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人血清白蛋白的闪光光解：吲哚三重态吸收光谱的表征及室温下的衰减

Flash photolysis of human serum albumin: characterization of the indole triplet absorption spectrum and decay at ambient temperature.

作者信息

Hicks B, White M, Ghiron C A, Kuntz R R, Volkert W A

出版信息

Proc Natl Acad Sci U S A. 1978 Mar;75(3):1172-5. doi: 10.1073/pnas.75.3.1172.

DOI:10.1073/pnas.75.3.1172

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC411431/

Abstract

The method of flash photolysis was used to identify the transient absorption spectrum and to characterize the decay kinetics of the indole triplet of human serum albumin. This protein was studied because it contains a single indole side chain which is deeply buried in an expandable oily region and because the phosphorescence of the homologous indole in bovine serum albumin could not be detected at ambient temperatures. The transient was identified on the following basis: (i) its triplet-triplet absorption spectrum was similar to those previously reported for indole and tryptophan; (ii) it was quenched by small quantities of oxygen; and (iii) it was photobleached by 370- to 700-nm light. In a nitrogen-saturated solution at room temperature, the indole triplet decays exponentially for more than a factor of 10 with a lifetime of 0.5 msec. These observations suggest that, because of its exponential decay and relatively long lifetime, the triplet will be more valuable than the indole singlet as an intrinsic reporter group for the study of the structure and dynamics of proteins in solution.

摘要

采用闪光光解方法来识别瞬态吸收光谱，并表征人血清白蛋白吲哚三重态的衰减动力学。对这种蛋白质进行研究的原因在于：它含有一个深埋于可扩展油性区域的单一吲哚侧链，并且在室温下无法检测到牛血清白蛋白中同源吲哚的磷光。基于以下几点鉴定出该瞬态：（i）其三重态 - 三重态吸收光谱与先前报道的吲哚和色氨酸的光谱相似；（ii）它被少量氧气淬灭；（iii）它被370至700纳米的光漂白。在室温下的氮气饱和溶液中，吲哚三重态以0.5毫秒的寿命呈指数衰减超过10倍。这些观察结果表明，由于其指数衰减和相对较长的寿命，三重态作为研究溶液中蛋白质结构和动力学的内在报告基团将比吲哚单重态更有价值。