Directed evolution of GFP with non-natural amino acids identifies residues for augmenting and photoswitching fluorescence

Directed evolution of GFP with non-natural amino acids identifies residues for augmenting and photoswitching fluorescence

Genetic code reprogramming allows proteins to sample new chemistry through the defined and targeted introduction of non-natural amino acids (nAAs). Many useful nAAs are derivatives of the natural aromatic amino acid tyrosine, with the OH group replaced with useful but often bulkier substituents. Ext...

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Bibliographic Details
Published in:Chemical science (Cambridge) Vol. 6; no. 2; pp. 1159 - 1166
Main Authors: Reddington, Samuel C, Baldwin, Amy J, Thompson, Rebecca, Brancale, Andrea, Tippmann, Eric M, Jones, D Dafydd
Format: Journal Article
Language:English
Published: England 01-02-2015
Subjects:
Amino acids
Chromophores
Evolution
Fluorescence
Photosensitivity
Proteins
Residues
Sampling
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Summary:Genetic code reprogramming allows proteins to sample new chemistry through the defined and targeted introduction of non-natural amino acids (nAAs). Many useful nAAs are derivatives of the natural aromatic amino acid tyrosine, with the OH group replaced with useful but often bulkier substituents. Extending residue sampling by directed evolution identified positions in Green Fluorescent Protein tolerant to aromatic nAAs, including identification of novel sites that modulate fluorescence. Replacement of the buried L44 residue by photosensitive -azidophenylalanine (azF) conferred environmentally sensitive photoswitching. modelling of the L44azF dark state provided an insight into the mechanism of action through modulation of the hydrogen bonding network surrounding the chromophore. Targeted mutagenesis of T203 with aromatic nAAs to introduce π-stacking with the chromophore successfully generated red shifted versions of GFP. Incorporation of azF at residue 203 conferred high photosensitivity on sfGFP with even ambient light mediating a functional switch. Thus, engineering proteins with non-natural aromatic amino acids by surveying a wide residue set can introduce new and beneficial properties into a protein through the sampling of non-intuitive mutations. Coupled with retrospective modelling, this will facilitate both our understanding of the impact of nAAs on protein structure and function, and future design endeavours.
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ISSN:2041-6520
2041-6539
DOI:10.1039/c4sc02827a