重新调整电化学叶片的电位。

IF 3.4 3区 化学 Q2 Chemistry
Marta M. Dolińska, Adam J. Kirwan and Clare F. Megarity
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引用次数: 0

摘要

电化学叶通过利用两项发现,实现了多酶级联的电化和控制:(i)能够使光合作用酶铁氧还蛋白 NADP+ 还原酶(FNR)通电,当它被包裹在高孔隙金属氧化物电极中时,驱动它催化 NADP+/NADPH 的相互转化;(ii)有证据表明,电极孔隙中可以共同包裹其他酶,通过一种依赖 NADP(H)的酶,通过 NADP(H)的循环,与 FNR 通电连接,驱动扩展级联。通过将一个关键的活性位点酪氨酸转变为丝氨酸,FNR 对 NADP(H)的专一性就被非磷酸化的 NAD(H)所取代。在这里,我们对这种变体 FNR 进行了电化学研究,结果表明,除了预期的辅因子偏好反转外,活性位点的这种变化还改变了 FNR 对黄素还原电位的调节,使其还原性降低。利用监测变体在 NADP(H)作用下的活性与电位的函数关系的能力揭示了一种受困的中间状态,只有施加负过电位才能缓解这种状态,从而使催化作用得以继续进行。此外,还发现了 NADP+(与 NAD(H)紧密结合)对 NAD(H)周转的抑制作用,有趣的是,这种抑制作用会随着施加的电位而变化。这些发现对于未来利用电化学叶片至关重要。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Retuning the potential of the electrochemical leaf†

Retuning the potential of the electrochemical leaf†

Retuning the potential of the electrochemical leaf†

The electrochemical leaf enables the electrification and control of multi-enzyme cascades by exploiting two discoveries: (i) the ability to electrify the photosynthetic enzyme ferredoxin NADP+ reductase (FNR), driving it to catalyse the interconversion of NADP+/NADPH whilst it is entrapped in a highly porous, metal oxide electrode, and (ii) the evidence that additional enzymes can be co-entrapped in the electrode pores where, through one NADP(H)-dependent enzyme, extended cascades can be driven by electrical connection to FNR, via NADP(H) recycling. By changing a critical active-site tyrosine to serine, FNR’s exclusivity for NADP(H) is swapped for unphosphorylated NAD(H). Here we present an electrochemical study of this variant FNR, and show that in addition to the intended inversion of cofactor preference, this change to the active site has altered FNR’s tuning of the flavin reduction potential, making it less reductive. Exploiting the ability to monitor the variant’s activity with NADP(H) as a function of potential has revealed a trapped intermediate state, relieved only by applying a negative overpotential, which allows catalysis to proceed. Inhibition by NADP+ (very tightly bound) with respect to NAD(H) turnover was also revealed and interestingly, this inhibition changes depending on the applied potential. These findings are of critical importance for future exploitation of the electrochemical leaf.

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来源期刊
Faraday Discussions
Faraday Discussions CHEMISTRY, PHYSICAL-
CiteScore
4.90
自引率
0.00%
发文量
259
审稿时长
2.8 months
期刊介绍: Discussion summary and research papers from discussion meetings that focus on rapidly developing areas of physical chemistry and its interfaces
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