Is orange carotenoid protein photoactivation a single-photon process?

IF 2.4 Q3 BIOPHYSICS
Biophysical reports Pub Date : 2022-08-23 eCollection Date: 2022-09-14 DOI:10.1016/j.bpr.2022.100072
Stanisław Niziński, Ilme Schlichting, Jacques-Philippe Colletier, Diana Kirilovsky, Gotard Burdzinski, Michel Sliwa
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引用次数: 3

Abstract

In all published photoactivation mechanisms of orange carotenoid protein (OCP), absorption of a single photon by the orange dark state starts a cascade of red-shifted OCP ground-state intermediates that subsequently decay within hundreds of milliseconds, resulting in the formation of the final red form OCPR, which is the biologically active form that plays a key role in cyanobacteria photoprotection. A major challenge in deducing the photoactivation mechanism is to create a uniform description explaining both single-pulse excitation experiments, involving single-photon absorption, and continuous light irradiation experiments, where the red-shifted OCP intermediate species may undergo re-excitation. We thus investigated photoactivation of Synechocystis OCP using stationary irradiation light with a biologically relevant photon flux density coupled with nanosecond laser pulse excitation. The kinetics of photoactivation upon continuous and nanosecond pulse irradiation light show that the OCPR formation quantum yield increases with photon flux density; thus, a simple single-photon model cannot describe the data recorded for OCP in vitro. The results strongly suggest a consecutive absorption of two photons involving a red intermediate with ≈100 millisecond lifetime. This intermediate is required in the photoactivation mechanism and formation of the red active form OCPR.

Abstract Image

Abstract Image

Abstract Image

橙类胡萝卜素蛋白的光激活是单光子过程吗?
在所有已发表的橙色类胡萝卜素蛋白(OCP)的光激活机制中,单个光子被橙色暗态吸收,会引发一系列红移的OCP基态中间体,这些中间体随后在数百毫秒内衰变,最终形成红色形态的OCPR,这是一种生物活性形态,在蓝藻光保护中起着关键作用。推断光激活机制的一个主要挑战是创建一个统一的描述来解释涉及单光子吸收的单脉冲激发实验和连续光照射实验,其中红移的OCP中间物质可能经历再激发。因此,我们使用具有生物相关光子通量密度的固定照射光与纳秒激光脉冲激发耦合研究了聚囊藻OCP的光激活。连续和纳秒脉冲辐照光的光活化动力学表明,OCPR形成量子产率随光子通量密度的增加而增加;因此,一个简单的单光子模型不能描述体外OCP记录的数据。结果强烈表明两个光子的连续吸收涉及一个寿命约为100毫秒的红色中间体。这种中间体是光活化机制和红色活性形式OCPR形成所必需的。
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来源期刊
Biophysical reports
Biophysical reports Biophysics
CiteScore
2.40
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75 days
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