@article{,
title = {Crystal structure and fluorescence properties of the iSpinach aptamer in complex with DFHBI},
author = {P Fernandez-Millan and A Autour and E Ennifar and E Westhof and M Ryckelynck},
url = {https://www.ncbi.nlm.nih.gov/pubmed/28939697?dopt=Abstract},
doi = {10.1261/rna.063008},
isbn = {28939697},
year = {2017},
date = {2017-01-01},
journal = {RNA},
volume = {23},
number = {12},
pages = {1788-1795},
abstract = {Fluorogenic RNA aptamers are short nucleic acids able to specifically interact with small molecules and strongly enhance their fluorescence upon complex formation. Among the different systems recently introduced, Spinach, an aptamer forming a fluorescent complex with the 3,5-difluoro-4-hydroxybenzylidene imidazolinone (DFHBI), is one of the most promising. Using random mutagenesis and ultrahigh-throughput screening, we recently developed iSpinach, an improved version of the aptamer, endowed with an increased folding efficiency and thermal stability. iSpinach is a shorter version of Spinach comprising five mutations whom the exact role was not deciphered yet. In this work, we co-crystallized a re-engineered version of iSpinach in complex with the DFHBI and solved the x-ray structure of the complex at 2 Å resolution. Only a few mutations were required to optimize iSpinach production and crystallization, underlying the good folding capacity of the molecule. The measured fluorescence half-lives in the crystal were 60% higher than in solution. Comparisons with structures previously reported for Spinach allows shedding some light on the possible function of the different beneficial mutations carried by iSpinach.},
keywords = {DFHBI Spinach crystal structure fluorescence fluorogenic RNA aptamer, ENNIFAR, RYCKELYNCK, Unité ARN, WESTHOF},
pubstate = {published},
tppubtype = {article}
}
Fluorogenic RNA aptamers are short nucleic acids able to specifically interact with small molecules and strongly enhance their fluorescence upon complex formation. Among the different systems recently introduced, Spinach, an aptamer forming a fluorescent complex with the 3,5-difluoro-4-hydroxybenzylidene imidazolinone (DFHBI), is one of the most promising. Using random mutagenesis and ultrahigh-throughput screening, we recently developed iSpinach, an improved version of the aptamer, endowed with an increased folding efficiency and thermal stability. iSpinach is a shorter version of Spinach comprising five mutations whom the exact role was not deciphered yet. In this work, we co-crystallized a re-engineered version of iSpinach in complex with the DFHBI and solved the x-ray structure of the complex at 2 Å resolution. Only a few mutations were required to optimize iSpinach production and crystallization, underlying the good folding capacity of the molecule. The measured fluorescence half-lives in the crystal were 60% higher than in solution. Comparisons with structures previously reported for Spinach allows shedding some light on the possible function of the different beneficial mutations carried by iSpinach.