An uncharged amine in the transition state of the ribosornal peptidyl transfer 
reaction.

Kingery, D. A.; Pfund, E.; Voorhees, R. M.; Okuda, K.; Wohlgemuth, I.; Kitchen, D. E.; Rodnina, M. V.; Strobel, S. A.

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An uncharged amine in the transition state of the ribosornal peptidyl transfer reaction.

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Wohlgemuth, I.
Department of Physical Biochemistry, MPI for biophysical chemistry, Max Planck Society;

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Rodnina, M. V.
Department of Physical Biochemistry, MPI for biophysical chemistry, Max Planck Society;

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Citation

Kingery, D. A., Pfund, E., Voorhees, R. M., Okuda, K., Wohlgemuth, I., Kitchen, D. E., et al. (2008). An uncharged amine in the transition state of the ribosornal peptidyl transfer reaction. Chemistry and Biology, 15(5), 493-500. Retrieved from http://download.cell.com/chemistry-biology/pdf/PIIS1074552108001555.pdf.

Cite as: https://hdl.handle.net/11858/00-001M-0000-0012-DC35-E

Abstract

The ribosome has an active site comprised of RNA that catalyzes peptide bond formation. To understand how RNA promotes this reaction requires a detailed understanding of the chemical transition state. Here, we report the Bronsted coefficient of the a-amino nucleophile with a series of puromycin derivatives. Both 50S subunit- and 70S ribosome-catalyzed reactions displayed linear free-energy relationships with slopes close to zero under conditions where chemistry is rate limiting. These results indicate that, at the transition state, the nucleophile is neutral in the ribosome-catalyzed reaction, in contrast to the substantial positive charge reported for typical uncatalyzed aminolysis reactions. This suggests that the ribosomal transition state involves deprotonation to a degree commensurate with nitrogen-carbon bond formation. Such a transition state is significantly different from that of uncatalyzed aminolysis reactions in solution.