Photoswitches: Key molecules for subdiffraction‐resolution fluorescence imaging and molecular quantification

Heilemann, Mike; Dedecker, Peter; Hofkens, Johan; Sauer, Markus

doi:10.1002/lpor.200810043

Cited by 248 publications

(203 citation statements)

References 185 publications

(302 reference statements)

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“…It follows that this convenient imaging technique cannot appreciate the subtle factors that govern biological processes and define biological structures at the molecular level. These stringent limitations can be overcome with the aid of photoactivatable fluorophores [26][27][28][29][30][31][32][33][34][35][36][37][38][39][40][41][42]. Indeed, the ability to switch fluorescence on under optical control permits the separation of distinct probes in time and the sequential reconstruction of images with subdiffraction resolution.…”

Section: Isrn Physical Chemistrymentioning

confidence: 99%

“…Indeed, fluorescence photoactivation permits the monitoring of dynamic processes in real time [13][14][15][16][17][18][19][20][21][22][23][24] as well as the acquisition of images with spatial resolution at the nanometer level [25][26][27][28][29][30][31][32][33][34][35][36][37][38][39][40][41][42]. As a result, significant research efforts are presently directed to the development of strategies for fluorescence photoactivation with fluorescent proteins and synthetic dyes together with their implementation in imaging applications.…”

Section: Introductionmentioning

confidence: 99%

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Photoactivatable Fluorophores

Raymo

2012

ISRN Physical Chemistry

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Photoactivatable fluorophores switch from a nonemissive to an emissive state upon illumination at an activating wavelength and then emit after irradiation at an exciting wavelength. The interplay of such activation and excitation events can be exploited to switch fluorescence on in a defined region of space at a given interval of time. In turn, the spatiotemporal control of fluorescence translates into the opportunity to implement imaging and spectroscopic schemes that are not possible with conventional fluorophores. Specifically, photoactivatable fluorophores permit the monitoring of dynamic processes in real time as well as the reconstruction of images with subdiffraction resolution. These promising applications can have a significant impact on the characterization of the structures and functions of biomolecular systems. As a result, strategies to implement mechanisms for fluorescence photoactivation with synthetic fluorophores are particularly valuable. In fact, a number of versatile operating principles have already been identified to activate the fluorescence of numerous members of the main families of synthetic dyes. These methods are based on either the irreversible cleavage of covalent bonds or the reversible opening and closing of rings. This paper overviews the fundamental mechanisms that govern the behavior of these photoresponsive systems, illustrates structural designs for fluorescence photoactivation, and provides representative examples of photoactivatable fluorophores in actions.

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Section: Isrn Physical Chemistrymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Photoactivatable Fluorophores

Raymo

2012

ISRN Physical Chemistry

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“…In the following, we will demonstrate that the photoswitch meets all the requirements of an ideal dye for super-resolved fluorescence microscopy: [28,29] spectrally well-separated on and off states, high absorption coefficients, high fluorescence quantum yield of …”

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confidence: 96%

Nanoscopic Visualization of Soft Matter Using Fluorescent Diarylethene Photoswitches

et al. 2016

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The in situ imaging of soft matter is of paramount importance for a detailed understanding of functionality on the nanoscopic scale. Although super-resolution fluorescence microscopy methods with their unprecedented imaging capabilities have revolutionized research in the life sciences, this potential has been far less exploited in materials science. One of the main obstacles for a more universal application of superresolved fluorescence microscopy methods is the limitation of readily available suitable dyes to overcome the diffraction limit. Here, we report a novel diarylethene-based photoswitch with a highly fluorescent closed and a nonfluorescent open form. Its photophysical properties, switching behavior, and high photostability make the dye an ideal candidate for photoactivation localization microscopy (PALM). It is capable of resolving apolar structures with an accuracy far beyond the diffraction limit of optical light in cylindrical micelles formed by amphiphilic block copolymers.The nanoscopic structure of soft-matter materials determines their properties. [1] Therefore, methods to directly visualize structures in the nanometer range are of paramount importance for the ongoing evolution of novel materials with specialized and adaptive properties for sophisticated applications. Scanning probe microscopy techniques give access to the nanometer range and determine surface properties such as topology and softness, [2,3] while modern electron microscopy methods, such as scanning electron microscopy (SEM) [4,5] and transmission electron microscopy (TEM), [6][7][8] can yield structural information even in the subnanometer range when there is sufficient electron density contrast. Despite the success of these methods, they are technically demanding and time-consuming. Furthermore, many softmatter samples possess poor electron contrast, and require non-invasive in situ imaging below the surface as well as the possibility to directly study dynamics. In recent years, superresolved fluorescence microscopy has revolutionized optical imaging, [9][10][11][12][13][14] by utilizing the photophysical or photochemical switching of fluorescent dyes in a sophisticated manner in combination with modern optics. So far, the life sciences have benefited, in particular, from the new possibilities of resolving structures well beyond the diffraction limit of light. Only a few examples of the application of super-resolution microscopy to materials science have been reported, [15][16][17][18] since concepts that require, for example, the addition of (polar) switching buffers often fail for these systems. Therefore, the main bottleneck for more universal applications of super-resolution imaging are switchable dyes with suitable (photo-)physical and chemical properties, such as high photostability, adjustable switching rates, minimum interaction with the environment to be probed, and simple design, with the possibility of multiple and straightforward derivatization for the specific labeling of structures or compartments. [19] ...

