新的藻体连接蛋白 ApcI 调节 Synechocystis sp. PCC 6803 的强光适应性

Roberto Espinoza-Corral, Tomáš Zavřel, Markus Sutter, Chase H Leslie, Kunwei Yang, Warren F Beck, Jan Červený, Cheryl A Kerfeld
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摘要

叶绿体是一种多功能蓝藻天线复合体,可收集光能以驱动光合作用。这些复合体还能适应各种光照条件,在强光下分解以防止光氧化,在弱光下排列成行以提高光收集效率。光质也会影响藻体的结构和功能,如在远红光照射下观察到的那样。在这里,我们描述了一种新的藻体连接蛋白ApcI(以前的假说蛋白sll1911),它在红光下特异表达。我们利用突变菌株分析、藻胶体结合实验和蛋白质相互作用研究对 Synechocystis sp.与野生型相比,apcI 的突变赋予了 Synechocystis sp.结合实验表明,ApcI利用一个同源的C-末端结构域取代了连接蛋白ApcG位于藻体核心面向膜的一侧。此外,还发现 ApcI 的 N 端延伸部分与光系统 II 相互作用。我们的发现凸显了藻体重塑对适应不同光照条件的重要性。ApcI的表征为蓝藻优化光收集以应对不同光环境的机制提供了新的见解。
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The new phycobilisome linker protein ApcI regulates high light adaptation in Synechocystis sp. PCC 6803
Phycobilisomes are versatile cyanobacterial antenna complexes that harvest light energy to drive photosynthesis. These complexes can also adapt to various light conditions, dismantling under high light to prevent photo-oxidation and arranging in rows under low light to increase light harvesting efficiency. Light quality also influences phycobilisome structure and function, as observed under far-red light exposure. Here we describe a new, phycobilisome linker protein, ApcI (previously hypothetical protein sll1911), expressed specifically under red light. We characterized ApcI in Synechocystis sp. PCC 6803 using mutant strain analyses, phycobilisome binding experiments, and protein interaction studies. Mutation of apcI conferred high light tolerance to Synechocystis sp. PCC 6803 compared to wild type with reduced energy transfer from phycobilisomes to the photosystems. Binding experiments revealed that ApcI replaces the linker protein ApcG at the membrane-facing side of the phycobilisome core using a paralogous C-terminal domain. Additionally, the N-terminal extension of ApcI was found to interact with photosystem II. Our findings highlight the importance of phycobilisome remodeling for adaptation under different light conditions. The characterization of ApcI provides new insights into the mechanisms by which cyanobacteria optimize light-harvesting in response to varying light environments.
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