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The Journal of Neurophysiology Vol. 81 No. 3 March 1999, pp. 1418-1423
Copyright ©1999 by the American Physiological Society
RAPID COMMUNICATION
Department of Psychology, University of Connecticut, Storrs, Connecticut 06269
Gabel, Lisa A. and
Eric S. Nisenbaum.
Muscarinic
receptors differentially modulate the persistent potassium current in
striatal spiny projection neurons. Cholinergic regulation of
striatal spiny projection neuron activity is predominantly mediated
through muscarinic receptor modulation of several subclasses of ion
channels. Because of its critical role in governing the recurring
episodes of hyperpolarization and depolarization characteristic of
spiny neurons in vivo, the 4-aminopyridine-resistant, persistent potassium (K+) current, IKrp, would
be a strategic target for modulation. The present results show that
IKrp can be either suppressed or enhanced by
muscarinic receptor stimulation. Biophysical analysis demonstrated that
the depression of IKrp was associated with a
hyperpolarizing shift in the voltage dependence of inactivation and a
reduction in maximal conductance. By contrast, the enhancement of
IKrp was linked to hyperpolarizing shifts in
both activation and inactivation voltage dependencies. Viewed in the
context of the natural activity of spiny neurons, muscarinic depression
of IKrp should uniformly increase excitability
in both hyperpolarized and depolarized states. In the hyperpolarized
state, the reduction in maximal conductance should bolster the efficacy
of impending excitatory input. Likewise, in the depolarized state, the
decreased availability of IKrp produced by the
shift in inactivation should enhance ongoing synaptic input. The
alterations associated with enhancement of IKrp
are predicted to have a more dynamic influence on spiny cell
excitability. In the hyperpolarized state, the negative shift in
activation should increase the flow of IKrp and
attenuate subsequent excitatory synpatic input; whereas once the cell
has traversed into the depolarized state, the negative shift in
inactivation should reduce the availability of this current and
diminish its influence on the existing excitatory barrage.
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