Polymyxin B nonapeptide potentiates the eradication of Gram-negative bacterial persisters.

Antibiotic-resistant Gram-negative bacteria remain a globally leading cause of bacterial infection-associated mortality, and it is imperative to identify novel therapeutic strategies. Recently, the advantage of using antibacterials selective against Gram-negative bacteria has been demonstrated with polymyxins that specifically target the lipopolysaccharides of Gram-negative bacteria. However, the severe cytotoxicity of polymyxins limits their clinical use. Here, we demonstrate that polymyxin B nonapeptide (PMBN), a polymyxin B derivative without the terminal amino acyl residue, can significantly enhance the effectiveness of commonly used antibiotics against only Gram-negative bacteria and their persister cells. We show that although PMBN itself does not exhibit antibacterial activity or cytotoxicity well above the 100-fold minimum inhibitory concentration of polymyxin B, PMBN can increase the potency of co-treated antibiotics. We also demonstrate that using PMBN in combination with other antibiotics significantly reduces the frequency of resistant mutant formation. Together, this work provides evidence of the utilities of PMBN as a novel potentiator for antibiotics against Gram-negative bacteria and insights for the eradication of bacterial persister cells during antibiotic treatment. IMPORTANCE: The significance of our study lies in addressing the problem of antibiotic-resistant Gram-negative bacteria, which continue to be a global cause of mortality associated with bacterial infections. Therefore, identifying innovative therapeutic approaches is an urgent need. Recent research has highlighted the potential of selective antibacterials like polymyxins, which specifically target the lipopolysaccharides of Gram-negative bacteria. However, the clinical use of polymyxins is limited by their severe cytotoxicity. This study unveils the effectiveness of polymyxin B nonapeptide (PMBN) in significantly enhancing the eradication of persister cells in Gram-negative bacteria. Although PMBN itself does not exhibit antibacterial activity or cytotoxicity, it remarkably reduces persister cells during the treatment of antibiotics. Moreover, combining PMBN with other antibiotics reduces the emergence of resistant mutants. Our research emphasizes the utility of PMBN as a novel potentiator to decrease persister cells during antibiotic treatments for Gram-negative bacteria.

Multiple heteroresistance to tigecycline and colistin in Acinetobacter baumannii isolates and its implications for combined antibiotic treatment.

BACKGROUND: We investigated the presence of heteroresistance against both tigecycline and colistin in Acinetobacter baumannii and then evaluated the effectiveness of combined antibiotic treatment given the existence of discrete tigecycline- and colistin-resistant subpopulations. METHODS: We performed population analysis profiling (PAP) to evaluate the degree of composite heteroresistance in A. baumannii isolates, with the extent of this resistance quantified using subsequent antibiotic susceptibility testing. We then evaluated the amino acid sequence of PmrBAC and the relative mRNA expression levels of pmrB. Finally, we investigated the combined antibiotic efficacy of tigecycline and colistin in multiple-heteroresistant isolates using dual PAP and in vitro time-killing assays. RESULTS: All tigecycline-heteroresistant A. baumannii isolates, with the exception of one colistin-resistant isolate, were also heteroresistant to colistin. Evaluations of the colistin-resistant subpopulations revealed amino acid alterations in PmrA and PmrB and increased expression of pmrB. All tigecycline-resistant subpopulations were susceptible to colistin, and all colistin-resistant subpopulations were susceptible to tigecycline. Dual PAP analysis using tigecycline and colistin showed no heteroresistance, and in vitro time-killing assays revealed that a combination of these two antibiotics effectively eliminated the bacterial cells. CONCLUSION: Our results suggest that multiple heteroresistance to tigecycline and colistin is highly prevalent among A. baumannii clinical isolates and that these resistant subpopulations exist independently in single multiple heteroresistant isolates. Therefore, our findings may explain the success of combined antibiotic therapies in these infections.

Lipid A modification-induced colistin-resistant Klebsiella variicola from healthy adults.

Background. Klebsiella variicola was once recognised as a benign plant-endosymbiont but recent case reports suggest that it is a newly emerging Gram-negative pathogen related to opportunistic infection of multiple sites in humans.Methods. Antimicrobial susceptibility testing was performed using broth microdilution method. To identify colistin resistance mechanisms, phoPQ, pmrAB, and mgrB were sequenced and their mRNA expression was analysed using quantitative real-time PCR. In addition, we tried to detect crrAB and mcr. The lipid A moieties of colistin-susceptible and -resistant isolates were analysed using MALDI-TOF.Results. Among the two K. variicola isolates, one is colistin-resistant, and another is colistin-susceptible. The colistin-resistant K. variicola isolate showed no mutations in phoPQ, pmrAB, and mgrB, and crrAB and mcr were not identified. However, its phoQ and pbgP expression was significantly higher and amino-arabinosylated lipid A with hexa-acylated species in lipopolysaccharide was identified.Conclusions. We found that colistin resistance in K. variicola was mediated by the modification of lipid A. Although the isolate was obtained from faecal samples of healthy adults, colistin-resistant K. variicola challenges public health as an opportunistic pathogen.

Treatment of Colistin Dependence-Developing Acinetobacter baumannii with Antibiotic Combinations at Subinhibitory Concentrations.

