Reaction Mechanism of the Terminal Plastoquinone QB in Photosystem II as Revealed by Time-Resolved Infrared Spectroscopy

IF 2.9 3区生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY

Biochemistry Biochemistry Pub Date : 2024-10-16 DOI:10.1021/acs.biochem.4c0050910.1021/acs.biochem.4c00509

Yuki Kato*, Honami Ito and Takumi Noguchi*,

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Abstract

The secondary plastoquinone (PQ) electron acceptor Q_B in photosystem II (PSII) undergoes a two-step photoreaction through electron transfer from the primary PQ electron acceptor Q_A, converting into plastoquinol (PQH₂). However, the detailed mechanism of the Q_B reactions remains elusive. Here, we investigated the reaction mechanism of Q_B in cyanobacterial PSII core complexes using two time-revolved infrared (TRIR) methods: dispersive-type TRIR spectroscopy and rapid-scan Fourier transform infrared spectroscopy. Upon the first flash, the ∼140 μs phase is attributed to electron transfer from Q_A^•– to Q_B, while the ∼2.2 and ∼440 ms phases are assigned to the binding of an internal PQ in a nearby cavity to the vacant Q_B site and an external PQ traveling to the Q_B site through channels, respectively, followed by immediate electron transfer. The resultant Q_B^•– is suggested to be in equilibrium with Q_BH^•, which is protonated at the distal oxygen. Upon the second flash, the ∼130 μs and ∼3.3 ms phases are attributed to electron transfer to Q_BH^• and the protonation of Q_B^•– followed by electron transfer, respectively, forming Q_BH^–, which then immediately accepts a proton from D1-H215 at the proximal oxygen to become Q_BH₂. The resultant D1-H215 anion is reprotonated in ∼22 ms via a pathway involving the bicarbonate ligand. The final ∼490 ms phase may reflect the release of PQH₂ and its replacement with PQ. The present results highlight the importance of time-resolved infrared spectroscopy in elucidating the mechanism of Q_B reactions in PSII.

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通过时间分辨红外光谱揭示光系统 II 中末端重醌 QB 的反应机制

光系统 II（PSII）中的次级质醌（PQ）电子受体 QB 通过初级 PQ 电子受体 QA 的电子转移，发生两步光反应，转化为质醌醇（PQH2）。然而，QB 反应的详细机理仍然难以捉摸。在此，我们利用两种时间变化红外光谱（TRIR）方法：色散型 TRIR 光谱和快速扫描傅立叶变换红外光谱，研究了蓝藻 PSII 核心复合物中 QB 的反应机制。在第一次闪光时，∼140 μs阶段是电子从QA--转移到QB的过程，而∼2.2和∼440 ms阶段则分别是附近空腔中的内部PQ与空置的QB位点结合以及外部PQ通过通道到达QB位点，然后立即进行电子转移的过程。由此产生的 QB- 与 QBH- 处于平衡状态，QBH- 在远端氧处质子化。在第二次闪光时，130 μs 和 3.3 ms 阶段分别是电子转移到 QBH- 和 QB--质子化，然后电子转移，形成 QBH-，然后立即从近端氧的 D1-H215 接受一个质子，成为 QBH2。由此产生的 D1-H215 阴离子在∼22 毫秒内通过涉及碳酸氢盐配体的途径再质子化。最后的 490 毫秒阶段可能反映了 PQH2 的释放及其与 PQ 的置换。本研究结果凸显了时间分辨红外光谱在阐明 PSII 中 QB 反应机理方面的重要性。

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

Biochemistry Biochemistry 生物-生化与分子生物学

CiteScore

5.50

自引率

3.40%

发文量

336

审稿时长

1-2 weeks

期刊介绍： Biochemistry provides an international forum for publishing exceptional, rigorous, high-impact research across all of biological chemistry. This broad scope includes studies on the chemical, physical, mechanistic, and/or structural basis of biological or cell function, and encompasses the fields of chemical biology, synthetic biology, disease biology, cell biology, nucleic acid biology, neuroscience, structural biology, and biophysics. In addition to traditional Research Articles, Biochemistry also publishes Communications, Viewpoints, and Perspectives, as well as From the Bench articles that report new methods of particular interest to the biological chemistry community.