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蓝藻光敏色素 2 光传感器的结构暗示了色氨酸开关在光敏色素信号中的作用。

Structure of the cyanobacterial phytochrome 2 photosensor implies a tryptophan switch for phytochrome signaling.

机构信息

From the Department of Chemistry, Biomedical Research Centre, Philipps-Universität, D-35032 Marburg, Germany.

出版信息

J Biol Chem. 2013 Dec 13;288(50):35714-25. doi: 10.1074/jbc.M113.510461. Epub 2013 Oct 30.

DOI:10.1074/jbc.M113.510461
PMID:24174528
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3861623/
Abstract

Phytochromes are highly versatile photoreceptors, which occur ubiquitously in plants as well as in many light-responsive microorganisms. Here, photosynthetic cyanobacteria utilize up to three different phytochrome architectures, where only the plant-like and the single-domain cyanobacteriochromes are structurally characterized so far. Cph2 represents a third group in Synechocystis species and affects their capability of phototaxis by controlling c-di-GMP synthesis and degradation. The 2.6-Å crystal structure of its red/far-red responsive photosensory module in the Pr state reveals a tandem-GAF bidomain that lacks the figure-of-eight knot of the plant/cph1 subfamily. Its covalently attached phycocyanobilin chromophore adopts a highly tilted ZZZssa conformation with a novel set of interactions between its propionates and the GAF1 domain. The tongue-like protrusion from the GAF2 domain interacts with the GAF1-bound chromophore via its conserved PRXSF, WXE, and W(G/A)G motifs. Mutagenesis showed that the integrity of the tongue is indispensable for Pr → Pfr photoconversion and involves a swap of the motifs' tryptophans within the tongue-GAF1 interface. This "Trp switch" is supposed to be a crucial element for the photochromicity of all multidomain phytochromes.

摘要

光敏色素是高度多功能的光受体,广泛存在于植物以及许多对光有反应的微生物中。这里,光合蓝藻利用多达三种不同的光敏色素结构,目前只有植物样和单结构域蓝藻色素被结构表征。Cph2 代表聚球藻属物种中的第三组,通过控制 c-di-GMP 的合成和降解来影响它们的趋光性能力。其在 Pr 状态下的红光/远红光响应光敏模块的 2.6Å 晶体结构揭示了串联 GAF 双域,该结构缺乏植物/cph1 亚家族的八结环。其共价连接的藻红胆素发色团采用高度倾斜的 ZZZssa 构象,其丙酸酯与 GAF1 结构域之间存在一组新的相互作用。来自 GAF2 结构域的舌状突起通过其保守的 PRXSF、WXE 和 W(G/A)G 基序与 GAF1 结合的发色团相互作用。突变显示,舌的完整性对于 Pr → Pfr 光转化是不可或缺的,并且涉及舌-GAF1 界面内的基序色氨酸的交换。这个“色氨酸开关”被认为是所有多结构域光敏色素光变色性的关键要素。

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