Mode of action of the positive modulator PNU-120596 on α7 nicotinic acetylcholine receptors.

We investigated the mode of action of PNU-120596, a type II positive allosteric modulator of the rat α7 nicotinic acetylcholine receptor expressed by GH4C1 cells, using patch-clamp and fast solution exchange. We made two important observations: first, while PNU-120596 rapidly associated to desensitized receptors, it had at least hundredfold lower affinity to resting conformation, therefore at 10 µM concentration it dissociated from resting receptors; and second, binding of PNU-120596 slowed down dissociation of choline molecules from the receptor radically. We propose that when agonist concentration is transiently elevated in the continuous presence of the modulator (as upon the neuronal release of acetylcholine in a modulator-treated animal) these two elements together cause occurrence of a cycle of events: Binding of the modulator is limited in the absence of the agonist. When the agonist is released, it binds to the receptor, and induces desensitization, thereby enabling modulator binding. Modulator binding in turn traps the agonist within its binding site for a prolonged period of time. Once the agonist finally dissociated, the modulator can also dissociate without re-binding, and the receptor assumes its original resting conformation. In kinetic simulations this "trapped agonist cycle" mechanism did not require that the orthosteric and allosteric ligands symmetrically modify each other's affinity, only the modulator must decrease agonist accessibility, and the agonist must induce a conformation that is accessible to the modulator. This mechanism effectively prolongs and amplifies the effect of the agonist.

Kinetic properties and open probability of α7 nicotinic acetylcholine receptors.

The alpha7 nicotinic acetylcholine receptor (nAChR) has some peculiar kinetic properties. From the literature of α7 nAChR-mediated currents we concluded that experimentally measured kinetic properties reflected properties of the solution exchange system, rather than genuine kinetic properties of the receptors. We also concluded that all experimentally measured EC50 values for agonists must inherently be inaccurate. The aim of this study was to assess the undistorted kinetic properties of α7 nAChRs, and to construct an improved kinetic model, which can also serve as a basis of modeling the effect of the positive allosteric modulator PNU-120596, as it is described in the accompanying paper. Agonist-evoked currents were recorded from GH4C1 cells stably transfected with pCEP4/rat α7 nAChR using patch-clamp and fast solution exchange. We used two approaches to circumvent the problem of insufficient solution exchange rate: extrapolation and kinetic modeling. First, using different solution exchange rates we recorded evoked currents, and extrapolated their amplitude and kinetics to instantaneous solution exchange. Second, we constructed a kinetic model that reproduced concentration-dependence and solution exchange rate-dependence of receptors, and then we simulated receptor behavior at experimentally unattainably fast solution exchange. We also determined open probabilities during choline-evoked unmodulated and modulated currents using nonstationary fluctuation analysis. The peak open probability of 10 mM choline-evoked currents was 0.033 ± 0.006, while in the presence of choline (10 mM) and PNU-120596 (10 µM), it was increased to 0.599 ± 0.058. Our kinetic model could adequately reproduce low open probability, fast kinetics, fast recovery and solution exchange rate-dependent kinetics.