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The Journal of Neurophysiology Vol. 82 No. 4 October 1999, pp. 1855-1864
Copyright ©1999 by the American Physiological Society
- and Decreased 
-Oscillations in a Mouse
Deficient for a Potassium Channel Expressed in Fast-Spiking
Interneurons
1The Center for Basic Neuroscience and 2Department of Psychiatry, The University of Texas Southwestern Medical Center, Dallas, Texas 75235-9111
Joho, Rolf H.,
Chi Shun Ho, and
Gerald A. Marks.
Increased - and Decreased -Oscillations in a Mouse
Deficient for a Potassium Channel Expressed in Fast-Spiking
Interneurons. J. Neurophysiol. 82: 1855-1864, 1999. Kv3.1 is a voltage-gated, fast activating/deactivating potassium
(K+) channel with a high-threshold of activation and a
large unit conductance. Kv3.1 K+ channels are expressed in
fast-spiking, parvalbumin-containing interneurons in cortex,
hippocampus, striatum, the thalamic reticular nucleus (TRN), and in
several nuclei of the brain stem. A high density of Kv3.1 channels
contributes to short-duration action potentials, fast
afterhyperpolarizations, and brief refractory periods enhancing the
capability in these neurons for high-frequency firing. Kv3.1
K+ channel expression in the TRN and cortex also suggests a
role in thalamocortical and cortical function. Here we show that fast gamma and slow delta oscillations recorded from the somatomotor cortex
are altered in the freely behaving Kv3.1 mutant mouse. Electroencephalographic (EEG) recordings from homozygous
Kv3.1
/ mice show a three- to fourfold increase in both
absolute and relative spectral power in the gamma frequency range
(20-60 Hz). In contrast, Kv3.1-deficient mice have a 20-50%
reduction of power in the slow delta range (2-3 Hz). The increase in
gamma power is most prominent during waking in the 40- to 55-Hz range,
whereas the decrease in delta power occurs equally across all states of arousal. Our findings suggest that Kv3.1-expressing neurons are involved in the generation and maintenance of cortical fast gamma and
slow delta oscillations. Hence the Kv3.1-mutant mouse could serve as a
model to study the generation and maintenance of fast gamma and slow
delta rhythms and their involvement in behavior and cognition.
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