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Temperature-cycle microscopy reveals single-molecule conformational heterogeneity


Yuan, Haifeng; Gaiduk, Alexander; Siekierzycka, Joanna R; Fujiyoshi, Satoru; Matsushita, Michio; Nettels, Daniel; Schuler, Benjamin; Seidel, Claus A M; Orrit, Michel (2015). Temperature-cycle microscopy reveals single-molecule conformational heterogeneity. Physical Chemistry Chemical Physics (PCCP), 17(9):6532-6544.

Abstract

Our previous temperature-cycle study reported FRET transitions between different states on FRET-labeled polyprolines [Yuan et al., PCCP, 2011, 13, 1762]. The conformational origin of such transitions, however, was left open. In this work, we apply temperature-cycle microscopy of single FRET-labeled polyproline and dsDNA molecules and compare their responses to resolve the conformational origin of different FRET states. We observe different steady-state FRET distributions and different temperature-cycle responses in the two samples. Our temperature-cycle results on single molecules resemble the results in steady-state measurements but reveal a dark state which could not be observed otherwise. By comparing the timescales and probabilities of different FRET states in temperature-cycle traces, we assign the conformational heterogeneity reflected by different FRET states to linker dynamics, dye-chain and dye-dye interactions. The dark state and low-FRET state are likely due to dye-dye interactions at short separations.

Abstract

Our previous temperature-cycle study reported FRET transitions between different states on FRET-labeled polyprolines [Yuan et al., PCCP, 2011, 13, 1762]. The conformational origin of such transitions, however, was left open. In this work, we apply temperature-cycle microscopy of single FRET-labeled polyproline and dsDNA molecules and compare their responses to resolve the conformational origin of different FRET states. We observe different steady-state FRET distributions and different temperature-cycle responses in the two samples. Our temperature-cycle results on single molecules resemble the results in steady-state measurements but reveal a dark state which could not be observed otherwise. By comparing the timescales and probabilities of different FRET states in temperature-cycle traces, we assign the conformational heterogeneity reflected by different FRET states to linker dynamics, dye-chain and dye-dye interactions. The dark state and low-FRET state are likely due to dye-dye interactions at short separations.

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Additional indexing

Item Type:Journal Article, refereed, original work
Communities & Collections:04 Faculty of Medicine > Department of Biochemistry
07 Faculty of Science > Department of Biochemistry
Dewey Decimal Classification:570 Life sciences; biology
610 Medicine & health
Language:English
Date:7 March 2015
Deposited On:24 Sep 2015 12:44
Last Modified:08 Dec 2017 14:07
Publisher:RSC Publishing
ISSN:1463-9076
Free access at:Publisher DOI. An embargo period may apply.
Publisher DOI:https://doi.org/10.1039/c4cp05486e
PubMed ID:25659944

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