posted on 2021-03-24, 08:20authored byInes Hübner, Justin A. Shapiro, Jörn Hoßmann, Jonas Drechsel, Stephan M. Hacker, Philip N. Rather, Dietmar H. Pieper, William M. Wuest, Stephan A. Sieber
Isonitrile
natural products exhibit promising antibacterial activities.
However, their mechanism of action (MoA) remains largely unknown.
Based on the nanomolar potency of xanthocillin X (Xan) against diverse difficult-to-treat Gram-negative bacteria, including
the critical priority pathogen Acinetobacter baumannii, we performed in-depth studies to decipher its MoA. While neither
metal binding nor cellular protein targets were detected as relevant
for Xan’s antibiotic effects, sequencing of resistant
strains revealed a conserved mutation in the heme biosynthesis enzyme
porphobilinogen synthase (PbgS). This mutation caused impaired enzymatic
efficiency indicative of reduced heme production. This discovery led
to the validation of an untapped mechanism, by which direct heme sequestration
of Xan prevents its binding into cognate enzyme pockets
resulting in uncontrolled cofactor biosynthesis, accumulation of porphyrins,
and corresponding stress with deleterious effects for bacterial viability.
Thus, Xan represents a promising antibiotic displaying
activity even against multidrug resistant strains, while exhibiting
low toxicity to human cells.