While individually inefficient against Gram-negative bacteria, in-vitro combinations of rifampin and OAK were mutually synergistic since sub-minimal inhibitory concentrations of one compound have potentiated the other by 2–4 orders of magnitude. Synergy persisted in-vivo as single-dose systemic treatment of Klebsiella infected mice resulted in 10–20% versus 60% survival, respectively accomplished by individual and combined compounds. This outcome was achieved without drug formulation, rather, pharmacokinetic considerations have inspired the therapeutic regimen.
To address the need for novel alternatives to antibiotics, we attempted to sensitize gram-negative bacilli to innate antibacterial protagonists. We report a lipopeptide-like sequence (C10OOc12O) that inflicted outer membrane damage at a low micromolar range, whereas measurable bacterial growth inhibition in broth medium required >10-fold higher concentrations. In serum, however, C10OOc12O induced antibacterial activity in a manner suppressible by anticomplement antibodies or heat treatment and acted synergistically with exogenous lysozyme in broth and serum media. Upon subcutaneous administration, C10OOc12O exhibited high circulating levels that correlated with significant therapeutic efficacies, using either the mouse peritonitis-sepsis model or the thigh infection model. These findings are consistent with the view that, by damaging the outer membrane, C10OOc12O was able to enhance gram-negative bacilli susceptibility to antibacterial components of the immune humoral arm. Such lipopeptides may therefore be useful in fighting gram-negative bacilli threats through sensitization to endogenous and/or exogenous antibacterial proteins such as lysozyme and complements.
We recently reported the aptitude of a membrane-active lipopeptide (COOcO) to sensitize gram-negative bacilli (GNB) to host antibacterial proteins. Here we explored the potential of harnessing such capacity in the presence of antibiotics. For this purpose, we compared sensitization to antibiotics in broth and plasma; assessed inner and outer membrane damages using scanning electron microscopy, dyes, and mutant strains; and assessed the ability to affect disease course using the mouse peritonitis-sepsis model for mono- and combination therapies. We found that by altering permeability of both outer and inner membranes, subinhibitory concentrations of COOcO can transiently sensitize GNB to diverse cytoplasm-targeting antibiotics in simple media. Sensitization was maintained in plasma, where COOcO instigated greater bactericidal activities, including in the presence of a bacteriostatic antibiotic (erythromycin). Single-dose administrations of rifampin and COOcO to -infected mice resulted in 55% 0, and 36% viability, respectively, for combined and individual treatments. Combining COOcO and erythromycin has similarly improved mice protection from developing fatal sepsis. Consequently, the data confirmed that COOcO renders GNB sensitive to both endogenous and exogenous antibacterials, and suggested that the tripartite concomitant presence increases therapeutic efficacy synergistically. This approach might expand the available treatment options to comprise antimicrobials with low permeability and/or efflux issues.-Jammal, J., Zaknoon, F., Mor, A. Eliciting improved antibacterial efficacy of host proteins in the presence of antibiotics.
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