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Literature DB >> 14602912

Mononucleotide derivatives as ribosomal P-site substrates reveal an important contribution of the 2'-OH to activity.

Silke Dorner¹, Claudia Panuschka, Walther Schmid, Andrea Barta.

Abstract

The chemical synthesis of various acylaminoacylated mononucleotides is described and their activities as donor substrates for the ribosomal peptide synthesis were investigated using PhetRNA(Phe) as an acceptor. This minimal reaction was characterized in detail and was shown to be stimulated by CMP, cytidine and cytosine. By using several cytidine and cytosine analogs evidence is provided that this enhancement is rather caused by base pairing to rRNA, followed by a structural change, than by a base mediated general acid/base catalysis. Only derivatives of AMP proved active as P-site substrates. Further, a significant contribution of the 2'-OH to activity was indicated by the finding that AcLeu-dAMP was inactive as donor substrate, although it is a good inhibitor of peptide bond formation and thus, is presumably bound to the P-site. However, Di(AcLeu)-2'-OCH(3)-Ade and DiAcLeu-AMP were moderately active in this assay suggesting that the reactivity of the 3'-acylaminoacid ester is stimulated by the presence of the 2'-oxygen group. A model is discussed how further interactions of the 2'-OH in the transition state might influence peptidyl transferase activity.

Entities: Chemical Species

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Year: 2003 PMID： 14602912 PMCID： PMC275539 DOI： 10.1093/nar/gkg842

Source DB: PubMed Journal: Nucleic Acids Res ISSN： 0305-1048 Impact factor: 16.971

26 in total

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26 in total

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5. Two distinct components of release factor function uncovered by nucleophile partitioning analysis.

Authors: Jeffrey J Shaw; Rachel Green
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6. The transition state for peptide bond formation reveals the ribosome as a water trap.

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7. Peptidyl-CCA deacylation on the ribosome promoted by induced fit and the O3'-hydroxyl group of A76 of the unacylated A-site tRNA.

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