Pheromone deactivation catalyzed by receptor molecules: a quantitative kinetic model.

Abstract

A quantitative model of pheromone-receptor interaction and pheromone deactivation, the supposed rate-limiting processes underlying the receptor potential kinetics, is worked out for the moth Antheraea poiyphemus. In this model, the pheromone interacts with the receptor molecule while bound to the reduced form of the pheromone binding protein. The receptor molecules—besides their receptor function—catalyze the observed shift of the pheromone-binding protein from the reduced to the oxidized form (Ziegelberger, G., Eur. J. Biochem., 232, 706–711, 1995), which deactivates the pheromone bound to pheromone binding protein. With the following parameters, the model fits morphological, radiometric, electrophysiological and biochemical data: a maximum estimate of 1.7 × 10⁷ receptor molecules/cell (with 40 000 units/μm² of receptor cell membrane), rate constants k₁ = 0.2/(s. μM) for the association, k₂ = 10/s for the dissociation of the ternary complex of binding protein, pheromone and receptor, and k₃ 10/s for the deactivation via the redox shift. With these parameters, the duration of elementary receptor potentials elicited by single pheromone molecules (∼50 ms) reflects the lifetime of the ternary complex, τ ≈ 1/(k₂ + k₃). The receptor occupancy produced by the model for threshold stimuli fits the sensitivity of the receptor cell to single pheromone molecules.