Literature DB >> 34294725

Structural and mechanistic basis for translation inhibition by macrolide and ketolide antibiotics.

Bertrand Beckert1, Elodie C Leroy2, Shanmugapriya Sothiselvam3, Lars V Bock4, Maxim S Svetlov3, Michael Graf1, Stefan Arenz1, Maha Abdelshahid1, Britta Seip2, Helmut Grubmüller5, Alexander S Mankin3, C Axel Innis6, Nora Vázquez-Laslop7, Daniel N Wilson8.   

Abstract

Macrolides and ketolides comprise a family of clinically important antibiotics that inhibit protein synthesis by binding within the exit tunnel of the bacterial ribosome. While these antibiotics are known to interrupt translation at specific sequence motifs, with ketolides predominantly stalling at Arg/Lys-X-Arg/Lys motifs and macrolides displaying a broader specificity, a structural basis for their context-specific action has been lacking. Here, we present structures of ribosomes arrested during the synthesis of an Arg-Leu-Arg sequence by the macrolide erythromycin (ERY) and the ketolide telithromycin (TEL). Together with deep mutagenesis and molecular dynamics simulations, the structures reveal how ERY and TEL interplay with the Arg-Leu-Arg motif to induce translational arrest and illuminate the basis for the less stringent sequence-specific action of ERY over TEL. Because programmed stalling at the Arg/Lys-X-Arg/Lys motifs is used to activate expression of antibiotic resistance genes, our study also provides important insights for future development of improved macrolide antibiotics.
© 2021. The Author(s).

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Year:  2021        PMID: 34294725     DOI: 10.1038/s41467-021-24674-9

Source DB:  PubMed          Journal:  Nat Commun        ISSN: 2041-1723            Impact factor:   14.919


  51 in total

1.  Structures of the Escherichia coli ribosome with antibiotics bound near the peptidyl transferase center explain spectra of drug action.

Authors:  Jack A Dunkle; Liqun Xiong; Alexander S Mankin; Jamie H D Cate
Journal:  Proc Natl Acad Sci U S A       Date:  2010-09-27       Impact factor: 11.205

2.  Revisiting the structures of several antibiotics bound to the bacterial ribosome.

Authors:  David Bulkley; C Axel Innis; Gregor Blaha; Thomas A Steitz
Journal:  Proc Natl Acad Sci U S A       Date:  2010-09-27       Impact factor: 11.205

Review 3.  Ribosome-targeting antibiotics and mechanisms of bacterial resistance.

Authors:  Daniel N Wilson
Journal:  Nat Rev Microbiol       Date:  2014-01       Impact factor: 60.633

Review 4.  Macrolide myths.

Authors:  Alexander S Mankin
Journal:  Curr Opin Microbiol       Date:  2008-10-03       Impact factor: 7.934

5.  Selective protein synthesis by ribosomes with a drug-obstructed exit tunnel.

Authors:  Krishna Kannan; Nora Vázquez-Laslop; Alexander S Mankin
Journal:  Cell       Date:  2012-10-26       Impact factor: 41.582

6.  The general mode of translation inhibition by macrolide antibiotics.

Authors:  Krishna Kannan; Pinal Kanabar; David Schryer; Tanja Florin; Eugene Oh; Neil Bahroos; Tanel Tenson; Jonathan S Weissman; Alexander S Mankin
Journal:  Proc Natl Acad Sci U S A       Date:  2014-10-27       Impact factor: 11.205

7.  Kinetics of drug-ribosome interactions defines the cidality of macrolide antibiotics.

Authors:  Maxim S Svetlov; Nora Vázquez-Laslop; Alexander S Mankin
Journal:  Proc Natl Acad Sci U S A       Date:  2017-12-11       Impact factor: 11.205

Review 8.  How Macrolide Antibiotics Work.

Authors:  Nora Vázquez-Laslop; Alexander S Mankin
Journal:  Trends Biochem Sci       Date:  2018-07-24       Impact factor: 13.807

Review 9.  Context-Specific Action of Ribosomal Antibiotics.

Authors:  Nora Vázquez-Laslop; Alexander S Mankin
Journal:  Annu Rev Microbiol       Date:  2018-06-15       Impact factor: 15.500

10.  A long-distance rRNA base pair impacts the ability of macrolide antibiotics to kill bacteria.

Authors:  Maxim S Svetlov; Sophie Cohen; Nada Alsuhebany; Nora Vázquez-Laslop; Alexander S Mankin
Journal:  Proc Natl Acad Sci U S A       Date:  2020-01-13       Impact factor: 11.205
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  7 in total

1.  Folding of VemP into translation-arresting secondary structure is driven by the ribosome exit tunnel.

Authors:  Michal H Kolář; Gabor Nagy; John Kunkel; Sara M Vaiana; Lars V Bock; Helmut Grubmüller
Journal:  Nucleic Acids Res       Date:  2022-02-28       Impact factor: 16.971

2.  Context-based sensing of orthosomycin antibiotics by the translating ribosome.

Authors:  Kyle Mangano; James Marks; Dorota Klepacki; Chayan Kumar Saha; Gemma C Atkinson; Nora Vázquez-Laslop; Alexander S Mankin
Journal:  Nat Chem Biol       Date:  2022-09-22       Impact factor: 16.174

3.  Ribosome collisions induce mRNA cleavage and ribosome rescue in bacteria.

Authors:  Kazuki Saito; Hanna Kratzat; Annabelle Campbell; Robert Buschauer; A Maxwell Burroughs; Otto Berninghausen; L Aravind; Rachel Green; Roland Beckmann; Allen R Buskirk
Journal:  Nature       Date:  2022-03-09       Impact factor: 69.504

4.  Structural basis for the context-specific action of the classic peptidyl transferase inhibitor chloramphenicol.

Authors:  Egor A Syroegin; Laurin Flemmich; Dorota Klepacki; Nora Vazquez-Laslop; Ronald Micura; Yury S Polikanov
Journal:  Nat Struct Mol Biol       Date:  2022-02-14       Impact factor: 18.361

5.  Cryo-EM structure of Mycobacterium tuberculosis 50S ribosomal subunit bound with clarithromycin reveals dynamic and specific interactions with macrolides.

Authors:  Wen Zhang; ZhiFei Li; Yufan Sun; Peng Cui; Jianhua Liang; Qinghe Xing; Jing Wu; Yanhui Xu; Wenhong Zhang; Ying Zhang; Lin He; Ning Gao
Journal:  Emerg Microbes Infect       Date:  2022-12       Impact factor: 7.163

6.  Structural basis for the inability of chloramphenicol to inhibit peptide bond formation in the presence of A-site glycine.

Authors:  Egor A Syroegin; Elena V Aleksandrova; Yury S Polikanov
Journal:  Nucleic Acids Res       Date:  2022-07-22       Impact factor: 19.160

Review 7.  Azithromycin through the Lens of the COVID-19 Treatment.

Authors:  Georgia G Kournoutou; George Dinos
Journal:  Antibiotics (Basel)       Date:  2022-08-05
  7 in total

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