Live Cell Imaging of Bioorthogonally Labelled Proteins Generated With a Single Pyrrolysine tRNA Gene

Aloush, Noa; Schvartz, Tomer; König, Andres I.; Cohen, Sarit; Brozgol, Eugene; Tam, Benjamin; Nachmias, Dikla; Ben-David, Oshrit; Garini, Yuval; Elia, Natalie; Arbely, Eyal

doi:10.1038/s41598-018-32824-1

Cited by 28 publications

(26 citation statements)

References 48 publications

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“…We began by testing the applicability of bioorthogonal labeling via GCE for single molecule imaging by using EGFR, a wellstudied receptor that has been previously labeled via GCE, as a benchmark. 16 To this end, EGFR was mutated to carry a TAG codon at the previously published labeling site, Leu 128, and cloned into a single expression vector that encodes the cognate pair of tRNA cua :tRNA-synthetase 17,18 (Fig. S1a †).…”

Section: Resultsmentioning

confidence: 99%

Live cell single molecule tracking and localization microscopy of bioorthogonally labeled plasma membrane proteins

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Section: Resultsmentioning

confidence: 99%

Live cell single molecule tracking and localization microscopy of bioorthogonally labeled plasma membrane proteins

et al. 2020

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“…In all the above‐mentioned examples, the unAA was incorporated at the extracellular regions of the protein and labeling was performed using cell‐impermeable Tet‐Fl‐dyes, thus avoiding the relatively high background levels associated with the technique (see subsection The click reaction, below). After further optimization, the GCE‐based labeling technique was successfully applied for intracellular labeling, and various intracellular components—including intermediate filaments, microtubules, intracellular vesicles, the PM, lysosomes, and the endoplasmic reticulum—were labeled and imaged in live mammalian cells [22,24,35–38]. Here, too, small proteins that could not be labeled using protein tags were successfully labeled and imaged.…”

Section: What Has Been Done With It?mentioning

confidence: 99%

Using unnatural amino acids to selectively label proteins for cellular imaging: a cell biologist viewpoint

Elia

2020

The FEBS Journal

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This viewpoint provides an overview of applying genetic code expansion and click chemistry for labeling proteins for cellular imaging applications. This approach, which enables labeling of proteins in cells at a specific site with fluorescent dyes, has several advantages for cellular imaging. However, it also introduces limitations and challenges for cellular imaging. The current state of the field is discussed as well as the advantages and limitations of this unique approach.

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“…[65] Furthermore, whereas most researchers would argue that more tRNA is better, one study reported that too much tRNA can lead to problems, such as background labelling in fluorescence microscopy studies. [66] This means that depending on the application, it is necessary to determine the optimal amount of both tRNA and aaRS. As discussed earlier, the ratio between the tRNA and aaRS also needs to be taken into account, [58] otherwise, tRNA might be sequestered by the aaRS.…”

Section: Trna Stability and Aars/trna Ratiomentioning

confidence: 99%

“…Recent studies have focused on making more‐stable, rationally designed tRNAs for the PylRS/tRNA system [65] . Furthermore, whereas most researchers would argue that more tRNA is better, one study reported that too much tRNA can lead to problems, such as background labelling in fluorescence microscopy studies [66] . This means that depending on the application, it is necessary to determine the optimal amount of both tRNA and aaRS.…”

Section: Challenges Associated With Genetic Code Expansion and Outlookmentioning

confidence: 99%

Expanding the Genetic Code for Neuronal Studies

Nikić

2020

ChemBioChem

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Genetic code expansion is one of the most powerful technologies in protein engineering. In addition to the 20 canonical amino acids, the expanded genetic code is supplemented by unnatural amino acids, which have artificial side chains that can be introduced into target proteins in vitro and in vivo. A wide range of chemical groups have been incorporated co-translationally into proteins in single cells and multicellular organisms by using genetic code expansion. Incorporated unnatural amino acids have been used for novel structure-function relationship studies, bioorthogonal labelling of proteins in cellulo for microscopy and in vivo for tissue-specific proteomics, the introduction of post-translational modifications and optical control of protein function, to name a few examples. In this Minireview, the development of genetic code expansion technology is briefly introduced, then its applications in neurobiology are discussed, with a focus on studies using mammalian cells and mice as model organisms.

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Live Cell Imaging of Bioorthogonally Labelled Proteins Generated With a Single Pyrrolysine tRNA Gene

Cited by 28 publications

References 48 publications

Live cell single molecule tracking and localization microscopy of bioorthogonally labeled plasma membrane proteins

Live cell single molecule tracking and localization microscopy of bioorthogonally labeled plasma membrane proteins

Using unnatural amino acids to selectively label proteins for cellular imaging: a cell biologist viewpoint

Expanding the Genetic Code for Neuronal Studies

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