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全反式视黄醛质子化席夫碱在溶剂中的超快激发态动力学

Ultrafast excited state dynamics of the protonated Schiff base of all-trans retinal in solvents.

作者信息

Zgrablić Goran, Voïtchovsky Kislon, Kindermann Maik, Haacke Stefan, Chergui Majed

机构信息

Laboratoire de Spectroscopie Ultrarapide, Ecole Polytechnique Fédérale de Lausanne, Institute of Chemical Sciences and Engineering, FSB-BSP, CH-1015 Lausanne-Dorigny, Switzerland.

出版信息

Biophys J. 2005 Apr;88(4):2779-88. doi: 10.1529/biophysj.104.046094.

DOI:10.1529/biophysj.104.046094
PMID:15792984
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1305373/
Abstract

We present a comparative study of the ultrafast photophysics of all-trans retinal in the protonated Schiff base form in solvents with different polarities and viscosities. Steady-state spectra of retinal in the protonated Schiff base form show large absorption-emission Stokes shifts (6500-8100 cm(-1)) for both polar and nonpolar solvents. Using a broadband fluorescence up-conversion experiment, the relaxation kinetics of fluorescence is investigated with 120 fs time resolution. The time-zero spectra already exhibit a Stokes-shift of approximately 6000 cm(-1), indicating depopulation of the Franck-Condon region in < or =100 fs. We attribute it to relaxation along skeletal stretching. A dramatic spectral narrowing is observed on a 150 fs timescale, which we assign to relaxation from the S(2) to the S(1) state. Along with the direct excitation of S(1), this relaxation populates different quasistationary states in S(1), as suggested from the existence of three distinct fluorescence decay times with different decay associated spectra. A 0.5-0.65 ps decay component is observed, which may reflect the direct repopulation of the ground state, in line with the small isomerization yield in solvents. Two longer decay components are observed and are attributed to torsional motion leading to photo-isomerization. The various decay channels show little or no dependence with respect to the viscosity or dielectric constant of the solvents. This suggests that in the protein, the bond selectivity of isomerization is mainly governed by steric effects.

摘要

我们展示了在具有不同极性和粘度的溶剂中,质子化席夫碱形式的全反式视黄醛超快光物理性质的比较研究。质子化席夫碱形式的视黄醛稳态光谱显示,对于极性和非极性溶剂,吸收 - 发射斯托克斯位移都很大(6500 - 8100 cm⁻¹)。利用宽带荧光上转换实验,以120 fs的时间分辨率研究了荧光的弛豫动力学。初始时刻光谱已经呈现出约6000 cm⁻¹的斯托克斯位移,表明在≤100 fs内弗兰克 - 康登区域的粒子数减少。我们将其归因于沿骨架拉伸的弛豫。在150 fs时间尺度上观察到显著的光谱变窄,我们将其归因于从S₂到S₁态的弛豫。与S₁的直接激发一起,这种弛豫在S₁中填充了不同的准稳态,这从具有不同衰减相关光谱的三个不同荧光衰减时间的存在可以看出。观察到一个0.5 - 0.65 ps的衰减分量,这可能反映了基态的直接再填充,这与溶剂中较小的异构化产率一致。观察到两个较长的衰减分量,并归因于导致光异构化的扭转运动。各种衰减通道对溶剂的粘度或介电常数几乎没有依赖性。这表明在蛋白质中,异构化的键选择性主要由空间效应控制。

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