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海鳗视紫红质中多个氨基酸残基之间远程协同颜色调谐的分子机制。

Molecular mechanism of long-range synergetic color tuning between multiple amino acid residues in conger rhodopsin.

作者信息

Watanabe Hiroshi C, Mori Yoshiharu, Tada Takashi, Yokoyama Shozo, Yamato Takahisa

机构信息

Graduate School of Science, Nagoya University, Furo-cho, Chikusa-ku, Nagoya, 464-8602, Japan.

出版信息

Biophysics (Oxf). 2010 Jan 1;6:67-68. doi: 10.2142/biophysics.6.67.

DOI:10.2142/biophysics.6.67
PMID:21297892
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3032607/
Abstract

The synergetic effects of multiple rhodopsin mutations on color tuning need to be completely elucidated. Systematic genetic studies and spectroscopy have demonstrated an interesting example of synergetic color tuning between two amino acid residues in conger rhodopsin's ancestral pigment (p501): -a double mutation at one nearby and one distant residue led to a significant λ(max) blue shift of 13 nm, whereas neither of the single mutations at these two sites led to meaningful shifts.To analyze the molecular mechanisms of this synergetic color tuning, we performed homology modeling, molecular simulations, and electronic state calculations. For the double mutant, N195A/A292S, in silico mutation analysis demonstrated conspicuous structural changes in the retinal chromophore, whereas that of the single mutant, A292S, was almost unchanged. Using statistical ensembles of QM/MM optimized structures, the excitation energy of retinal chromophore was evaluated for the three visual pigments. As a result, the λ(max) shift of double mutant (DM) from p501 was -8 nm, while that of single mutant (SM) from p501 was +1 nm. Molecular dynamics simulation for DM demonstrated frequent isomerization between 6-s-cis and 6-s-trans conformers. Unexpectedly, however, the two conformers exhibited almost identical excitation energy, whereas principal component analysis (PCA) identified the retinal-counterion cooperative change of BLA (bond length alternation) and retinal-counterion interaction lead to the shift.

摘要

多种视紫红质突变对颜色调谐的协同效应需要得到全面阐明。系统的遗传学研究和光谱学研究展示了一个关于康吉鳗视紫红质原始色素(p501)中两个氨基酸残基之间协同颜色调谐的有趣例子:在一个相邻残基和一个远距离残基处的双突变导致最大吸收波长(λ(max))显著蓝移13纳米,而这两个位点的单突变均未导致有意义的波长移动。为了分析这种协同颜色调谐的分子机制,我们进行了同源建模、分子模拟和电子态计算。对于双突变体N195A/A292S,计算机模拟突变分析表明视黄醛发色团有明显的结构变化,而单突变体A292S的结构几乎没有变化。使用量子力学/分子力学(QM/MM)优化结构的统计系综,对三种视觉色素的视黄醛发色团的激发能进行了评估。结果,双突变体(DM)相对于p501的λ(max)移动为 -8纳米,而单突变体(SM)相对于p501的λ(max)移动为 +1纳米。对双突变体的分子动力学模拟表明6-s-顺式和6-s-反式构象之间频繁异构化。然而,出乎意料的是,这两种构象表现出几乎相同的激发能,而主成分分析(PCA)表明BLA(键长交替)的视黄醛-抗衡离子协同变化和视黄醛-抗衡离子相互作用导致了这种移动。

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