Amphotericin B (AmB) is a lifesaving antibiotic used to treat deep-seated mycotic infections. Both the pharmaceutical activity and highly toxic side effects of the drug rely on its interaction with biomembranes, which is governed by the molecular organization of AmB. In the present work, we present a detailed analysis of self-assembly of AmB molecules in different environments, interesting from the physiological standpoint, based on molecular spectroscopy techniques: electronic absorption, circular dichroism, steady state and time-resolved fluorescence and molecular dynamic calculations. The results show that, in the water medium, AmB self-associates to dimeric structures, referred to as "parallel" and "antiparallel". AmB dimers can further assemble into tetramers which can play a role of transmembrane ion channels, affecting electrophysiological homeostasis of a living cell. Understanding structural determinants of self-assembly of AmB opens a way to engineering preparations of the drug which retain pharmaceutical effectiveness under reduced toxicity.
Amphotericin B (AmB) is a lifesaving polyene antibiotic used widely to treat deep-seated mycoses. Both the pharmaceutical effectiveness as well as toxic side effects depend on molecular organization of the drug. In the present study, we analyzed steady-state fluorescence, fluorescence anisotropy spectra, fluorescence lifetimes, and fluorescence anisotropy decays of AmB in the systems believed to ensure monomeric organization of the drug and in model lipid membranes. The results of the analyses show that in all of the systems studied, the drug appears in, at least, two spectral forms, interpreted as monomeric and aggregated. Spectroscopic and fluorescence lifetime characteristics of both forms are provided. Interpretation of the fluorescence anisotropy spectra of AmB incorporated into liposomes formed with dipalmitoylphosphatidylcholine let us conclude that monomers of the drug are more tightly bound to the lipid membranes as compared to the aggregates and that AmB aggregates destabilize the membrane structure. Structural model analysis, compared to the analysis of spectral shifts, leads to the conclusion that basic constituents of AmB aggregated structure is a tetramer composed of two hydrogen-bond-stabilized dimers, each dimer formed by molecules twisted by ca. 170°. The tetramer itself can span lipid bilayers and can act as a transmembrane ion channel. Specific aggregate formation of AmB has been concluded as a universal and ubiquitous form of molecular organization of the drug. This process is discussed in terms of toxic side effects of AmB.
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