一种特殊细菌光敏色素的飞秒至微秒光动力学

Femto- to Microsecond Photodynamics of an Unusual Bacteriophytochrome.

作者信息

Mathes Tilo, Ravensbergen Janneke, Kloz Miroslav, Gleichmann Tobias, Gallagher Kevin D, Woitowich Nicole C, St Peter Rachael, Kovaleva Svetlana E, Stojković Emina A, Kennis John T M

机构信息

†Biophysics Group, Department of Physics and Astronomy, Faculty of Sciences, Vrije Universiteit, De Boelelaan 1081, 1081 HV, Amsterdam, The Netherlands.

‡Department of Biology, Northeastern Illinois University, 5500 North St. Louis Avenue, Chicago, Illinois 60625, United States.

出版信息

J Phys Chem Lett. 2015 Jan 15;6(2):239-43. doi: 10.1021/jz502408n. Epub 2014 Dec 30.

DOI:10.1021/jz502408n

PMID:26263456

Abstract

A bacteriophytochrome from Stigmatella aurantiaca is an unusual member of the bacteriophytochrome family that is devoid of hydrogen bonding to the carbonyl group of ring D of the biliverdin (BV) chromophore. The photodynamics of BV in SaBphP1 wild type and the single mutant T289H reintroducing hydrogen bonding to ring D show that the strength of this particular weak interaction determines excited-state lifetime, Lumi-R quantum yield, and spectral heterogeneity. In particular, excited-state decay is faster in the absence of hydrogen-bonding to ring D, with excited-state half-lives of 30 and 80 ps for wild type and the T289H mutant, respectively. Concomitantly, the Lumi-R quantum yield is two times higher in wild type as compared with the T289H mutant. Furthermore, the spectral heterogeneity in the wild type is significantly higher than that in the T289H mutant. By extending the observable time domain to 25 μs, we observe a new deactivation pathway from the Lumi-R intermediate in the 100 ns time domain that corresponds to a backflip of ring D to the original Pr 15Za isomeric state.

摘要

来自橙色粘球菌的一种细菌光敏色素是细菌光敏色素家族中的一个特殊成员，它与胆绿素（BV）发色团的D环羰基没有氢键作用。橙色粘球菌细菌光敏色素1（SaBphP1）野生型及重新引入与D环氢键作用的单突变体T289H中BV的光动力学表明，这种特殊弱相互作用的强度决定了激发态寿命、Lumi-R量子产率和光谱异质性。特别是，在不存在与D环氢键作用的情况下，激发态衰变更快，野生型和T289H突变体的激发态半衰期分别为30皮秒和80皮秒。同时，野生型的Lumi-R量子产率比T289H突变体高两倍。此外，野生型的光谱异质性明显高于T289H突变体。通过将可观测时域扩展到25微秒，我们在100纳秒时域中观察到一种从Lumi-R中间体开始的新失活途径，该途径对应于D环向后翻转至原始Pr 15Za异构体状态。

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一种特殊细菌光敏色素的飞秒至微秒光动力学

Femto- to Microsecond Photodynamics of an Unusual Bacteriophytochrome.

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