Uncompetitive antagonism of AMPA receptors: Mechanistic insights from studies of polyamine toxin derivatives.

Philanthotoxins are uncompetitive antagonists of Ca2+-permeable AMPA receptors presumed to bind to the pore-forming region, but a detailed molecular mechanism for this interaction is missing. Here a small library of novel philanthotoxins was designed and synthesized using a solid-phase strategy. The biological activities were investigated at cloned and "native" AMPA receptors using electrophysiological techniques. A distinct relationship between length of the polyamine moiety and the location of a secondary amino group was observed. Fitting the data to the Woodhull equation allowed the first experimental demonstration of the relative location and orientation of the philanthotoxin molecule in the receptor. These results were corroborated by in silico studies using a homology model of the AMPA receptor ion channel. Together these studies provide strong evidence for a molecular mechanism by which polyamine toxins antagonize the AMPA receptor ion channel and provide the basis for rational development of uncompetitive antagonists of AMPA receptors.

Design and synthesis of labeled analogs of PhTX-56, a potent and selective AMPA receptor antagonist.

Polyamines and polyamine toxins are biologically important molecules, having modulatory effects on nucleotides and proteins. The wasp toxin, philanthotoxin-433 (PhTX-433), is a non-selective and uncompetitive antagonist of ionotropic receptors, such as ionotropic glutamate receptors and nicotinic acetylcholine receptors. Polyamine toxins are used for the characterization of subtypes of ionotropic glutamate receptors, the Ca2+-permeable AMPA and kainate receptors. A derivative of the native polyamine toxin, philanthotoxin-56 (PhTX-56), has recently been shown to be an exceptionally potent and selective antagonist of Ca2+-permeable AMPA receptors. PhTX-56 and its labeled derivatives are promising tools for structure-function studies of the ion channel of the AMPA receptor. We now describe the design and synthesis of 3H-, 13C-, and 15N-labeled derivatives of PhTX-56 for molecular level studies of AMPA receptors. [3H]PhTX-56 was prepared from a diiodo-precursor with high specific radioactivity, providing the first radiolabeled ligand binding to the pore-forming part of AMPA receptors. For advanced biological NMR studies, 13C and 15N-labeled PhTX-56 were synthesized using solid-phase synthesis. These analogs can provide detailed information on the ligand-receptor interaction. In conclusion, synthesis of labeled derivatives of PhTX-56 provides important tools for future studies of the pore-forming region of AMPA receptors.