University of Wisconsin Milwaukee, Milwaukee, WI, USA.
Center for Free-Electron Laser Science, Deutsches Elektronen-Synchrotron (DESY), Hamburg, Germany.
Nature. 2021 Nov;599(7886):697-701. doi: 10.1038/s41586-021-04050-9. Epub 2021 Nov 3.
The structural dynamics of a molecule are determined by the underlying potential energy landscape. Conical intersections are funnels connecting otherwise separate potential energy surfaces. Posited almost a century ago, conical intersections remain the subject of intense scientific interest. In biology, they have a pivotal role in vision, photosynthesis and DNA stability. Accurate theoretical methods for examining conical intersections are at present limited to small molecules. Experimental investigations are challenged by the required time resolution and sensitivity. Current structure-dynamical understanding of conical intersections is thus limited to simple molecules with around ten atoms, on timescales of about 100 fs or longer. Spectroscopy can achieve better time resolutions, but provides indirect structural information. Here we present few-femtosecond, atomic-resolution videos of photoactive yellow protein, a 2,000-atom protein, passing through a conical intersection. These videos, extracted from experimental data by machine learning, reveal the dynamical trajectories of de-excitation via a conical intersection, yield the key parameters of the conical intersection controlling the de-excitation process and elucidate the topography of the electronic potential energy surfaces involved.
分子的结构动力学由潜在的能量景观决定。锥型交叉是连接不同势能面的漏斗。锥型交叉在近一个世纪前被提出,至今仍是科学研究的热点。在生物学中,它们在视觉、光合作用和 DNA 稳定性方面起着关键作用。目前,用于检查锥型交叉的精确理论方法仅限于小分子。实验研究受到所需的时间分辨率和灵敏度的限制。因此,目前对锥型交叉的结构动力学的理解仅限于大约有十个原子的简单分子,在大约 100 飞秒或更长的时间尺度上。光谱学可以实现更好的时间分辨率,但提供的是间接的结构信息。本文通过机器学习从实验数据中提取了光致变色黄色蛋白的几百飞秒原子分辨率视频,这是一种 2000 个原子的蛋白质,穿过锥型交叉。这些视频揭示了通过锥型交叉进行退激发的动态轨迹,得出了控制退激发过程的锥型交叉的关键参数,并阐明了涉及的电子势能面的地形。
