How electron tunneling and uphill excitation energy transfer support photochemistry in Halomicronema hongdechloris.

IF 2.9 3区生物学 Q2 PLANT SCIENCES

Photosynthesis Research Pub Date : 2024-03-01 Epub Date: 2024-01-10 DOI:10.1007/s11120-023-01064-4

Franz-Josef Schmitt, Anne Hüls, Marcus Moldenhauer, Thomas Friedrich

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Abstract

Halomicronema hongdechloris, the first cyanobacterium reported to produce the red-shifted chlorophyll f (Chl f) upon acclimation to far-red light, demonstrates remarkable adaptability to diverse light conditions. The photosystem II (PS II) of this organism undergoes reversible changes in its Chl f content, ranging from practically zero under white-light culture conditions to a Chl f: Chl a ratio of up to 1:8 when exposed to far-red light (FRL) of 720-730 nm for several days. Our ps time- and wavelength-resolved fluorescence data obtained after excitation of living H. hongdechloris cells indicate that the Soret band of a far-red (FR) chlorophyll involved in charge separation absorbs around 470 nm. At 10 K, the fluorescence decay at 715-720 nm is still fast with a time constant of 165 ps indicating an efficient electron tunneling process. There is efficient excitation energy transfer (EET) from 715-720 nm to 745 nm with the latter resulting from FR Chl f, which mainly functions as light-harvesting pigment upon adaptation to FRL. From there, excitation energy reaches the primary donor in the reaction center of PS II with an energetic uphill EET mechanism inducing charge transfer. The fluorescence data are well explained with a secondary donor P_D1 represented by a red-shifted Chl a molecule with characteristic fluorescence around 715 nm and a more red-shifted FR Chl f with fluorescence around 725 nm as primary donor at the Chl_D1 or P_D2 position.

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电子隧道和上坡激发能量转移如何支持卤米龙（Halomicronema hongdechloris）的光化学。

卤米龙（Halomicronema hongdechloris）是第一个被报道在适应远红光后产生红移叶绿素f（Chl f）的蓝藻，它对不同光照条件的适应能力非常强。这种生物的光系统 II（PS II）的叶绿素 f 含量会发生可逆变化，从白光培养条件下的几乎为零，到暴露在 720-730 纳米的远红光（FRL）下数天后叶绿素 f：叶绿素 a 的比例高达 1:8。我们对活的 H. hongdechloris 细胞进行激发后获得的 ps 时间和波长分辨荧光数据表明，参与电荷分离的远红光（FR）叶绿素的 Soret 波段吸收波长约为 470 nm。在 10 K 时，715-720 nm 处的荧光衰减仍然很快，时间常数为 165 ps，这表明电子隧道过程非常有效。从 715-720 纳米到 745 纳米之间存在高效的激发能量转移（EET），后者来自 FR Chl f，它在适应 FRL 后主要发挥光收集色素的作用。从这里，激发能量到达 PS II 反应中心的初级供体，通过高能上坡 EET 机制诱导电荷转移。在 ChlD1 或 PD2 的位置上，以具有 715 nm 附近特征荧光的红移 Chl a 分子为代表的次级供体 PD1 和具有 725 nm 附近荧光的更红移 FR Chl f 作为初级供体，可以很好地解释荧光数据。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Photosynthesis Research 生物-植物科学

CiteScore

6.90

自引率

8.10%

发文量

审稿时长

4.5 months

期刊介绍： Photosynthesis Research is an international journal open to papers of merit dealing with both basic and applied aspects of photosynthesis. It covers all aspects of photosynthesis research, including, but not limited to, light absorption and emission, excitation energy transfer, primary photochemistry, model systems, membrane components, protein complexes, electron transport, photophosphorylation, carbon assimilation, regulatory phenomena, molecular biology, environmental and ecological aspects, photorespiration, and bacterial and algal photosynthesis.