posted on 2016-12-23, 14:07authored byJan-Stefan Völler, Morana Dulic, Ulla I. M. Gerling-Driessen, Hernan Biava, Tobias Baumann, Nediljko Budisa, Ita Gruic-Sovulj, Beate Koksch
Fluorine being not
substantially present in the chemistry of living
beings is an attractive element in tailoring novel chemical, biophysical,
and pharmacokinetic properties of peptides and proteins. The hallmark
of ribosome-mediated artificial amino acid incorporation into peptides
and proteins is a broad substrate tolerance, which is assumed to rely
on the absence of evolutionary pressure for efficient editing of artificial
amino acids. We used the well-characterized editing proficient isoleucyl-tRNA
synthetase (IleRS) from Escherichia coli to investigate
the crosstalk of aminoacylation and editing activities against fluorinated
amino acids. We show that translation of trifluoroethylglycine (TfeGly)
into proteins is prevented by hydrolysis of TfeGly-tRNAIle in the IleRS post-transfer editing domain. The remarkable observation
is that dissociation of TfeGly-tRNAIle from IleRS is significantly
slowed down. This finding is in sharp contrast to natural editing
reactions by tRNA synthetases wherein fast editing rates for the noncognate
substrates are essential to outcompete fast aa-tRNA dissociation rates.
Using a post-transfer editing deficient mutant of IleRS (IleRSAla10),
we were able to achieve ribosomal incorporation of TfeGly in vivo.
Our work expands the knowledge of ribosome-mediated artificial amino
acid translation with detailed analysis of natural editing function
against an artificial amino acid providing an impulse for further
systematic investigations and engineering of the translation and editing
of unusual amino acids.