Structural Biological Study Based on Spectroscopic Analysis of Cone Pigment

Kota Katayama
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Abstract

Vitamin A is adequately distributed within the body to maintain the biological function of retinoids in the periph-eral tissues and the production of the visual chromophore, 11- cis -retinal, in the eye. One of the mysteries in our vision is that humans recognize color by use of a single chromophore molecule (11- cis -retinal), meaning that the chromophore is identical even between blue-absorbing and red-absorbing sensors. Humans have two different types of retinal contain-ing light-sensitive proteins expressed in the retina, rhodopsin (Rh) achieving the twilight vision and three cone pigments, which mediate color vision. Each different chromophore-protein interaction allows preferential absorption of a selected range of wavelengths. While the structural basis for photoreaction and signal transduction of Rh has been well understood by the determination of its atomic-level structure, structural studies of cone pigments lag far behind those of Rh, mainly because of difficulty in sample preparation and lack of suitable methods in structural analysis. We thus attempted to express monkey cone pigments in HEK293 cell lines for structural analysis using light-induced difference Fourier-transform infrared (FTIR) spectroscopy. The first structural information successfully elicited from the highly accurate spectra for each cone pigment showed that the retinal chromophore is structurally similar between Rh and cone pigments, but the hydrogen-bonding network around the retinal chromophore is entirely different between them. In addition, some spectral differences are observed between cone pigments, including protein-bound water molecules. These differences could be interpreted to play a role in spectral tuning.
基于视锥色素光谱分析的结构生物学研究
维生素A在体内充分分布,以维持外周组织中类维甲酸的生物功能和眼睛中视觉发色团11-顺式视网膜的产生。我们视觉中的一个谜团是人类通过使用单一的发色团分子(11-顺式-视网膜)来识别颜色,这意味着即使在蓝色和红色吸收传感器之间,发色团也是相同的。人类有两种不同类型的视网膜,其中包含在视网膜中表达的光敏蛋白,一种是实现黄昏视觉的视紫红质(Rh),另一种是调节色觉的三种视锥色素。每种不同的发色团-蛋白质相互作用允许优先吸收选定的波长范围。虽然通过测定其原子水平结构已经很好地了解了Rh光反应和信号转导的结构基础,但锥色素的结构研究远远落后于Rh,主要原因是样品制备困难和缺乏合适的结构分析方法。因此,我们尝试在HEK293细胞系中表达猴锥色素,并利用光诱导差分傅立叶变换红外(FTIR)光谱对其进行结构分析。从每个视锥色素的高精度光谱中成功获得的第一个结构信息表明,Rh和视锥色素之间的视网膜发色团结构相似,但它们之间视网膜发色团周围的氢键网络完全不同。此外,在锥体色素(包括蛋白质结合水分子)之间观察到一些光谱差异。这些差异可以解释为在光谱调谐中起作用。
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