光合放氧中心的蛋白质连接
Protein Ligation of the Photosynthetic Oxygen-Evolving Center.
作者信息
Debus Richard J
机构信息
Department of Biochemistry, University of California at Riverside, Riverside, CA 92521-0129.
出版信息
Coord Chem Rev. 2008 Feb;252(3-4):244-258. doi: 10.1016/j.ccr.2007.09.022.
Abstract
Photosynthetic water oxidation is catalyzed by a unique Mn(4)Ca cluster in Photosystem II. The ligation environment of the Mn(4)Ca cluster optimizes the cluster's reactivity at each step in the catalytic cycle and minimizes the release of toxic, partly oxidized intermediates. However, our understanding of the cluster's ligation environment remains incomplete. Although the recent X-ray crystallographic structural models have provided great insight and are consistent with most conclusions of earlier site-directed mutagenesis studies, the ligation environments of the Mn(4)Ca cluster in the two available structural models differ in important respects. Furthermore, while these structural models and the earlier mutagenesis studies agree on the identity of most of the Mn(4)Ca cluster's amino acid ligands, they disagree on the identity of others. This review describes mutant characterizations that have been undertaken to probe the ligation environment of the Mn(4)Ca cluster, some of which have been inspired by the recent X-ray crystallographic structural models. Many of these characterizations have involved Fourier Transform Infrared (FTIR) difference spectroscopy because of the extreme sensitivity of this form of spectroscopy to the dynamic structural changes that occur during an enzyme's catalytic cycle.
摘要
光合水氧化由光系统II中独特的Mn(4)Ca簇催化。Mn(4)Ca簇的配位环境在催化循环的每个步骤中优化了簇的反应活性,并使有毒的部分氧化中间体的释放降至最低。然而,我们对该簇配位环境的理解仍不完整。尽管最近的X射线晶体学结构模型提供了深刻的见解,并且与早期定点诱变研究的大多数结论一致,但两个现有结构模型中Mn(4)Ca簇的配位环境在重要方面存在差异。此外,虽然这些结构模型和早期诱变研究在大多数Mn(4)Ca簇氨基酸配体的身份上达成一致,但在其他配体的身份上存在分歧。本综述描述了为探究Mn(4)Ca簇的配位环境而进行的突变体表征,其中一些受到了最近X射线晶体学结构模型的启发。由于这种光谱形式对酶催化循环中发生的动态结构变化具有极高的灵敏度,许多这些表征都涉及傅里叶变换红外(FTIR)差光谱。
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