Literature DB >> 12760849

Variable sensitivity to bacterial methionyl-tRNA synthetase inhibitors reveals subpopulations of Streptococcus pneumoniae with two distinct methionyl-tRNA synthetase genes.

Daniel R Gentry1, Karen A Ingraham, Michael J Stanhope, Stephen Rittenhouse, Richard L Jarvest, Peter J O'Hanlon, James R Brown, David J Holmes.   

Abstract

As reported previously (J. R. Jarvest et al., J. Med. Chem. 45:1952-1962, 2002), potent inhibitors (at nanomolar concentrations) of Staphylococcus aureus methionyl-tRNA synthetase (MetS; encoded by metS1) have been derived from a high-throughput screening assay hit. Optimized compounds showed excellent activities against staphylococcal and enterococcal pathogens. We report on the bimodal susceptibilities of S. pneumoniae strains, a significant fraction of which was found to be resistant (MIC, > or =8 mg/liter) to these inhibitors. Using molecular genetic techniques, we have found that the mechanism of resistance is the presence of a second, distantly related MetS enzyme, MetS2, encoded by metS2. We present evidence that the metS2 gene is necessary and sufficient for resistance to MetS inhibitors. PCR analysis for the presence of metS2 among a large sample (n = 315) of S. pneumoniae isolates revealed that it is widespread geographically and chronologically, occurring at a frequency of about 46%. All isolates tested also contained the metS1 gene. Searches of public sequence databases revealed that S. pneumoniae MetS2 was most similar to MetS in Bacillus anthracis, followed by MetS in various non-gram-positive bacterial, archaeal, and eukaryotic species, with streptococcal MetS being considerably less similar. We propose that the presence of metS2 in specific strains of S. pneumoniae is the result of horizontal gene transfer which has been driven by selection for resistance to some unknown class of naturally occurring antibiotics with similarities to recently reported synthetic MetS inhibitors.

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Year:  2003        PMID: 12760849      PMCID: PMC155832          DOI: 10.1128/AAC.47.6.1784-1789.2003

Source DB:  PubMed          Journal:  Antimicrob Agents Chemother        ISSN: 0066-4804            Impact factor:   5.191


  16 in total

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2.  The impact of genomics on novel antibacterial targets.

Authors:  D J Payne; N G Wallis; D R Gentry; M Rosenberg
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Authors:  S Lacks
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4.  Complete genome sequence of a virulent isolate of Streptococcus pneumoniae.

Authors:  H Tettelin; K E Nelson; I T Paulsen; J A Eisen; T D Read; S Peterson; J Heidelberg; R T DeBoy; D H Haft; R J Dodson; A S Durkin; M Gwinn; J F Kolonay; W C Nelson; J D Peterson; L A Umayam; O White; S L Salzberg; M R Lewis; D Radune; E Holtzapple; H Khouri; A M Wolf; T R Utterback; C L Hansen; L A McDonald; T V Feldblyum; S Angiuoli; T Dickinson; E K Hickey; I E Holt; B J Loftus; F Yang; H O Smith; J C Venter; B A Dougherty; D A Morrison; S K Hollingshead; C M Fraser
Journal:  Science       Date:  2001-07-20       Impact factor: 47.728

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Authors:  L S Håvarstein; G Coomaraswamy; D A Morrison
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6.  Pseudomonic acid: an antibiotic produced by Pseudomonas fluorescens.

Authors:  A T Fuller; G Mellows; M Woolford; G T Banks; K D Barrow; E B Chain
Journal:  Nature       Date:  1971-12-17       Impact factor: 49.962

7.  Nanomolar inhibitors of Staphylococcus aureus methionyl tRNA synthetase with potent antibacterial activity against gram-positive pathogens.

Authors:  Richard L Jarvest; John M Berge; Valerie Berry; Helen F Boyd; Murray J Brown; John S Elder; Andrew K Forrest; Andrew P Fosberry; Daniel R Gentry; Martin J Hibbs; Deborah D Jaworski; Peter J O'Hanlon; Andrew J Pope; Stephen Rittenhouse; Robert J Sheppard; Courtney Slater-Radosti; Angela Worby
Journal:  J Med Chem       Date:  2002-05-09       Impact factor: 7.446

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Authors:  D J LeBlanc; L N Lee; A Abu-Al-Jaibat
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  32 in total

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2.  Novel approach to mapping of resistance mutations in whole genomes by using restriction enzyme modulation of transformation efficiency.

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3.  Selective inhibitors of methionyl-tRNA synthetase have potent activity against Trypanosoma brucei Infection in Mice.

Authors:  Sayaka Shibata; J Robert Gillespie; Angela M Kelley; Alberto J Napuli; Zhongsheng Zhang; Kuzma V Kovzun; Ranae M Pefley; Jocelyn Lam; Frank H Zucker; Wesley C Van Voorhis; Ethan A Merritt; Wim G J Hol; Christophe L M J Verlinde; Erkang Fan; Frederick S Buckner
Journal:  Antimicrob Agents Chemother       Date:  2011-01-31       Impact factor: 5.191

4.  Crystallization of Mycobacterium smegmatis methionyl-tRNA synthetase in the presence of methionine and adenosine.

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5.  Inhibition of methionyl-tRNA synthetase by REP8839 and effects of resistance mutations on enzyme activity.

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Review 6.  Biased gene transfer in microbial evolution.

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7.  Optimization of Methionyl tRNA-Synthetase Inhibitors for Treatment of Cryptosporidium Infection.

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8.  Bacterial resistance to leucyl-tRNA synthetase inhibitor GSK2251052 develops during treatment of complicated urinary tract infections.

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9.  The role of a novel auxiliary pocket in bacterial phenylalanyl-tRNA synthetase druggability.

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Journal:  J Biol Chem       Date:  2014-06-16       Impact factor: 5.157

10.  Distinct states of methionyl-tRNA synthetase indicate inhibitor binding by conformational selection.

Authors:  Cho Yeow Koh; Jessica E Kim; Sayaka Shibata; Ranae M Ranade; Mingyan Yu; Jiyun Liu; J Robert Gillespie; Frederick S Buckner; Christophe L M J Verlinde; Erkang Fan; Wim G J Hol
Journal:  Structure       Date:  2012-08-16       Impact factor: 5.006
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