Superresolution imaging techniques based on sequential imaging of sparse subsets of single molecules require fluorophores whose emission can be photoactivated or photoswitched. Because typical organic fluorophores can emit significantly more photons than average fluorescent proteins, organic fluorophores have a potential advantage in superresolution imaging schemes, but targeting to specific cellular proteins must be provided. We report the design and application of HaloTag-based target-specific azido DCDHFs, a class of photoactivatable push-pull fluorogens which produce bright fluorescent labels suitable for single-molecule superresolution imaging in live bacterial and fixed mammalian cells.Recently, sequential imaging of sparse subsets of photoactivatable/photoswitchable singlemolecule fluorophores has enabled optical imaging beyond the diffraction limit (DL), providing insight into the sub-diffraction world (e.g. PALM, FPALM, STORM). 1-3 These single-molecule superresolution (SR) techniques have provided the impetus for development of new controllable fluorophores with large numbers of emitted photons N, because the achievable resolution scales as . 4 Most previous SR experiments in living cells 5 have used photocontrollable fluorescent proteins. 6-9 However, despite having the advantage of being target-specific, fluorescent proteins on average provide 10-fold fewer photons before photobleaching than good organic fluorophores. 10,11 Small organic fluorophores have the additional benefit of synthetic design flexibility for tuning target specificity, spectral wavelength, solubility, and other desired properties. Therefore, targeted bright organic Here we present a target-specific photoactivatable organic fluorophore for use inside living and fixed cells, 3, based on the commercial HaloTag targeting approach. [20][21][22] This method requires a genetic fusion to the HaloEnzyme (HaloEnz), which forms a covalent linkage to the HaloTag substrate, thus labeling the protein of interest (i.e. a protein-HaloEnzHaloTag-fluorophore covalent unit). Specifically, we present: (i) the basic photophysical properties of a new targeted photoactivatable probe; (ii) proof-of-principle labeling of known structures in fixed and living mammalian cells validated by co-staining with antibodies or co-transfection with fluorescent proteins; (iii) specific SR imaging of microtubules in a mammalian cell with quantification of resolution enhancement; (iv) demonstration of targeted labeling in living bacteria with diffraction-limited imaging; and finally, (v) SR imaging of poorly understood structures inside living bacteria.As molecules with bright emission for single-molecule imaging, dicyanomethylenedihydrofuran (DCDHF) push-pull fluorophores emit millions of photons before photobleaching, and can enter living cells. 15,23 Recently, we reported a photoactivatable DCDHF fluorogen based on photocaging the fluorescence by replacing the amine donor with a poorly-donating but photolabile azide, which can then be converted back to an am...
Molluscan shells, mainly composed of calcium carbonate, also contain organic components such as proteins and polysaccharides. Shell organic matrices construct frameworks of shell structures and regulate crystallization processes during shell formation. To date, a number of shell matrix proteins (SMPs) have been identified, and their functions in shell formation have been studied. However, previous studies focused only on SMPs extracted from adult shells, secreted after metamorphosis. Using proteomic analyses combined with genomic and transcriptomic analyses, we have identified 31 SMPs from larval shells of the pearl oyster, Pinctada fucata, and 111 from the Pacific oyster, Crassostrea gigas. Larval SMPs are almost entirely different from those of adults in both species. RNA-seq data also confirm that gene expression profiles for larval and adult shell formation are nearly completely different. Therefore, bivalves have two repertoires of SMP genes to construct larval and adult shells. Despite considerable differences in larval and adult SMPs, some functional domains are shared by both SMP repertoires. Conserved domains include von Willebrand factor type A (VWA), chitin-binding (CB), carbonic anhydrase (CA), and acidic domains. These conserved domains are thought to play crucial roles in shell formation. Furthermore, a comprehensive survey of animal genomes revealed that the CA and VWA–CB domain-containing protein families expanded in molluscs after their separation from other Lophotrochozoan linages such as the Brachiopoda. After gene expansion, some family members were co-opted for molluscan SMPs that may have triggered to develop mineralized shells from ancestral, nonmineralized chitinous exoskeletons.
SUMMARY A desire to better understand the role of voltagegated sodium channels (NaVs) in signal conduction and their dysregulation in specific disease states motivates the development of high precision tools for their study. Nature has evolved a collection of small molecule agents, including the shellfish poison (+)-saxitoxin, that bind to the extracellular pore of select NaV isoforms. As described in this report, de novo chemical synthesis has enabled the preparation of fluorescently labeled derivatives of (+)-saxitoxin, STX-Cy5, and STX-DCDHF, which display reversible binding to NaVs in live cells. Electrophysiology and confocal fluorescence microscopy studies confirm that these STX-based dyes function as potent and selective NaV labels. The utility of these probes is underscored in single-molecule and super-resolution imaging experiments, which reveal NaV distributions well beyond the optical diffraction limit in subcellular features such as neuritic spines and filopodia.
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