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调频原子力显微镜揭示了与每个展开的I27肌联蛋白结构域相关的单个中间体。

Frequency modulation atomic force microscopy reveals individual intermediates associated with each unfolded I27 titin domain.

作者信息

Higgins Michael J, Sader John E, Jarvis Suzanne P

机构信息

Centre for Research on Adaptive Nanodevices and Nanostructures (CRANN), University of Dublin, Trinity College, Dublin 2, Ireland.

出版信息

Biophys J. 2006 Jan 15;90(2):640-7. doi: 10.1529/biophysj.105.066571. Epub 2005 Oct 28.

DOI:10.1529/biophysj.105.066571
PMID:16258037
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1367068/
Abstract

In this study, we apply a dynamic atomic force microscopy (AFM) technique, frequency modulation (FM) detection, to the mechanical unfolding of single titin I27 domains and make comparisons with measurements made using the AFM contact or static mode method. Static mode measurements revealed the well-known force transition occurring at 100-120 pN in the first unfolding peak, which was less clear, or more often absent, in the subsequent unfolding peaks. In contrast, some FM-AFM curves clearly resolved a force transition associated with each of the unfolding peaks irrespective of the number of observed unfolded domains. As expected for FM-AFM, the frequency shift response of the main unfolding peaks and their intermediates could only be detected when the oscillation amplitudes used were smaller than the interaction lengths being measured. It was also shown that the forces measured for the dynamical interaction of the FM-AFM technique were significantly lower than those measured using the static mode. This study highlights the potential for using dynamic AFM for investigating biological interactions, including protein unfolding and the detection of novel unfolding intermediates.

摘要

在本研究中,我们将动态原子力显微镜(AFM)技术,即调频(FM)检测,应用于单个肌联蛋白I27结构域的机械展开,并与使用AFM接触或静态模式方法所做的测量进行比较。静态模式测量揭示了在第一个展开峰中于100 - 120 pN出现的众所周知的力转变,而在随后的展开峰中这种转变不太明显,或者更常见的是不存在。相比之下,一些FM - AFM曲线清晰地分辨出与每个展开峰相关的力转变,而与观察到的展开结构域数量无关。正如FM - AFM所预期的那样,只有当所使用的振荡幅度小于正在测量的相互作用长度时,才能检测到主要展开峰及其中间体的频率偏移响应。研究还表明,FM - AFM技术动态相互作用所测量的力显著低于使用静态模式测量的力。这项研究突出了使用动态AFM研究生物相互作用的潜力,包括蛋白质展开以及新型展开中间体的检测。

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