Kinetics of reformation of an S0 state capable of progressing to an S1 state after the O2 release by Photosystem II

Alain Boussac, Julien Selles, Miwa Sugiura
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Abstract

The active site for water oxidation in Photosystem II (PSII ) consists of a Mn4CaO5 cluster close to a redox-active tyrosine residue (TyrZ). The enzyme cycles through five sequential oxidation states, from S0 to S4, in the water splitting process. O2 evolution occurs in the final S3TyrZ dot to S0TyrZ transition. Chloride is also involved in this mechanism. By using PSII from Thermosynechococcus elongatus in which both Ca and Cl have been substituted for Sr and Br, in order to slow down the S3TyrZdot to S0TyrZ + O2 transition, with a t1/2 ~ 5 ms at room temperature, it is shown that the kinetics of the recovery of a functional S0 has a tfrac12 also close to 5 ms. It is suggested that, similarly, the reformation of a functional S0 state follows the S3TyrZdot to S0TyrZ + O2 transition transition in CaCl-PSII and that the insertion of a new substrate molecule of water (O5) and protons does not require further delay.
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光系统 II 释放 O2 后 S0 状态转变为 S1 状态的动力学过程
光系统 II(PSII)中的水氧化活性位点由靠近氧化还原活性酪氨酸残基(TyrZ)的 Mn4CaO5 簇组成。该酶在水分裂过程中循环经历从 S0 到 S4 的五个连续氧化态。在最后的 S3TyrZ 点到 S0TyrZ 的转变过程中会发生 O2 演化。氯化物也参与了这一机制。通过使用拉长热球藻的 PSII(其中 Ca 和 Cl 已被 Sr 和 Br 取代)来减缓 S3TyrZ 点到 S0TyrZ + O2 的转变(室温下 t1/2 约为 5 毫秒),结果表明功能 S0 的恢复动力学 tfrac12 也接近 5 毫秒。这表明,类似地,在 CaCl-PSII 中,功能性 S0 状态的重构遵循 S3TyrZdot 到 S0TyrZ + O2 的转变,而新的水 (O5) 和质子底物分子的插入不需要进一步的延迟。
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