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“…However, several obstacles remain: (i) PA-FP "blinking" leads to severe overcounting biases. Blinking refers to a process by which a PA-FP produces a series of intermittent emission bursts, instead of a single continuous burst (24,25), by transiently transitioning to a "dark" state. Accordingly, counting the number of emission bursts over a region of interest (ROI) will lead to overestimating the number of labeled molecules; and (ii) Unknown blinking statistics.…”

mentioning

confidence: 99%

Stochastic approach to the molecular counting problem in superresolution microscopy

Rollins

Shin

Bustamante

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

107

119

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Superresolution imaging methods-now widely used to characterize biological structures below the diffraction limit-are poised to reveal in quantitative detail the stoichiometry of protein complexes in living cells. In practice, the photophysical properties of the fluorophores used as tags in superresolution methods have posed a severe theoretical challenge toward achieving this goal. Here we develop a stochastic approach to enumerate fluorophores in a diffraction-limited area measured by superresolution microscopy. The method is a generalization of aggregated Markov methods developed in the ion channel literature for studying gating dynamics. We show that the method accurately and precisely enumerates fluorophores in simulated data while simultaneously determining the kinetic rates that govern the stochastic photophysics of the fluorophores to improve the prediction's accuracy. This stochastic method overcomes several critical limitations of temporal thresholding methods.single molecule | fluorescence | protein complexes | superresolution | counting problem P rotein-protein and protein-nucleic acid interactions are responsible for most of information processing and control in the cell. Moreover, essential cellular tasks such as replication, transcription, translation, recombination, control of gene expression, and transport of proteins across membranes, to cite a few, all depend on the interaction among preorganized molecular assemblies (1-4). Developing a mechanistic understanding of cell biology requires a quantitative determination of macromolecular organization and interaction in living cells. In particular, characterizing protein-protein and protein-nucleic acid complexes and their stoichiometric ratios is a first step in determining how altered stoichiometries may lead to disease states of the cell (5-8).Conventional optical microscopy is diffraction limited and typically cannot resolve images below the 250-nm range, but superresolution (SR) methods can achieve tens of nanometer resolution (9-12). One such SR method is photoactivated localization microscopy (PALM), where temporal separation is achieved by illuminating a sample with inactive (i.e., nonfluorescing) fluorophores under low light intensity. The light stochastically triggers fluorophore activation. Once active, a fluorophore is excited by light of a different wavelength and releases a burst of photons (an emission burst). This emission is used to locate the position of the emitter with uncertainty that depends only on the number of photons detected. A short time later, the fluorophore irreversibly photobleaches. The low probability of photoactivation ensures that two fluorophores separated less than the diffraction limit will most probably not emit simultaneously. In this manner, the PALM fluorophores that could not otherwise be spatially separated are instead separated in time. The fluorophores in PALM are genetically encoded with photoactivatable fluorescent proteins (PA-FPs) (13)-often mEos2 (14) or Dendra2 (15, 16)-that are fused to proteins ...

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Photoswitches: Key molecules for subdiffraction‐resolution fluorescence imaging and molecular quantification

Cited by 248 publications

References 185 publications

Photoactivatable Fluorophores

Photoactivatable Fluorophores

Nanoscopic Visualization of Soft Matter Using Fluorescent Diarylethene Photoswitches

Stochastic approach to the molecular counting problem in superresolution microscopy

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