The emergence of bacterial antimicrobial resistance threatens to undermine the utility of antibiotic therapy in medicine. This threat can be addressed, in part, by reinventing existing antibiotic classes using chemical synthesis. Here we present the discovery of BT-33, a fluorinated macrobicyclic oxepanoprolinamide antibiotic with broad-spectrum activity against multidrug-resistant bacterial pathogens. Structure-activity relationships within the macrobicyclic substructure reveal structural features that are essential to the enhanced potency of BT-33 as well as its increased metabolic stability relative to its predecessors clindamycin, iboxamycin and cresomycin. Using X-ray crystallography, we determine the structure of BT-33 in complex with the bacterial ribosome revealing that its fluorine atom makes an additional van der Waals contact with nucleobase G2505. Through variable-temperature H NMR experiments, density functional theory calculations and vibrational circular dichroism spectroscopy, we compare macrobicyclic homologues of BT-33 and a C7 desmethyl analogue and find that the C7 methyl group of BT-33 rigidifies the macrocyclic ring in a conformation that is highly preorganized for ribosomal binding.
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Discovery of a fluorinated macrobicyclic antibiotic through chemical synthesis.
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Department of Chemistry and Chemical Biology, Harvard University, Cambridge, MA, USA.
The emergence of bacterial antimicrobial resistance threatens to undermine the utility of antibiotic therapy in medicine. This threat can be addressed, in part, by reinventing existing antibiotic classes using chemical synthesis. Here we present the discovery of BT-33, a fluorinated macrobicyclic oxepanoprolinamide antibiotic with broad-spectrum activity against multidrug-resistant bacterial pathogens.
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Octafluorocyclopentene (OFCP) engages linear, unprotected peptides in polysubstitution cascades that generate complex fluorinated polycycles. The reactions occur in a single flask at 0-25 °C and require no catalysts or heavy metals. OFCP can directly polycyclize linear sequences using native functionality, or fluorospiroheterocyclic intermediates can be intercepted with exogenous nucleophiles.
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