The small GTPases, Rab5 and Rac, are essential for endocytosis and actin remodeling, respectively. Coordination of these processes is critical to achieve spatial restriction of intracellular signaling, which is essential for a variety of polarized functions. Here, we show that clathrin- and Rab5-mediated endocytosis are required for the activation of Rac induced by motogenic stimuli. Rac activation occurs on early endosomes, where the RacGEF Tiam1 is also recruited. Subsequent recycling of Rac to the plasma membrane ensures localized signaling, leading to the formation of actin-based migratory protrusions. Thus, membrane trafficking of Rac is required for the spatial resolution of Rac-dependent motogenic signals. We further demonstrate that a Rab5-to-Rac circuitry controls the morphology of motile mammalian tumor cells and primordial germinal cells during zebrafish development, suggesting that this circuitry is relevant for the regulation of migratory programs in various cells, in both in vitro settings and whole organisms.
Lens-based optical microscopy failed to discern fluorescent features closer than 200 nm for decades, but the recent breaking of the diffraction resolution barrier by sequentially switching the fluorescence capability of adjacent features on and off is making nanoscale imaging routine. Reported fluorescence nanoscopy variants switch these features either with intense beams at defined positions or randomly, molecule by molecule. Here we demonstrate an optical nanoscopy that records raw data images from living cells and tissues with low levels of light. This advance has been facilitated by the generation of reversibly switchable enhanced green fluorescent protein (rsEGFP), a fluorescent protein that can be reversibly photoswitched more than a thousand times. Distributions of functional rsEGFP-fusion proteins in living bacteria and mammalian cells are imaged at <40-nanometre resolution. Dendritic spines in living brain slices are super-resolved with about a million times lower light intensities than before. The reversible switching also enables all-optical writing of features with subdiffraction size and spacings, which can be used for data storage.
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 ...
The super-resolution microscopy called RESOLFT relying on fluorophore switching between longlived states, stands out by its coordinate-targeted sequential sample interrogation using low light levels. While RESOLFT has been shown to discern nanostructures in living cells, the reversibly photoswitchable green fluorescent protein (rsEGFP) employed in these experiments was switched rather slowly and recording lasted tens of minutes. We now report on the generation of rsEGFP2 providing faster switching and the use of this protein to demonstrate 25–250 times faster recordings.DOI: http://dx.doi.org/10.7554/eLife.00248.001
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.