Time-resolved investigation of nanometric cell membrane patches with a mid-infrared laser microscope

Frontiers in photonics Pub Date : 2023-04-28 DOI:10.3389/fphot.2023.1175033

A. Intze, M. Temperini, L. Baldassarre, V. Giliberti, M. Ortolani, R. Polito

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引用次数: 1

Abstract

The proton pump Bacteriorhodopsin (BR) undergoes repeated photocycles including reversible conformational changes upon visible light illumination. Exploiting the sensitivity of infrared (IR) spectra to the conformation, we have determined the reaction kinetic parameters of the conductive intermediate M for the wild-type protein and for its slow mutant D96N during its photocycle. Time-resolved IR micro-spectroscopy using an in-house developed confocal laser microscope operating in the mid-IR is employed to record absorption changes of 10−4 at wavelengths λ1 = 6.08 μm and λ2 = 6.35 μm, assigned to backbone and retinal structural modifications, respectively. Protein samples were embedded in dried lipid bilayers deposited on ultraflat gold supports to enhance the surface field. The signals were analyzed according to a simplified photocycle model with only two dominant states: the dark-adapted state BR* and the intermediate M. We obtained the excitation and relaxation times of the intermediate M from exponential fits to the absorption change time traces. Our results constitute a first step towards future plasmonic-assisted nanoscale time-resolved mid-IR spectrometers for the characterization of bioelectronic and light-harvesting nanodevices based on BR.

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用中红外激光显微镜对纳米细胞膜贴片的时间分辨研究

质子泵细菌视紫红质（BR）在可见光照射下经历重复的光循环，包括可逆的构象变化。利用红外光谱对构象的敏感性，我们确定了导电中间体M在其光循环过程中对野生型蛋白质及其慢突变体D96N的反应动力学参数。使用内部开发的在中红外波段工作的共焦激光显微镜，使用时间分辨红外显微光谱记录波长λ1=6.08μm和λ2=6.35μm下10−4的吸收变化，分别归属于主干和视网膜结构修饰。将蛋白质样品包埋在沉积在超平坦金载体上的干燥脂质双层中，以增强表面场。根据只有两个主导态的简化光循环模型分析信号：暗适应态BR*和中间体M。我们从指数拟合到吸收变化时间轨迹获得了中间体M的激发和弛豫时间。我们的研究结果为未来等离子体辅助纳米级时间分辨中红外光谱仪迈出了第一步，该光谱仪用于表征基于BR的生物电子和光捕获纳米器件。

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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Frontiers in photonics

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