Reliability and accuracy of single-molecule FRET studies for characterization of structural dynamics and distances in proteins

Agam, Ganesh; Gebhardt, Christian; Popara, Milana; Maechtel, Rebecca; Folz, Julian; Ambrose, Ben; Chamachi, Neharika; Chung, Sang Yoon; Craggs, Timothy D.; Boer, Marijn de; Grohmann, Dina; Ha, Taekjip; Hartmann, Andreas; Hendrix, Jelle; Hirschfeld, Verena; Huebner, Christian; Hugel, Thorsten; Kammerer, Dominik; Kang, Hyun Seo; Kapanidis, Achillefs N.; Krainer, Georg; Kramm, Kevin; Lemke, Edward A.; Lerner, Eitan; Margeat, Emmanuel; Martens, Kirsten; Michaelis, Jens; Mitra, Jaba; Munoz, Gustavo G. Moya; Quast, Robert B.; Robb, Nicole C.; Sattler, Michael; Schlierf, Michael; Schneider, Jonathan; Schroeder, Tim; Sefer, Anna; Tan, Piau Siong; Thurn, Johann; Tinnefeld, Philip; Noort, John van; Weiss, Shimon; Wendler, Nicolas; Barth, Anders; Seidel, Claus A. M.; Lamb, Don C.; Cordes, Thorben

doi:10.1101/2022.08.03.502619

Cited by 24 publications

(47 citation statements)

References 88 publications

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“…This allows observation of slower molecular dynamics and measurement of slower diffusion properties of larger particles. In general, "larger confocal volumes, in combination with high irradiances, yield the highest number of photons per burst", according to [5]. Luminosa offers the ability to increase the observation volume from three to six times larger than diffraction limited, depending on the excitation wavelength.…”

Section: Smfret For Dynamic Structural Biologymentioning

confidence: 99%

Time‐resolved microscopy made easy

Loidolt‐Krüger

2023

PhotonicsViews

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Quantitative single molecule and time‐resolved fluorescence techniques offer new insights into many samples in life and materials sciences. So far, their adoption has been slow because expert knowledge was required for correct data acquisition and analysis. Now, PicoQuant have developed a new confocal microscope called Luminosa. It combines state‐of‐the‐art hardware with cutting‐edge software to deliver high‐quality data while simplifying daily operation. The software includes context‐based workflows for each technique. This article shows how it streamlines single‐molecule Förster resonance energy transfer (smFRET) experiments.

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Section: Smfret For Dynamic Structural Biologymentioning

confidence: 99%

Time‐resolved microscopy made easy

Loidolt‐Krüger

2023

PhotonicsViews

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“…Dynamic structural changes of nucleic acids and proteins are central to their functionalities 2 . smFRET is frequently used to gain structural and dynamic insights into conformational changes of nucleic acids and proteins, and to decipher their folding and assembly mechanisms 3,5,8 . In particular changes of solution conditions are an important tool to tune kinetics of structural transitions and to drive molecules into desired conformations.…”

Section: Probing Conformational Changes Of Biomolecules By Multiwell ...mentioning

confidence: 99%

“…Single-molecule Förster resonance energy transfer (smFRET) has become a widely used technique to monitor biomolecular conformations and dynamics on the nanometer scale 1,2 . Advanced data analysis approaches to characterize dynamics from nanoseconds to minutes and hours, together with standardizations across many laboratories and open science initiatives, have pushed smFRET to a routinely accessible technique in biophysical and biochemical research [3][4][5][6][7][8] . smFRET, due to its versatility and sensitivity, is now extensively used to address a wide range of questions in dynamic structural biology and biophysics, including the functional mechanisms of enzymes and membrane proteins [9][10][11] , protein-nucleic acid and small-moleculeprotein interactions 12,13 , and protein or nucleic-acid folding 3,14,15 , to name but a few 2,5,16 .…”

Section: Introductionmentioning

confidence: 99%

“…Such measurements also often demand a high sampling density to alleviate overparameterization effects and to increase fitting accuracy and precision. Moreover, for the determination of experimental variability, a need for technical and biological replicates arises in general, not least to ascertain reproducibility and enhance scientific rigor 4,8,23 . Hence, rapidly more than 50 conditions need to be probed in smFRET experiments.…”

