP hydrolysis by a ChlID motor complex to chelation within the ChlH subunit. We probed the structure and catalytic function of ChlH using a combination of X-ray crystallography, computational modelling, mutagenesis and enzymology. Two linked domains of ChlH in an initially open conformation of ChlH bind protoporphyrin IX, and the rearrangement of several loops envelops this substrate, forming an active site cavity. This induced fit brings an essential glutamate (E660), proposed to be the key catalytic residue for magnesium insertion, into proximity with the porphyrin. A buried solvent channel adjacent to E660 connects the exterior bulk solvent to the active site, forming a possible conduit for the delivery of magnesium or abstraction of protons.

摘要

镁插入原卟啉启动了叶绿素的生物合成，叶绿素是光合作用的基础色素。该反应由镁螯合酶复合物催化，通过ChlID运动复合物水解ATP与ChlH亚基内的螯合作用相偶联。我们结合X射线晶体学、计算建模、诱变和酶学方法，探究了ChlH的结构和催化功能。ChlH最初处于开放构象时的两个相连结构域结合原卟啉IX，几个环的重排包裹住该底物，形成一个活性位点腔。这种诱导契合使一个必需的谷氨酸（E660）靠近卟啉，E660被认为是镁插入的关键催化残基。与E660相邻的一个埋藏溶剂通道将外部大量溶剂连接到活性位点，形成了一个可能用于输送镁或提取质子的管道。

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镁螯合酶的活性位点。

The active site of magnesium chelatase.

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