The Structure of the Bimolecular Complex between Amphotericin
B and Ergosterol in Membranes Is Stabilized by Face-to-Face van der
Waals Interaction with Their Rigid Cyclic Cores
Amphotericin B (AmB) is a polyene
macrolide antibiotic isolated
from Streptomyces nodosus. The antifungal activity
of AmB can be attributed to the formation of an ion-channel assembly
in the presence of ergosterol (Erg), in which there are two different
AmB–Erg orientations, parallel and antiparallel, as reported
previously. In this study, to elucidate the structures of those AmB–Erg
complexes based on solid-state nuclear magnetic resonance, a 19F-labeled AmB derivative was newly prepared by a hybrid synthesis
that utilized degradation products from the drug. Using the 2-(trimethylsilyl)ethoxymethyl
(SEM) group as the protecting group for the carboxylic acid moiety
of AmB, the fully deprotected labeled AmB compounds were obtained
successfully. Then, these labeled AmBs were subjected to 13C{19F} rotational-echo double-resonance (REDOR) experiments
in hydrated lipid bilayers. The results indicated the coexistence
of parallel and antiparallel orientations for AmB and Erg pairing,
at a ratio of 7:3. A total of six distances between AmB and Erg were
successfully obtained. Geometry analysis using the distance constraints
derived from the REDOR experiments provided the plausible AmB–Erg
complex structure for both the parallel and antiparallel interactions.
The flat macrolide of AmB and the tetracyclic core of Erg closely
contacted in a face-to-face manner, thus maximizing the van der Waals
interaction between the two molecules. This interaction can be attributed
to the coexistence of both the parallel and antiparallel orientations.