Nuclear hyperpolarization in electron-transfer proteins: Revealing unexpected light-induced 15N signals with field-cycling magic-angle spinning NMR

Patrick Kurle-Tucholski , Luca Gerhards , Yonghong Ding , Yunmi Kim , Irina S. Anisimova , A. Alia , Ilia A. Solov'yov , Jörg Matysik
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Abstract

The solid-state photo-CIDNP (photo-chemically induced dynamic nuclear polarization) effect allows for nuclear hyperpolarization, i.e., non-Boltzmann nuclear spin population. The effect relies on the light-induced formation of a spin-correlated radical pair (SCRP) and has been observed in various photosynthetic reaction center (RC) proteins and flavin-containing light, oxygen, voltage (LOV) proteins. Both systems exhibit strongly enhanced NMR signals originating from the electron transfer partners. Here, we present experimental data on the magnetic field dependence of the 15N solid-state photo-CIDNP effect in both phototropin LOV1 C57S from Chlamydomonas reinhardtii and the bacterial photosynthetic RC from Rhodobacter sphaeroides. Using a pneumatic field-cycling system, samples containing a frozen solution of the proteins are explored between 0.25 T and 9.4 T. Both systems yield hyperpolarized 15N NMR signals across the entire magnetic field range originating from the electron transfer moieties. Also, in both systems, hyperpolarized signals from unexpected positions are detected between 1.0 T and 2.0 T: position N-1 of the flavin in the LOV1 protein and the τ-N of the axial magnesium-coordinating histidine of the donor. A first attempt to explain the occurrence of these unexpected signals based on quantum chemical calculations is presented.

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电子传递蛋白中的核超极化:用场循环魔角旋转 NMR 揭示意想不到的光诱导 15N 信号
固态光-CIDNP(光化学诱导动态核极化)效应允许核超极化,即非玻尔兹曼核自旋群。这种效应依赖于光诱导形成的自旋相关自由基对(SCRP),并已在各种光合反应中心(RC)蛋白质和含黄素的光、氧、电压(LOV)蛋白质中观察到。这两个系统都显示出源自电子转移伴侣的强烈增强 NMR 信号。在这里,我们展示了有关 15N 固态光-CIDNP 效应在莱茵衣藻的趋光蛋白 LOV1 C57S 和孢氏红杆菌的细菌光合 RC 中的磁场依赖性的实验数据。利用气动磁场循环系统,在 0.25 T 和 9.4 T 之间对含有冷冻蛋白质溶液的样品进行了探究。在整个磁场范围内,两个系统都产生了源于电子传递分子的超极化 15N NMR 信号。此外,在这两个系统中,在 1.0 T 和 2.0 T 之间都检测到了来自意外位置的超极化信号:LOV1 蛋白中黄素的 N-1 位置和供体的轴向镁配位组氨酸的 τ-N 位置。本文首次尝试根据量子化学计算来解释这些意外信号的出现。
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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