6533b7d2fe1ef96bd125e130

RESEARCH PRODUCT

Origin of impulse initiation in the slowly adapting stretch receptor of the crayfish

subject

description

Characteristic for the crayfish stretch receptor is a gradual decrease in axon diameter up to a stretch of axon about 350 μm away from the soma-axon border. In response to depolarizing currents applied at different positions along the axon this stretch of axon can be localized as the most excitable membrane region. When depolarizing current steps of 10–25 nA intensity are injected into the soma the first impulse is always triggered in the soma (due to sudden rise in the membrane potential) while the second impulse originates at the axon region of highest escitability. As the intensity of the stimulus is increased the site of impulse initiation along the axon shifts nearer to the receptor soma. At a stimulus intensity of 50 nA the second impulse is suppressed and only the membrane potential at the axon hillock increases slightly. An analysis of the conductances for sodium and potassium ions as well as of the leakage current suggests that the molecular basis for the observed variations in excitability resides in a gradual decrease of the sodium conductance between the cell soma and the small-diameter region of the axon. However, the resting potential in this most excitable axon region is only some 3 mV more positive as compared to the receptor soma. A mathematical formulation is presented for the encoder mechanism in a soma-axon region with varying diameter. Using a slightly modified form of the Hodgkin-Huxley equations the experimentally observed changes in membrane potential and in the time course of the ionic currents can be adequately described by applying a nonlinear cable equation to the inhomogeneous axon.