posted on 2021-03-09, 19:06authored byLeslie
W. Chan, Kelsey E. Hern, Chayanon Ngambenjawong, Katie Lee, Ester J. Kwon, Deborah T. Hung, Sangeeta N. Bhatia
The drug-impermeable
bacterial membrane in Gram-negative pathogens
limits antibiotic access to intracellular drug targets. To expand
our rapidly waning antibiotic arsenal, one approach is to improve
the intracellular delivery of drugs with historically poor accumulation
in Gram-negative bacteria. To do so, we engineered macromolecular
potentiators to permeabilize the Gram-negative membrane to facilitate
drug influx. Potentiators, known as WD40, were synthesized by grafting
multiple copies of a cationic α-helical antimicrobial peptide,
WLBU2, onto a dextran polymer scaffold. WD40 enabled drug uptake in
the model pathogen P. aeruginosa, a capability
that was not observed with unmodified WLBU2 peptide. WD40 was able
to reduce minimum inhibitory concentrations of a drug panel by up
to 3 orders of magnitude. Hydrophobic and highly three-dimensional
antibiotics exhibited the greatest potentiation. Antibiotic activity
was potentiated in several clinical strains and resulted in sensitization
of drug-resistant strains to rifampin, a drug not previously used
for Gram-negative infections.