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Auteurs principaux: Scott, Will, Ivorra-Molla, Esther, Akhuli, Dipayan, Massam-Wu, Teresa, Lysyganicz, Pawel K, Walsh, Rylie, Parent, Matthew, Cook, Jonathan, Song, Lijiang, Kumar, Abhishek, Schneider, Falk, Mishima, Masanori, Crow, Allister, Balasubramanian, Mohan K
Format: Artículo científico
Langue:en
Publié: The Journal of biological chemistry 2025
Sujets:
Accès en ligne:https://pubmed.ncbi.nlm.nih.gov/41109344/
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author Scott, Will
Ivorra-Molla, Esther
Akhuli, Dipayan
Massam-Wu, Teresa
Lysyganicz, Pawel K
Walsh, Rylie
Parent, Matthew
Cook, Jonathan
Song, Lijiang
Kumar, Abhishek
Schneider, Falk
Mishima, Masanori
Crow, Allister
Balasubramanian, Mohan K
author_facet Scott, Will
Ivorra-Molla, Esther
Akhuli, Dipayan
Massam-Wu, Teresa
Lysyganicz, Pawel K
Walsh, Rylie
Parent, Matthew
Cook, Jonathan
Song, Lijiang
Kumar, Abhishek
Schneider, Falk
Mishima, Masanori
Crow, Allister
Balasubramanian, Mohan K
Scott, Will
Ivorra-Molla, Esther
Akhuli, Dipayan
Massam-Wu, Teresa
Lysyganicz, Pawel K
Walsh, Rylie
Parent, Matthew
Cook, Jonathan
Song, Lijiang
Kumar, Abhishek
Schneider, Falk
Mishima, Masanori
Crow, Allister
Balasubramanian, Mohan K
collection PubMed - marine biology
contents StayRose: A photostable StayGold derivative redshifted by genetic code expansion. Scott, Will Ivorra-Molla, Esther Akhuli, Dipayan Massam-Wu, Teresa Lysyganicz, Pawel K Walsh, Rylie Parent, Matthew Cook, Jonathan Song, Lijiang Kumar, Abhishek Schneider, Falk Mishima, Masanori Crow, Allister Balasubramanian, Mohan K Zebrafish Animals Escherichia coli Red Fluorescent Protein Luminescent Proteins Genetic Code Green Fluorescent Proteins Tyrosine Crystallography, X-Ray Photobleaching of fluorescent proteins often limits the acquisition of high-quality images in microscopy. StayGold, a novel dimeric GFP recently monomerized through sequence engineering, addresses this challenge with its high photostability. There is now a focus on producing different colored StayGold derivatives to facilitate concurrent tagging of multiple targets. The unnatural amino acid 3-aminotyrosine has previously been shown to redshift superfolder GFP upon incorporation into its chromophore via genetic code expansion. Here, we apply the same strategy to redshift StayGold through substitution of tyrosine-58 with 3-aminotyrosine. The resultant red fluorescent protein, StayRose, shows an excitation wavelength maximum of 530 nm and an emission wavelength maximum of 588 nm. Importantly, the monomeric mStayRose retains the favorable photostability in vivo in Escherichia coli and zebrafish embryos. A high-resolution crystal structure of StayRose confirms the modified structure of the amino chromophore within an unperturbed 3D fold. Although reliant on genetic code expansion, StayRose provides an important step toward developing redshifted StayGold derivatives.
format Artículo científico
id pubmed_41109344
institution PubMed
language en
publishDate 2025
publisher The Journal of biological chemistry
record_format pubmed
spellingShingle StayRose: A photostable StayGold derivative redshifted by genetic code expansion.
Scott, Will
Ivorra-Molla, Esther
Akhuli, Dipayan
Massam-Wu, Teresa
Lysyganicz, Pawel K
Walsh, Rylie
Parent, Matthew
Cook, Jonathan
Song, Lijiang
Kumar, Abhishek
Schneider, Falk
Mishima, Masanori
Crow, Allister
Balasubramanian, Mohan K
Zebrafish
Animals
Escherichia coli
Red Fluorescent Protein
Luminescent Proteins
Genetic Code
Green Fluorescent Proteins
Tyrosine
Crystallography, X-Ray
StayRose: A photostable StayGold derivative redshifted by genetic code expansion. Scott, Will Ivorra-Molla, Esther Akhuli, Dipayan Massam-Wu, Teresa Lysyganicz, Pawel K Walsh, Rylie Parent, Matthew Cook, Jonathan Song, Lijiang Kumar, Abhishek Schneider, Falk Mishima, Masanori Crow, Allister Balasubramanian, Mohan K Zebrafish Animals Escherichia coli Red Fluorescent Protein Luminescent Proteins Genetic Code Green Fluorescent Proteins Tyrosine Crystallography, X-Ray Photobleaching of fluorescent proteins often limits the acquisition of high-quality images in microscopy. StayGold, a novel dimeric GFP recently monomerized through sequence engineering, addresses this challenge with its high photostability. There is now a focus on producing different colored StayGold derivatives to facilitate concurrent tagging of multiple targets. The unnatural amino acid 3-aminotyrosine has previously been shown to redshift superfolder GFP upon incorporation into its chromophore via genetic code expansion. Here, we apply the same strategy to redshift StayGold through substitution of tyrosine-58 with 3-aminotyrosine. The resultant red fluorescent protein, StayRose, shows an excitation wavelength maximum of 530 nm and an emission wavelength maximum of 588 nm. Importantly, the monomeric mStayRose retains the favorable photostability in vivo in Escherichia coli and zebrafish embryos. A high-resolution crystal structure of StayRose confirms the modified structure of the amino chromophore within an unperturbed 3D fold. Although reliant on genetic code expansion, StayRose provides an important step toward developing redshifted StayGold derivatives.
title StayRose: A photostable StayGold derivative redshifted by genetic code expansion.
topic Zebrafish
Animals
Escherichia coli
Red Fluorescent Protein
Luminescent Proteins
Genetic Code
Green Fluorescent Proteins
Tyrosine
Crystallography, X-Ray
url https://pubmed.ncbi.nlm.nih.gov/41109344/