The ester bond of peptidyl-tRNA undergoes nucleophilic attack in solution and when catalyzed by the ribosome. To characterize the uncatalyzed hydrolysis reaction, a model of peptide release, the transition state structure for hydrolysis of a peptidyl-tRNA mimic was determined. Kinetic isotope effects were measured at several atoms that potentially undergo a change in bonding in the transition state. Large kinetic isotope effects of carbonyl (18)O and alpha-deuterium substitutions on uncatalyzed hydrolysis indicate the transition state is nearly tetrahedral. Kinetic isotope effects were also measured for aminolysis by hydroxylamine to study a reaction similar to the formation of a peptide bond. In contrast to hydrolysis, the large leaving group (18)O isotope effect indicates the C-O3' bond has undergone significant scission in the transition state. The smaller carbonyl (18)O and alpha-deuterium effects are consistent with a later transition state. The assay developed here can also be used to measure isotope effects for the ribosome-catalyzed reactions. These uncatalyzed reactions serve as a basis for determining what aspects of the transition states are stabilized by the ribosome to achieve a rate enhancement.
The ester bond of peptidyl-tRNA undergoes nucleophilic attack in solution and when catalyzed by the ribosome. To characterize the uncatalyzed hydrolysis reaction, a model of n class="Chemical">peptide release, the transition state structure for hydrolysis of a peptidyl-tRNA mimic was determined. Kinetic isotope effects were measured at several atoms that potentially undergo a change in bonding in the transition state. Large kinetic isotope effects of carbonyl (18)O and alpha-deuterium substitutions on uncatalyzed hydrolysis indicate the transition state is nearly tetrahedral. Kinetic isotope effects were also measured for aminolysis by hydroxylamine to study a reaction similar to the formation of a peptide bond. In contrast to hydrolysis, the large leaving group (18)O isotope effect indicates the C-O3' bond has undergone significant scission in the transition state. The smaller carbonyl (18)O and alpha-deuterium effects are consistent with a later transition state. The assay developed here can also be used to measure isotope effects for the ribosome-catalyzed reactions. These uncatalyzed reactions serve as a basis for determining what aspects of the transition states are stabilized by the ribosome to achieve a rate enhancement.
Authors: Martin Laurberg; Haruichi Asahara; Andrei Korostelev; Jianyu Zhu; Sergei Trakhanov; Harry F Noller Journal: Nature Date: 2008-07-02 Impact factor: 49.962
Authors: David A Kingery; Emmanuel Pfund; Rebecca M Voorhees; Kensuke Okuda; Ingo Wohlgemuth; David E Kitchen; Marina V Rodnina; Scott A Strobel Journal: Chem Biol Date: 2008-05
Authors: Andrei Korostelev; Haruichi Asahara; Laura Lancaster; Martin Laurberg; Alexander Hirschi; Jianyu Zhu; Sergei Trakhanov; William G Scott; Harry F Noller Journal: Proc Natl Acad Sci U S A Date: 2008-12-08 Impact factor: 11.205
Authors: Albert Weixlbaumer; Hong Jin; Cajetan Neubauer; Rebecca M Voorhees; Sabine Petry; Ann C Kelley; Venki Ramakrishnan Journal: Science Date: 2008-11-07 Impact factor: 47.728
Authors: Daniel L Kellerman; Kandice S Simmons; Mayra Pedraza; Joseph A Piccirilli; Darrin M York; Michael E Harris Journal: Anal Biochem Date: 2015-05-01 Impact factor: 3.365