Molecular Science of Rhodopsins

H. Kandori
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引用次数: 2

Abstract

Rhodopsins contain a retinal molecule, and convert light into chemical energy or signal. The chromophore of visual or microbial rhodopsins is a retinal Schiff base of the 11-cis or all-trans form, respectively, where specific chromophore-protein interaction determines their colors. Upon light absorption, ultrafast photoisomerization initiates protein structural changes, leading to each functional expression. By use of spectroscopic methods, we have been studying how rhodopsins respond to light. Ultrafast spectroscopy of visual rhodopsin revealed that cis-trans isomerization is the primary event in our vision, which is optimized in protein environment. Fourier-transform infrared (FTIR) spectroscopy of visual and microbial rhodopsins provides various important vibrational bands related to structural changes of these proteins. Detection of protein-bound water molecules is one of the research highlights, and the comprehensive FTIR study has shown that a strongly hydrogen-bonded water molecule is the functional determinant of light-driven proton pump proteins. Here I review our spectroscopic challenge for > 25 years, particularly focusing our recent findings.
红紫红质的分子科学
视紫红质含有一种视网膜分子,能将光转化为化学能或信号。视紫红质或微生物紫红质的发色团分别是11-顺式或全反式的视网膜希夫碱,其中特定的发色团-蛋白质相互作用决定了它们的颜色。光吸收后,超快光异构化引发蛋白质结构变化,导致各种功能表达。利用光谱学方法,我们一直在研究视紫红质对光的反应。视觉紫红质的超快光谱分析表明,顺反异构化是我们视觉的主要过程,在蛋白质环境下进行优化。可见光和微生物紫红质的傅里叶变换红外光谱(FTIR)提供了与这些蛋白质结构变化相关的各种重要振动带。蛋白质结合水分子的检测是研究的重点之一,全面的FTIR研究表明,强氢键水分子是光驱动质子泵蛋白的功能决定因素。在这里,我回顾了我们25年来的光谱挑战,特别关注我们最近的发现。
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