变构双脚踏车式异构化伴随氢键断裂是细菌视紫红质质子泵浦的初始事件。
Aborted double bicycle-pedal isomerization with hydrogen bond breaking is the primary event of bacteriorhodopsin proton pumping.
机构信息
Dipartimento di Chimica G. Ciamician, Università di Bologna, via Selmi 2, Bologna, I-40126 Italy.
出版信息
Proc Natl Acad Sci U S A. 2010 Nov 23;107(47):20172-7. doi: 10.1073/pnas.1007000107. Epub 2010 Nov 3.
Abstract
Quantum mechanics/molecular mechanics calculations based on ab initio multiconfigurational second order perturbation theory are employed to construct a computer model of Bacteriorhodopsin that reproduces the observed static and transient electronic spectra, the dipole moment changes, and the energy stored in the photocycle intermediate K. The computed reaction coordinate indicates that the isomerization of the retinal chromophore occurs via a complex motion accounting for three distinct regimes: (i) production of the excited state intermediate I, (ii) evolution of I toward a conical intersection between the excited state and the ground state, and (iii) formation of K. We show that, during stage ii, a space-saving mechanism dominated by an asynchronous double bicycle-pedal deformation of the C10═C11─C12═C13─C14═N moiety of the chromophore dominates the isomerization. On this same stage a N─H/water hydrogen bond is weakened and initiates a breaking process that is completed during stage iii.
摘要
基于从头算多组态二级微扰理论的量子力学/分子力学计算被用来构建细菌视紫红质的计算机模型,该模型再现了观察到的静态和瞬态电子光谱、偶极矩变化以及光循环中间体 K 中储存的能量。计算得到的反应坐标表明,视黄醛发色团的异构化通过一个复杂的运动发生,该运动包括三个不同的状态:(i)激发态中间体 I 的产生,(ii)I 向激发态和基态之间的锥形交叉的演化,以及(iii)K 的形成。我们表明,在阶段 ii 中,以发色团的 C10═C11─C12═C13─C14═N 部分的异步双脚踏板变形为主导的节省空间的机制主导着异构化。在同一阶段,N─H/水氢键减弱并启动一个断裂过程,该过程在阶段 iii 中完成。
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2
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Nature. 2010 Sep 23;467(7314):440-3. doi: 10.1038/nature09346.
3
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