Dipartimento di Fisica, Università di Roma, La Sapienza, I-00185 Roma, Italy.
Istituto di Fotonica e Nanotecnologie (IFN-CNR), Dipartimento di Fisica, Politecnico di Milano, Piazza L. da Vinci 32, 20133 Milano, Italy.
Nat Chem. 2016 Dec;8(12):1137-1143. doi: 10.1038/nchem.2569. Epub 2016 Sep 5.
Determining the initial pathway for ultrafast energy redistribution within biomolecules is a challenge, and haem proteins, for which energy can be deposited locally in the haem moiety using short light pulses, are suitable model systems to address this issue. However, data acquired using existing experimental techniques that fail to combine sufficient structural sensitivity with adequate time resolution have resulted in alternative hypotheses concerning the interplay between energy flow among highly excited vibrational levels and potential concomitant electronic processes. By developing a femtosecond-stimulated Raman set-up, endowed with the necessary tunability to take advantage of different resonance conditions, here we visualize the temporal evolution of energy redistribution over different vibrational modes in myoglobin. We establish that the vibrational energy initially stored in the highly excited Franck-Condon manifold is transferred with different timescales into low- and high-frequency modes, prior to slow dissipation through the protein. These findings demonstrate that a newly proposed mechanism involving the population dynamics of specific vibrational modes settles the controversy on the existence of transient electronic intermediates.
确定生物分子内部超快能量再分配的初始途径是一项挑战,而血红素蛋白就是一个合适的模型系统,因为可以使用短光脉冲将能量局部沉积在血红素部分。然而,使用现有的实验技术获取的数据未能将足够的结构灵敏度与足够的时间分辨率结合起来,这些数据导致了关于高度激发振动能级之间能量流动与潜在伴随电子过程之间相互作用的替代假说。通过开发具有充分可调性以利用不同共振条件的飞秒受激拉曼装置,我们在这里可视化了肌红蛋白中不同振动模式上能量再分配的时间演化。我们确定,最初储存在高度激发的 Franck-Condon 简并态中的振动能量以不同的时间尺度转移到低频和高频模式中,然后通过蛋白质缓慢耗散。这些发现表明,一种新提出的机制涉及特定振动模式的种群动力学,解决了关于瞬态电子中间产物存在的争议。