Section: Introductionmentioning

confidence: 99%

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Farewell to single-well: An automated single-molecule FRET platform for high-content, multiwell plate screening of biomolecular conformations and dynamics

Hartmann

Sreenivasa

Schenkel

et al. 2023

Preprint

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Single-molecule FRET (smFRET) has become a widely used tool for probing the structure, dynamics, and functional mechanisms of biomolecular systems, and is extensively used to address questions ranging from biomolecular folding to drug discovery. Investigations by smFRET often require sampling of a large parameter space, for example, by varying one or more constituent molecular components in ten or more steps to reliably extract distances, kinetic rates, and other quantitative parameters. Confocal smFRET measurements, for example, which are amongst the widely used smFRET assays, are typically performed in a single-well format and measurements are conducted in a manual manner, making sampling of many experimental parameters laborious and time consuming. To address this challenge, we extend here the capabilities of confocal smFRET beyond single-well measurements by integrating a multiwell plate functionality into a confocal microscope to allow for continuous and automated smFRET measurements. We show that the multiwell plate assay is on par with conventional single-well smFRET measurements in terms of accuracy and precision yet enables probing tens to hundreds of conditions in a fully automized manner. We demonstrate the broad applicability of the multiwell plate assay towards DNA hairpin dynamics, protein folding, and competitive and cooperative protein–DNA interactions, revealing new insights that would be hard if not impossible to achieve with conventional single-well format measurements. The higher sampling density afforded by the multiwell plate format increases the accuracy of data analysis by at least 10-fold. We further showcase that the assay provides access to smFRET-based screening of drug–protein interactions. For the adaptation into existing instrumentations, we provide a detailed guide and open-source acquisition and analysis software. Taken together, the automated multiwell plate assay developed here opens up new possibilities to acquire high-content smFRET datasets for in-depth single-molecule analysis of biomolecular conformations, interactions, and dynamics.

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“…By removing ensemble averaging, it is possible to directly measure the underlying conformational states and molecular dynamics of biomolecules. Its ability to measure accurate distances and kinetics turned smFRET into a powerful tool for deciphering molecular interaction mechanisms and structures of biomolecules 1–3 . Typically, FRET experiments are performed using two colors and used to probe conformational distributions and distance changes.…”

Section: Introductionmentioning

confidence: 99%

Deep-Learning Assisted, Single-molecule Imaging analysis (Deep-LASI) of multi-color DNA Origami structures

Wanninger

Asadiatouei

Bohlen

et al. 2023

Preprint

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Single-molecule experiments have changed the way we investigate the physical world but data analysis is typically time-consuming and prone to human bias. Here, we present Deep-LASI (Deep-Learning Assisted Single-molecule Imaging analysis), a software package consisting of an ensemble of deep neural networks to rapidly analyze single-, two- and three-color single-molecule data, in particular from single-molecule Foerster Resonance Energy Transfer (FRET) experiments. Deep-LASI automatically sorts single molecule traces, determines FRET correction factors and classifies the state transitions of dynamic traces, all in ~20-100 ms per trajectory. We thoroughly benchmarked Deep-LASI using ground truth simulations as well as experimental data analyzed manually by an expert user and compared the results with a conventional Hidden Markov Model analysis. We illustrate the capabilities of the technique using a highly tunable L-shaped DNA origami structure and use Deep-LASI to perform titrations, analyze protein conformational dynamics and demonstrate its versatility for analyzing both total internal reflection fluorescence microscopy and confocal smFRET data.

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Reliability and accuracy of single-molecule FRET studies for characterization of structural dynamics and distances in proteins

Cited by 24 publications

References 88 publications

Time‐resolved microscopy made easy

Time‐resolved microscopy made easy

Farewell to single-well: An automated single-molecule FRET platform for high-content, multiwell plate screening of biomolecular conformations and dynamics

Deep-Learning Assisted, Single-molecule Imaging analysis (Deep-LASI) of multi-color DNA Origami structures

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