Electrophysiological Characteristics of Classes of Neuron in the HVc of the Zebra Finch

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Electrophysiological Characteristics of Classes of Neuron in the HVc of the Zebra Finch

Michinori Kubota and Ikuo Taniguchi

Department of Neurophysiology, Medical Research Institute, Tokyo Medical and Dental University, Tokyo 101-0062, Japan

Kubota, Michinori and Ikuo Taniguchi. Electrophysiological characteristics of classes of neuron in the HVc of the zebrafinch. J. Neurophysiol. 80: 914-923, 1998. Whole cell recordingswere made from zebra finch HVc neurons in slice preparations.Four distinct classes of neuron were found on the basis of theirelectrophysiological properties. The morphological characteristicsof some of these neurons were also examined by intracellular injectionof Lucifer yellow. Type I neurons (21 of 65 cells) had longertime-to-peak of an afterhyperpolarization following an actionpotential than the other classes. They exhibited both fast andtime-dependent inward rectification and an initial high-frequencyfiring followed by a slower constant firing. Type I neurons hadlarge somata and thick dendrites with many spines. The axons ofsome of the neurons in this class projected in the direction ofarea X of the parolfactory lobe. Type II neurons (30 of 65 cells)had a more negative resting membrane potential than the otherclasses. They exhibited fast inward rectification. Type II neuronscould be divided into two subclasses by the absence (IIa; 22 cells)and the presence (IIb; 8 cells) of a low-threshold transient depolarization.Type IIa neurons had relatively small somata and thin, spiny dendrites.The axons of some of the neurons in this class projected in thedirection of the robust nucleus of the archistriatum (RA). TypeIIb neurons had relatively large somata and thick dendrites withmany spines. Type III neurons (6 of 65 cells) had a shorter action-potentialduration than the other classes. They exhibited prominent time-dependentinward rectification and a regular tonic firing with little orno accommodation. Type III neurons had beaded, aspiny dendrites.Type IV neurons (8 of 65 cells) had a longer action-potentialduration, a much larger input resistance, and longer membranetime constant than the other classes. Type IV neurons had smallsomata and thin, short, sparsely spiny dendrites. The axons ofsome of the neurons in this class projected in the direction ofthe RA. These classes of neuron may play distinct roles in songproduction and representation in the HVc.

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