501939-82-8Relevant articles and documents
Compound design guidelines for evading the efflux and permeation barriers of Escherichia coli with the oxazolidinone class of antibacterials: Test case for a general approach to improving whole cell Gram-negative activity
Spaulding, Andrew,Takrouri, Khuloud,Mahalingam, Pornachandran,Cleary, Dillon C.,Cooper, Harold D.,Zucchi, Paola,Tear, Westley,Koleva, Bilyana,Beuning, Penny J.,Hirsch, Elizabeth B.,Aggen, James B.
, p. 5310 - 5321 (2017/11/13)
Previously we reported the results from an effort to improve Gram-negative antibacterial activity in the oxazolidinone class of antibiotics via a systematic medicinal chemistry campaign focused entirely on C-ring modifications. In that series we set about testing if the efflux and permeation barriers intrinsic to the outer membrane of Escherichia coli could be rationally overcome by designing analogs to reside in specific property limits associated with Gram-negative activity: i) low MW (7.4 1), and iii) zwitterionic character at pH 7.4. Indeed, we observed that only analogs residing within these limits were able to overcome these barriers. Herein we report the results from a parallel effort where we explored structural changes throughout all three rings in the scaffold for the same purpose. Compounds were tested against a diagnostic MIC panel of Escherichia coli and Staphylococcus aureus strains to determine the impact of combining structural modifications in overcoming the OM barriers and in bridging the potency gap between the species. The results demonstrated that distributing the charge-carrying moieties across two rings was also beneficial for avoidance of the outer membrane barriers. Importantly, analysis of the structure-permeation relationship (SPR) obtained from this and the prior study indicated that in addition to MW, polarity, and zwitterionic character, having ≤4 rotatable bonds is also associated with evasion of the OM barriers. These combined results provide the medicinal chemist with a framework and strategy for overcoming the OM barriers in GNB in antibacterial drug discovery efforts.
METHOD FOR TREATING, PREVENTING, OR REDUCING THE RISK OF SKIN INFECTION
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, (2016/06/06)
The present invention relates to methods for treating acne and other skin infections caused or mediated by Propionibacterium acnes, Gardnerella vaginalis, or Staphylococcus aureus in a patient with a safe and effective amount of a topically applied oxazolidinone antibiotic compound.
Novel substituted (pyridin-3-yl)phenyloxazolidinones: Antibacterial agents with reduced activity against monoamine oxidase A and increased solubility
Reck, Folkert,Zhou, Fei,Eyermann, Charles J.,Kern, Gunther,Carcanague, Dan,Ioannidis, Georgine,Illingworth, Ruth,Poon, Grace,Gravestock, Michael B.
, p. 4868 - 4881 (2008/03/12)
Oxazolidinones represent a new and promising class of antibacterial agents. Current research in this area is mainly concentrated on improving the safety profile and the antibacterial spectrum. Oxazolidinones bearing a (pyridin-3-yl)phenyl moiety (e.g., 3) generally show improved antibacterial activity compared to linezolid but suffer from potent monoamine oxidase A (MAO-A) inhibition and low solubility. We now disclose the finding that new analogues of 3 with acyclic substituents on the pyridyl moiety exhibit excellent activity against Gram-positive pathogens, including linezolid-resistant Streptococcus pneumoniae. Generally, more bulky substituents yielded significantly reduced MAO-A inhibition relative to the unsubstituted compound 3. The MAO-A SAR can be rationalized on the basis of docking studies using a MAO-A/MAO-B homology model. Solubility was enhanced with incorporation of polar groups. One optimized analogue, compound 13, showed low clearance in the rat and efficacy against S. pneumoniae in a mouse pneumonia model.