PMID: 15216632Jun 26, 2004Paper

Amphotericin B channel conductance inactivation

Tsitologiia
Vafa IbragimovaD I Aliev

Abstract

Effects induced in bilayer lipid membranes by amphotericin B and its alkyl derivatives was analysed. Inactivation of the antibiotic-dependent multichannel membrane conductance was discovered. Kinetics of membrane conductivity was shown to depend on the antibiotic concentration in the membrane. At concentrations between 10(-8) and 10(-7) M, the resulting conductance appeared to the transient. We suggest that the phenomenon of biphasic kinetics of membrane conductance is the result of a consecutive transformation of polyene channels in the membrane: half-pores are assembled on either side of membrane-nonconducting 1; two half-pores combine to build up a conducting channels-conducting 2, and the conducting channels are disassemled to monomers and nonconducting self-associated forms inside the membrane-disassembled state (nonconducting 3). To explain the transient characteristics of the induced conductance, it is proposed that the antibiotic, present in the solution under self-associated form, binds the membrane and forms pores, then dissociates in the bilayer in a non-active monomeric form. The existence of definite monomers and nonconducting self-associated forms of amphotericin B molecules inside the membrane was estimated from ...Continue Reading

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