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Metal-induced isomerization yields an intracellular chelator that disrupts bacterial iron homeostasis.

Author(s): Shannon B. Falconer; Wenliang Wang; Sebastian S. Gehrke; Jessica D. Cuneo; James F. Britten; Gerard D. Wright; Eric D. Brown

Publication: 2014. "Chem Biol" 21, 1 (January 16.): 136-45.

Identifier(s): PubMed ID: 24361049; ISSN: 1879-1301; Citation Key: 7393

DOI: https://doi.org/10.1016/j.chembiol.2013.11.007

Publication type: Journal Article

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Abstract:

The dwindling supply of antibiotics that remain effective against drug-resistant bacterial pathogens has precipitated efforts to identify new compounds that inhibit bacterial growth using untapped mechanisms of action. Here, we report both (1) a high-throughput screening methodology designed to discover chemical perturbants of the essential, yet unexploited, process of bacterial iron homeostasis, and (2) our findings from a small-molecule screen of more than 30,000 diverse small molecules that led to the identification and characterization of two spiro-indoline-thiadiazoles that disrupt iron homeostasis in bacteria. We show that these compounds are intracellular chelators with the capacity to exist in two isomeric states. Notably, these spiroheterocyles undergo a transition to an open merocyanine chelating form with antibacterial activity that is specifically induced in the presence of its transition-metal target.