Objectives: Fosfomycin (FOS) remains an important therapeutic option for urinary tract infections caused by uropathogenic Escherichia coli (UPEC), but specific virulence traits as biofilm formation, metabolic adaptation, and antimicrobial resistance may limit its efficacy. This study investigated whether the natural compound, trans-cinnamaldehyde (t-CA) potentiates FOS activity against UPEC and explored the underlying mechanisms of its effect Methods: The interaction between t-CA and FOS was assessed using checkerboard assays, time-kill analysis. We evaluated biofilm viability and structure using confocal and scanning microscopy as well as catheter-associated biofilm models. Next, effects on membrane integrity, cell-surface properties, membrane potential, intracellular pyruvate levels, and resistance evolution during serial passage were evaluated. Molecular docking was used to explore potential interactions of t-CA with enzymes involved in pyruvate metabolism. Galleria mellonella infection model was employed to evaluate in vivo therapeutical efficiency. Results: t-CA potentiated FOS activity against laboratory, reference, and clinical UPEC strains, with synergistic or additive interactions observed across the tested collection. The combination enhanced bacterial killing, reduced biofilm viability and biomass, and disrupted biofilm architecture. In catheter-associated biofilms, combined treatment markedly impaired surface-associated UPEC communities. t-CA reduced extracellular matrix abundance and altered cell-surface hydrophobicity and membrane potential without inducing detectable oxidative stress. Mechanistically, t-CA affected pyruvate homeostasis, reduced intracellular pyruvate levels, and phenotypically intersected with the BtsSR pyruvate-sensing pathway. Serial exposure to FOS alone rapidly increased MIC, whereas t-CA limited this phenomenon and did not itself promote reduced susceptibility. The compound combination also improved the survival of UTI89-infected G. mellonella larvae. Conclusions: t-CA enhances FOS activity against UPEC through complementing the antibiofilm and metabolic effects. By weakening biofilm matrix integrity, perturbing pyruvate homeostasis, and limiting FOS-associated MIC elevation, t-CA represents a promising adjuvant candidate for improving FOS efficacy against biofilm-associated UPEC infections.
Karczewska, M., Strzelecki, P., Maciag-Dorszynska, M., Kapusta, M., Pyrczak-Felczykowska, A., Szalewska-Palasz, A., Nowicki, D.
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