Breaking the diffraction barrier in fluorescence microscopy at low light intensities by using reversibly photoswitchable proteins

Hofmann, M.; Eggeling, Christian; Jakobs, Stefan; Hell, Stefan W.

doi:10.1073/pnas.0506010102

Cited by 753 publications

(688 citation statements)

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Section: A R T I C L E Smentioning

confidence: 99%

“…They have facilitated in vivo protein-tracking schemes 2,3 , applications based on singlemolecule observations 4,5 and fluorescence microscopy with subdiffraction resolution [6][7][8][9][10] .Still, photoswitchable proteins have not displayed their full potential, because proteins that are just photoactivatable 11-13 can be switched only once, which implies that repeated measurements with the same molecule are impossible. On the other hand, photochromic or reversibly switchable fluorescent proteins (RSFPs) can be repeatedly photoswitched between a fluorescent and a nonfluorescent state by irradiation with light of two different wavelengths.…”

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

et al. 2011

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VOLUME 29 NUMBER 10 OCTOBER 2011 nature biotechnology A r t i c l e sFluorescent proteins (FPs) 1 whose fluorescence can be reversibly or irreversibly switched by optical irradiation have opened new opportunities for the imaging of cells. They have facilitated in vivo protein-tracking schemes 2,3 , applications based on singlemolecule observations 4,5 and fluorescence microscopy with subdiffraction resolution [6][7][8][9][10] .Still, photoswitchable proteins have not displayed their full potential, because proteins that are just photoactivatable 11-13 can be switched only once, which implies that repeated measurements with the same molecule are impossible. On the other hand, photochromic or reversibly switchable fluorescent proteins (RSFPs) can be repeatedly photoswitched between a fluorescent and a nonfluorescent state by irradiation with light of two different wavelengths. However, in all previously characterized RSFPs, the wavelength used for generating the fluorescence emission is identical to one of the wavelengths used for switching the fluorescence on or off. The result is a complex interlocking of switching and fluorescence readout [14][15][16][17][18][19][20][21][22] , impeding or even precluding many applications, including fluorescence nanoscopy (super-resolution microscopy). Hence, the identification of an RSFP in which the generation of fluorescence is disentangled from switching has long been pursued. RESULTS Generation of the RSFP DreiklangNumerous GFP variants exhibit some degree of (generally undesirable) reversible photoswitching 4,23,24 . We found that the fluorescence of the yellow fluorescent protein Citrine 25,26 , a derivative of GFP, can be reversibly modulated to a small extent by alternate irradiation with light of 365 nm (on switching) and 405 nm (off switching), whereas fluorescence is excited at 515 nm. However, the achievable contrast was low, especially at pH values >6, rendering the reversible switching of Citrine unusable (Supplementary Fig. 1).To further develop this unusual switching behavior, we performed extensive random mutagenesis as well as directed PCR-mediated mutagenesis on a plasmid encoding Citrine. We transformed Escherichia coli with the plasmid, and screened with an automated home-built fluorescence microscope for bacterial colonies expressing fluorescent proteins whose fluorescence was excited with green light (515 nm) and which could be reversibly photoswitched from a fluorescent state to a long-lived nonfluorescent state by irradiation with near-UV (405 nm) light and back to a fluorescent state by UV (365 nm) light (Fig. 1a). In several consecutive screening rounds ~70,000 individual clones were analyzed. Finally, we identified a mutant differing from Citrine at four positions (Citrine-V61L, F64I, Y145H, N146D) ( Supplementary Fig. 2), which can be effectively switched and excited to fluoresce. We named this switchable fluorescent protein Dreiklang, the German word for a three-note chord in music.At thermal equilibrium, Dreiklang adopts the brightly fluorescent ...

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Section: A R T I C L E Smentioning

confidence: 99%

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confidence: 99%

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

et al. 2011

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“…When this spot of subdiffraction dimensions is scanned across the specimen, a super-resolution image is obtained. Subdiffraction imaging techniques that share this working principle are termed reversible saturable optical transition (RESOLFT) [2]; depending on the particular molecular transition exploited to switch fluorophores to a dark state, the modalities are termed stimulated emission depletion (STED) [3][4][5], ground stated depletion (GSD) [6,7] or, simply, RESOLFT [8].…”

Section: Conceptmentioning

confidence: 99%

“…Only those fluorophores in this subdiffraction-sized active region can subsequently be excited; hence, fluorescence is assigned unequivocally to that small spot [8,22]. Akin to STED, the size of the subdiffraction spot in RESOLFT imaging is determined by Eq.…”

Section: Resolft Based On Photoswitching Fluorescent Proteinsmentioning

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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“…In the past two decades a number of super-resolved microscopy (SRM) techniques have emerged for which the resolution is not limited by diffraction. Following the invention of stimulated emission depletion (STED) microscopy [4,5] and ground state depletion (GSD) microscopy [6] these laser scanning approaches were generalised as "RESOLFT" [7] techniques and were later complemented by stochastically switched single molecule localisation techniques such as PALM [8,9] and STORM [10]. While all these SRM techniques can provide excellent laterally super-resolved images of cells near the microscope coverslip, it is more challenging to realise SRM in the axial direction, particularly inside biological samples that present optical aberrations and scattering.…”

Section: Introductionmentioning

confidence: 99%

3‐D stimulated emission depletion microscopy with programmable aberration correction

Lenz

Sinclair

Savell

et al. 2013

Journal of Biophotonics

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We present a stimulated emission depletion (STED) microscope that provides 3‐D super resolution by simultaneous depletion using beams with both a helical phase profile for enhanced lateral resolution and an annular phase profile to enhance axial resolution. The 3‐D depletion point spread function is realised using a single spatial light modulator that can also be programmed to compensate for aberrations in the microscope and the sample. We apply it to demonstrate the first 3‐D super‐resolved imaging of an immunological synapse between a Natural Killer cell and its target cell. (© 2014 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)

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Breaking the diffraction barrier in fluorescence microscopy at low light intensities by using reversibly photoswitchable proteins

Cited by 753 publications

References 23 publications

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

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

Fluorescence nanoscopy. Methods and applications

3‐D stimulated emission depletion microscopy with programmable aberration correction

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