A reversibly photoswitchable GFP-like protein with fluorescence excitation decoupled from switching

Brakemann, T.; Stiel, André C.; Weber, Gert; Andresen, Martin A.; Testa, Ilaria; Grotjohann, Tim; Leutenegger, Marcel; Plessmann, Uwe; Urlaub, Henning; Eggeling, Christian; Wahl, Markus C.; Hell, Stefan W.; Jakobs, Stefan

doi:10.1038/nbt.1952

Cited by 281 publications

(425 citation statements)

References 48 publications

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“…Alexa 647, Dronpa, Dreinklang and rsEGFP) 3,[18][19][20] and (ii) irreversibly photoactivatable and photoconvertible (e.g. PA-GFP, PA-mCherry, mEos2, mEos3.1, mEos3.2, Dendra2, mClavGR2 and mMaple) [21][22][23][24][25][26][27] .…”

Section: Introductionmentioning

confidence: 99%

Single-molecule evaluation of fluorescent protein photoactivation efficiency using an in vivo nanotemplate

et al. 2014

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Photoswitchable fluorescent probes are central to localization-based super-resolution microscopy. Among these probes, fluorescent proteins are appealing because they are genetically encoded. Moreover, the ability to achieve a one to one labeling ratio between the fluorescent protein and the protein of interest makes them attractive for quantitative single molecule counting. The percentage of fluorescent protein that is photoactivated into a fluorescently detectable form (i.e. photoactivation efficiency) plays a critical role in properly interpreting the quantitative information. It is important to characterize the photoactivation efficiency at the single molecule level to replicate the conditions used in super-resolution imaging. Here, we used the human Glycine receptor expressed in Xenopus oocytes and stepwise photobleaching or single molecule counting-PALM to determine the percentage of photoactivated fluorescent protein for mEos2, mEos3.1, mEos3.2, Dendra2, mClavGR2, mMaple, PA-GFP and PA-mCherry. This analysis provides important information that must be considered when using these fluorescent proteins in quantitative super-resolution microscopy.

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Section: Introductionmentioning

confidence: 99%

Single-molecule evaluation of fluorescent protein photoactivation efficiency using an in vivo nanotemplate

et al. 2014

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“…STED imaging can be performed on fusion constructs of fluorescent proteins that also span most of the visible spectrum: green (GFP [112]), yellow (YFP [113] and citrine [114]) and far-red emitting proteins (TagRFP657 [115] and the tetrametric E2-Crimson [116]). Several reversible photoswitchable proteins have also been demonstrated suitable for RESOLFT imaging, exploiting their reversible switching behaviour to deplete the periphery of the focal spot (Dronpa and its counterpart Padron derivative [15,22], rsEGFP2 [23] and Dreiklang [117]). …”

Section: Fluorescent Probes For Sted Imagingmentioning

confidence: 99%

Fluorescence nanoscopy. Methods and applications

Requejo-Isidro

2013

J Chem Biol

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Fluorescence nanoscopy refers to the experimental techniques and analytical methods used for fluorescence imaging at a resolution higher than conventional, diffractionlimited, microscopy. This review explains the concepts behind fluorescence nanoscopy and focuses on the latest and promising developments in acquisition techniques, labelling strategies to obtain highly detailed super-resolved images and in the quantitative methods to extract meaningful information from them.

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“…This has been used to explore lipid organization on the cell surface [55]. The optimization of the fluorophores for STED has led to the reduction in the laser powers needed, reducing concerns about photodamage caused by the lasers [56].…”

Section: Future Outlooksmentioning

confidence: 99%

Imaging the cell surface and its organization down to the level of single molecules

Klenerman

Shevchuk

Novák

et al. 2013

Phil. Trans. R. Soc. B

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Determining the organization of key molecules on the surface of live cells in two dimensions and how this changes during biological processes, such as signalling, is a major challenge in cell biology and requires methods with nanoscale spatial resolution and high temporal resolution. Here, we review biophysical tools, based on scanning ion conductance microscopy and single-molecule fluorescence and the combination of both of these methods, which have recently been developed to address these issues. We then give examples of how these methods have been be applied to provide new insights into cell membrane organization and function, and discuss some of the issues that will need to be addressed to further exploit these methods in the future.

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A reversibly photoswitchable GFP-like protein with fluorescence excitation decoupled from switching

Cited by 281 publications

References 48 publications

Single-molecule evaluation of fluorescent protein photoactivation efficiency using an in vivo nanotemplate

Single-molecule evaluation of fluorescent protein photoactivation efficiency using an in vivo nanotemplate

Fluorescence nanoscopy. Methods and applications

Imaging the cell surface and its organization down to the level of single molecules

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