Rhoades Elizabeth, Gussakovsky Eugene, Haran Gilad
Department of Chemical Physics, Weizmann Institute of Science, Rehovot 76100, Israel.
Proc Natl Acad Sci U S A. 2003 Mar 18;100(6):3197-202. doi: 10.1073/pnas.2628068100. Epub 2003 Feb 28.
Recent theoretical work suggests that protein folding involves an ensemble of pathways on a rugged energy landscape. We provide direct evidence for heterogeneous folding pathways from single-molecule studies, facilitated by a recently developed immobilization technique. Individual fluorophore-labeled molecules of the protein adenylate kinase were trapped within surface-tethered lipid vesicles, thereby allowing spatial restriction without inducing any spurious interactions with the environment, which often occur when using direct surface-linking techniques. The conformational fluctuations of these protein molecules, prepared at the thermodynamic midtransition point, were studied by using fluorescence resonance energy transfer between two specifically attached labels. Folding and unfolding transitions appeared in experimental time traces as correlated steps in donor and acceptor fluorescence intensity. The size of the steps, in fluorescence resonance energy transfer efficiency units, shows a very broad distribution. This distribution peaks at a relatively low value, indicating a preference for small-step motion on the energy landscape. The time scale of the transitions is also distributed, and although many transitions are too fast to be time-resolved here, the slowest ones may take >1 sec to complete. These extremely slow changes during the folding of single molecules highlight the possible importance of correlated, non-Markovian conformational dynamics.
近期的理论研究表明,蛋白质折叠在崎岖的能量景观上涉及一系列途径。我们通过单分子研究为异质折叠途径提供了直接证据,这得益于最近开发的固定技术。蛋白质腺苷酸激酶的单个荧光团标记分子被困在表面 tethered 脂质囊泡内,从而实现空间限制,而不会诱导与环境的任何虚假相互作用,这种相互作用在使用直接表面连接技术时经常发生。通过使用两个特异性连接的标记之间的荧光共振能量转移,研究了在热力学中间转变点制备的这些蛋白质分子的构象波动。折叠和去折叠转变在实验时间轨迹中表现为供体和受体荧光强度的相关步骤。以荧光共振能量转移效率单位表示的步骤大小显示出非常广泛的分布。该分布在相对较低的值处达到峰值,表明在能量景观上倾向于小步运动。转变的时间尺度也呈分布状态,尽管许多转变太快以至于在此无法进行时间分辨,但最慢的转变可能需要超过 1 秒才能完成。单分子折叠过程中这些极其缓慢的变化突出了相关的、非马尔可夫构象动力学的可能重要性。