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The Journal of Neurophysiology Vol. 86 No. 3 September 2001, pp. 1226-1236
Copyright ©2001 by the American Physiological Society
1Neuroscience Program and 2Department of Physiology and Biophysics, University of Miami School of Medicine, Miami, Florida 33136; and 3Department of Biological Sciences, Purdue University, West Lafayette, Indiana 47907
Baccus, Stephen A.,
Christie L. Sahley, and
Kenneth J. Muller.
Multiple Sites of Action Potential Initiation Increase
Neuronal Firing Rate. J. Neurophysiol. 86: 1226-1236, 2001. Sensory input to an individual interneuron or motoneuron
typically evokes activity at a single site, the initial segment, so
that firing rate reflects the balance of excitation and inhibition there. In a network of cells that are electrically coupled, a sensory
input produced by appropriate, localized stimulation can cause impulses
to be initiated in several places. An example in the leech is the chain
of S cells, which are critical for sensitization of reflex responses to
mechanosensory stimulation. S cells, one per segment, form an
electrically coupled chain extending the entire length of the CNS. Each
S cell receives input from mechanosensory neurons in that segment.
Because impulses can arise in any S cell and can reliably propagate
throughout the chain, all the S cells behave like a single neuron with
multiple initiation sites. In the present experiments, well-defined
stimuli applied to a small area of skin evoked mechanosensory action
potentials that propagated centrally to several segments, producing S
cell impulses in those segments. Following pressure to the skin,
impulses arose first in the S cell of the same segment as the stimulus,
followed by impulses in S cells in other segments. Often four or five
separate initiation sites were observed. This timing of impulse
initiation played an important role in increasing the frequency of
firing. Impulses arising at different sites did not usually collide but added to the total firing rate of the chain. A computational model is
presented to illustrate how mechanosensory neurons distribute the
effects of a single sensory stimulus into spatially and temporally separated synaptic input. The model predicts that changes in impulse propagation in mechanosensory neurons can alter S cell frequency of
firing by changing the number of initiation sites.
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