Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 A trimethoprim derivative impedes antibiotic resistance evolution.

Literature DB >> 34011959

A trimethoprim derivative impedes antibiotic resistance evolution.

Madhu Sudan Manna^1,2, Yusuf Talha Tamer¹, Ilona Gaszek¹, Nicole Poulides¹, Ayesha Ahmed¹, Xiaoyu Wang², Furkan C R Toprak³, DaNae R Woodard⁴, Andrew Y Koh^5,6, Noelle S Williams², Dominika Borek⁷, Ali Rana Atilgan⁸, John D Hulleman^4,9, Canan Atilgan⁸, Uttam Tambar², Erdal Toprak^10,11.

Abstract

The antibiotic trimethoprim (TMP) is used to treat a variety of Escherichia coli infections, but its efficacy is limited by the rapid emergence of TMP-resistant bacteria. Previous laboratory evolution experiments have identified resistance-conferring mutations in the gene encoding the TMP target, bacterial dihydrofolate reductase (DHFR), in particular mutation L28R. Here, we show that 4'-desmethyltrimethoprim (4'-DTMP) inhibits both DHFR and its L28R variant, and selects against the emergence of TMP-resistant bacteria that carry the L28R mutation in laboratory experiments. Furthermore, antibiotic-sensitive E. coli populations acquire antibiotic resistance at a substantially slower rate when grown in the presence of 4'-DTMP than in the presence of TMP. We find that 4'-DTMP impedes evolution of resistance by selecting against resistant genotypes with the L28R mutation and diverting genetic trajectories to other resistance-conferring DHFR mutations with catalytic deficiencies. Our results demonstrate how a detailed characterization of resistance-conferring mutations in a target enzyme can help identify potential drugs against antibiotic-resistant bacteria, which may ultimately increase long-term efficacy of antimicrobial therapies by modulating evolutionary trajectories that lead to resistance.

Entities: CellLine Chemical Disease Gene Mutation Species

Year: 2021 PMID： 34011959 DOI： 10.1038/s41467-021-23191-z

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

41 in total

1. The epidemiology of antibiotic resistance in hospitals: paradoxes and prescriptions.

Authors: M Lipsitch; C T Bergstrom; B R Levin
Journal: Proc Natl Acad Sci U S A Date: 2000-02-15 Impact factor: 11.205

2. A new antibiotic kills pathogens without detectable resistance.

Authors: Losee L Ling; Tanja Schneider; Aaron J Peoples; Amy L Spoering; Ina Engels; Brian P Conlon; Anna Mueller; Till F Schäberle; Dallas E Hughes; Slava Epstein; Michael Jones; Linos Lazarides; Victoria A Steadman; Douglas R Cohen; Cintia R Felix; K Ashley Fetterman; William P Millett; Anthony G Nitti; Ashley M Zullo; Chao Chen; Kim Lewis
Journal: Nature Date: 2015-01-07 Impact factor: 49.962

3. A Deep Learning Approach to Antibiotic Discovery.

Authors: Jonathan M Stokes; Kevin Yang; Kyle Swanson; Wengong Jin; Andres Cubillos-Ruiz; Nina M Donghia; Craig R MacNair; Shawn French; Lindsey A Carfrae; Zohar Bloom-Ackermann; Victoria M Tran; Anush Chiappino-Pepe; Ahmed H Badran; Ian W Andrews; Emma J Chory; George M Church; Eric D Brown; Tommi S Jaakkola; Regina Barzilay; James J Collins
Journal: Cell Date: 2020-04-16 Impact factor: 41.582

Review 4. Understanding, predicting and manipulating the genotypic evolution of antibiotic resistance.

Authors: Adam C Palmer; Roy Kishony
Journal: Nat Rev Genet Date: 2013-02-19 Impact factor: 53.242

Review 5. Tackling antibiotic resistance.

Authors: Karen Bush; Patrice Courvalin; Gautam Dantas; Julian Davies; Barry Eisenstein; Pentti Huovinen; George A Jacoby; Roy Kishony; Barry N Kreiswirth; Elizabeth Kutter; Stephen A Lerner; Stuart Levy; Kim Lewis; Olga Lomovskaya; Jeffrey H Miller; Shahriar Mobashery; Laura J V Piddock; Steven Projan; Christopher M Thomas; Alexander Tomasz; Paul M Tulkens; Timothy R Walsh; James D Watson; Jan Witkowski; Wolfgang Witte; Gerry Wright; Pamela Yeh; Helen I Zgurskaya
Journal: Nat Rev Microbiol Date: 2011-11-02 Impact factor: 60.633

6. The emergence and mechanisms of trimethoprim resistance in Escherichia coli isolated from outpatients in Finland.

Authors: E Heikkilä; O V Renkonen; R Sunila; P Uurasmaa; P Huovinen
Journal: J Antimicrob Chemother Date: 1990-02 Impact factor: 5.790

Review 7. Resistance to trimethoprim-sulfamethoxazole.

Authors: P Huovinen
Journal: Clin Infect Dis Date: 2001-05-04 Impact factor: 9.079

8. Nucleotide sequence of dihydrofolate reductase genes from trimethoprim-resistant mutants of Escherichia coli. Evidence that dihydrofolate reductase interacts with another essential gene product.

Authors: D R Smith; J M Calvo
Journal: Mol Gen Genet Date: 1982

9. High-Order Epistasis in Catalytic Power of Dihydrofolate Reductase Gives Rise to a Rugged Fitness Landscape in the Presence of Trimethoprim Selection.

Authors: Yusuf Talha Tamer; Ilona K Gaszek; Haleh Abdizadeh; Tugce Altinusak Batur; Kimberly A Reynolds; Ali Rana Atilgan; Canan Atilgan; Erdal Toprak
Journal: Mol Biol Evol Date: 2019-07-01 Impact factor: 16.240

10. Steering Evolution with Sequential Therapy to Prevent the Emergence of Bacterial Antibiotic Resistance.

Authors: Daniel Nichol; Peter Jeavons; Alexander G Fletcher; Robert A Bonomo; Philip K Maini; Jerome L Paul; Robert A Gatenby; Alexander R A Anderson; Jacob G Scott
Journal: PLoS Comput Biol Date: 2015-09-11 Impact factor: 4.475

4 in total

1. Structure-guided functional studies of plasmid-encoded dihydrofolate reductases reveal a common mechanism of trimethoprim resistance in Gram-negative pathogens.

Authors: Jolanta Krucinska; Michael N Lombardo; Heidi Erlandsen; Alexavier Estrada; Debjani Si; Kishore Viswanathan; Dennis L Wright
Journal: Commun Biol Date: 2022-05-13