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The Journal of Neurophysiology Vol. 87 No. 3 March 2002, pp. 1303-1310
Copyright ©2002 by the American Physiological Society
1Department of Neurology and Neurological Sciences, Stanford University Medical Center, Stanford, California 94305; and 2The Center for Basic Neuroscience, The University of Texas Southwestern Medical Center, Dallas, Texas 75235
Porcello, Darrell M.,
Chi Shun Ho,
Rolf H. Joho, and
John R. Huguenard.
Resilient RTN Fast Spiking in Kv3.1 Null Mice Suggests Redundancy
in the Action Potential Repolarization Mechanism. J. Neurophysiol. 87: 1303-1310, 2002. Fast spiking
(FS), GABAergic neurons of the reticular thalamic nucleus (RTN) are
capable of firing high-frequency trains of brief action potentials,
with little adaptation. Studies in recombinant systems have shown that
high-voltage-activated K+ channels containing the Kv3.1
and/or Kv3.2 subunits display biophysical properties that may
contribute to the FS phenotype. Given that RTN expresses high levels of
Kv3.1, with little or no Kv3.2, we tested whether this subunit was
required for the fast action potential repolarization mechanism
essential to the FS phenotype. Single- and multiple-action potentials
were recorded using whole-cell current clamp in RTN neurons from brain
slices of wild-type and Kv3.1-deficient mice. At 23°C, action
potentials recorded from homozygous Kv3.1 deficient mice
(Kv3.1
/) compared with their wild-type
(Kv3.1+/+) counterparts had reduced amplitudes (
6%) and
fast after-hyperpolarizations (16%). At 34°C, action potentials in
Kv3.1/ mice had increased duration (21%) due to a
reduced rate of repolarization (30%) when compared with wild-type
controls. Action potential trains in Kv3.1/ were
associated with a significantly greater spike decrement and broadening
and a diminished firing frequency versus injected current relationship
(F/I) at 34°C. There was no change in either spike
count or maximum instantaneous frequency during low-threshold Ca2+ bursts in Kv3.1/ RTN neurons at either
temperature tested. Our findings show that Kv3.1 is not solely
responsible for fast spikes or high-frequency firing in RTN neurons.
This suggests genetic redundancy in the system, possibly in the form of
other Kv3 members, which may suffice to maintain the FS phenotype in
RTN neurons in the absence of Kv3.1.
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