zeta potential differences between A. baumannii phenotypes probably reflect compositional outer-membrane variations that impact the electrostatic component of colistin activity.
Fluorescence assays employing semi-synthetic or commercial dansyl-polymyxin B, have been widely employed to assess the affinity of polycations, including polymyxins, for bacterial cells and lipopolysaccharide (LPS). The five primary γ-amines on diaminobutyric-acid residues of polymyxin B are potentially derivatized with dansyl-cholride. Mass spectrometric analysis of the commercial product revealed a complex mixture of di- or tetra- dansyl-substituted polymyxin B. We synthesized a mono-substituted fluorescent derivative, dansyl[Lys]1polymyxinB3. The affinity of polymyxin for purified Gram-negative LPS, and whole bacterial cells was investigated. The affinity of dansyl[Lys]1polymyxinB3 for LPS was comparable to polymyxin B and colistin, and considerably greater (kd < 1 μM) than for whole cells (kd ~6 to 12 μM). Isothermal titration calorimetric studies demonstrated exothermic enthalpically driven binding between both polymyxin B and dansyl[Lys]1polymyxinB3 to LPS, attributed to electrostatic interactions. The hydrophobic dansyl moiety imparted a greater entropic contribution to the dansyl[Lys]1polymyxinB3-LPS reaction. Molecular modeling revealed a loss of electrostatic contact within the dansyl[Lys]1polymyxinB3-LPS complex due to steric hindrance from the dansyl[Lys]1 fluorophore; this corresponded with diminished antibacterial activity (MIC ≥ 16 μg/mL). Dansyl[Lys]1polymyxinB3 may prove useful as a screening tool for drug development.
The prevalence of infections caused by multidrug-resistant gram-negative Acinetobacter baumannii strains and the lack of novel antibiotics under development are posing a global dilemma, forcing a resurgence of the last-line antibiotic colistin. Our aim was to use atomic force microscopy (AFM) to investigate the morphology and topography of paired colistin-susceptible and -resistant cells from colistin-heteroresistant A. baumannii strains as a function of bacterial growth phase and colistin exposure. An optimal AFM bacterial sample preparation protocol was established and applied to examine three paired strains. Images revealed rod-shaped colistin-susceptible cells (1.65 ؎ 0.27 m by 0.98 ؎ 0.07 m) at mid-logarithmic phase, in contrast to spherical colistin-resistant cells (1.03 ؎ 0.09 m); the latter were also more diverse in appearance and exhibited a rougher surface topography (7.05 ؎ 1.3 nm versus 11.4 ؎ 2.5 nm for susceptible versus resistant, respectively). Cellular elongation up to ϳ18 m at stationary phase was more commonly observed in susceptible strains, although these "worm-like" cells were also observed occasionally in the resistant population. The effects of colistin exposure on the cell surface of colistin-susceptible and -resistant cells were found to be similar; topographical changes were minor in response to 0.5 g/ml colistin; however, at 4 g/ml colistin, a significant degree of surface disruption was detected. At 32 g/ml colistin, cellular clumping and surface smoothening were evident. Our study has demonstrated for the first time substantial morphological and topographical differences between colistin-susceptible and -resistant cells from heteroresistant A. baumannii strains. These results contribute to an understanding of colistin action and resistance in regard to this problematic pathogen.
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