Recent studies have revealed that colistin dependence frequently develops in colistin-susceptible Acinetobacter baumannii isolates. Despite resistance in parental strains, colistin-dependent mutants showed increased susceptibility to several antibiotics, which suggests the possibility of developing strategies to eliminate multidrug-resistant (MDR) A. baumannii. We investigated in vitro and in vivo efficacy of combinations of colistin and other antibiotics using MDR A. baumannii strains H08-391, H06-855, and H09-94, which are colistin-susceptible but develops colistin dependence upon exposure to colistin. An in vitro time-killing assay, a checkerboard assay, and an antibiotic treatment assay using Galleria mellonella larvae were performed. Although a single treatment of colistin at a high concentration did not prevent colistin dependence, combinations of colistin with other antibiotics at subinhibitory concentrations, especially amikacin, eradicated the strains by inhibiting the development of colistin dependence, in the in vitro time-killing assay. Only 40% of G. mellonella larvae infected by A. baumannii survived with colistin treatment alone; however, all or most of them survived following treatment with the combination of colistin and other antibiotics (amikacin, ceftriaxone, and tetracycline). Our results suggest the possibility of the combination of colistin and amikacin or other antibiotics as one of therapeutic options against A. baumannii infections by eliminating colistin-dependent mutants.

Development mechanism of resistant population post-exposure to tigecycline in tigecycline-heteroresistant Acinetobacter baumannii strain.

Tigecycline heteroresistance is highly prevalent in Acinetobacter baumannii clinical isolates, reducing the efficacy of tigecycline treatment. This study investigated the population dynamics of A. baumannii with tigecycline heteroresistance to determine the origin of resistance that occurs over time after antibiotic exposure. Tigecycline heteroresistance was imitated by mixing tigecycline-susceptible and -resistant A. baumannii isolates in a 1:10-6 ratio, and confirmed using population analysis profiling. Growth curves and an in-vitro competition assay found no difference in bacterial fitness between tigecycline-resistant and -susceptible populations. The green fluorescent protein (GFP) expression system and flow cytometry were used to monitor the population dynamics of the heteroresistant population, while differentiating the resistant population from the susceptible population. The mimicked tigecycline heteroresistance was confirmed to be reproducible and stable without tigecycline. The GFP-expressing population (i.e. the resistant population) nearly went undetected because it only represented approximately 10-6 of the entire population. However, when the mimicked tigecycline-heteroresistant strain was treated with tigecycline, most subpopulations expressing GFP were detected. The surviving A. baumannii population, upon exposure to tigecycline, exhibited a high minimum inhibitory concentration for tigecycline, equivalent to that of tigecycline-resistant isolates that were used to mimic heteroresistance. These results indicate that the development of resistance in tigecycline-heteroresistant A. baumannii strains, resulting in decreased antibiotic efficacy, may depend on the selection of a pre-existing resistant subpopulation.

Tigecycline Heteroresistance and Resistance Mechanism in Clinical Isolates of Acinetobacter baumannii.

Tigecycline is regarded as a last-resort treatment for multidrug-resistant Acinetobacter baumannii. However, tigecycline resistance in A. baumannii has increased worldwide. In this study, we investigated tigecycline heteroresistance in A. baumannii isolates from South Korea. Antibiotic susceptibility testing was performed on 323 nonduplicated A. baumannii isolates. Among 260 and 37 tigecycline-susceptible and -intermediate-resistant A. baumannii isolates, 146 (56.2%) and 22 (59.5%) isolates were identified as heteroresistant to tigecycline through a disk diffusion assay and population analysis profiling. For selected isolates, an in vitro time-kill assay was performed, and survival rates were measured after preincubation with diverse concentrations of tigecycline. Heteroresistant isolates showed regrowth after 12 h of 2× MIC of tigecycline treatment, and resistant subpopulations were selected by preexposure to tigecycline. Furthermore, genetic alterations in adeABC, adeRS, and rpsJ were assessed, and the relative mRNA expression levels of adeB and adeS were compared. The tigecycline resistance in subpopulations might be due to the insertion of ISAba1 in adeS, leading to the overexpression of the AdeABC efflux pump. However, the tigecycline resistance of subpopulations was not stable during serial passages in antibiotic-free medium. The reversion of tigecycline susceptibility by antibiotic-free passages might occur by additional insertions of ISAba10 in adeR and nucleotide alterations in adeS in some mutants. Tigecycline heteroresistance is prevalent in A. baumannii isolates, which results in treatment failure. Tigecycline resistance is mainly due to the overexpression of the AdeABC efflux pump, which is associated with genetic mutations, but this resistance could be reversed into susceptibility by additional mutations in antibiotic-free environments. IMPORTANCE The evidence that antibiotic heteroresistance is responsible for treatment failure in clinical settings is increasing. Thus, detection and characterization of heteroresistance would be important for appropriate therapeutic guidance to treat bacterial infections. However, data on tigecycline heteroresistance in Gram-negative bacteria is currently limited, although tigecycline is regarded as a last-line antibiotic against infections caused by antibiotic-resistant pathogens. In this study, we investigated the tigecycline heteroresistance in Acinetobacter baumannii, which has been listed by the WHO as a priority for research and development of new antibiotics. We found very high prevalence of tigecycline-heteroresistant A. baumannii clinical isolates, which may result in treatment failure due to the selection of resistant subpopulations. We also identified the main resistance mechanism in tigecycline-resistant subpopulations, that is, upregulation of AdeABC efflux pumps due to ISAba1 insertion in adeS.