色觉的光化学决定因素:揭示视蛋白如何调节其生色团的吸收波长。
The photochemical determinants of color vision: revealing how opsins tune their chromophore's absorption wavelength.
机构信息
Department of Chemistry, Massachusetts Institute of Technology, Cambridge, MA, USA.
出版信息
Bioessays. 2014 Jan;36(1):65-74. doi: 10.1002/bies.201300094. Epub 2013 Oct 24.
Abstract
The evolution of a variety of important chromophore-dependent biological processes, including microbial light sensing and mammalian color vision, relies on protein modifications that alter the spectral characteristics of a bound chromophore. Three different color opsins share the same chromophore, but have three distinct absorptions that together cover the entire visible spectrum, giving rise to trichromatic vision. The influence of opsins on the absorbance of the chromophore has been studied through methods such as model compounds, opsin mutagenesis, and computational modeling. The recent development of rhodopsin mimic that uses small soluble proteins to recapitulate the binding and wavelength tuning of the native opsins provides a new platform for studying protein-regulated spectral tuning. The ability to achieve far-red shifted absorption in the rhodopsin mimic system was attributed to a combination of the lack of a counteranion proximal to the iminium, and a uniformly neutral electrostatic environment surrounding the chromophore.
摘要
各种重要的依赖发色团的生物过程的进化,包括微生物光感应和哺乳动物颜色视觉,依赖于改变结合发色团光谱特征的蛋白质修饰。三种不同的光感受器共享相同的发色团,但具有三个不同的吸收峰,共同覆盖整个可见光谱,产生三色视觉。通过模型化合物、光感受器突变和计算建模等方法研究了光感受器对发色团吸收的影响。最近开发的视蛋白模拟物使用小的可溶性蛋白质来重现天然光感受器的结合和波长调谐,为研究蛋白质调节的光谱调谐提供了一个新的平台。视蛋白模拟物系统能够实现远红移吸收归因于缺乏紧邻亚氨基的抗衡离子,以及围绕发色团的均匀中性静电环境的共同作用。
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