Sleep-Related Neural Activity in a Premotor and a Basal-Ganglia Pathway of the Songbird

doi:10.1152/jn.01064.2005

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Sleep-Related Neural Activity in a Premotor and a Basal-Ganglia Pathway of the Songbird

Richard H. R. Hahnloser¹^,2, Alexay A. Kozhevnikov²^,3 and Michale S. Fee²^,3

¹Institute for Neuroinformatics University of Zurich/Swiss Federal Institute of Technology, Zurich, Switzerland; ²Bell Labs, Lucent Technologies, Murray Hill, New Jersey; and ³McGovern Institute for Brain Research, Massachusetts Institute of Technology, Cambridge, Massachusetts

Submitted 11 October 2005; accepted in final form 15 February 2006

During singing, neurons in premotor nucleus RA (robust nucleusof the arcopallium) of the zebra finch produce complex temporalsequences of bursts that are recapitulated during sleep. RAreceives input from nucleus HVC via the premotor pathway, andalso from the lateral magnocellular nucleus of the anteriornidopallium (LMAN), part of a basal ganglia-related circuitessential for vocal learning. We explore the propagation ofsleep-related spike patterns in these two pathways and theirinfluences on RA activity. We promote sleep in head-fixed birdsby injections of melatonin and make single-neuron recordingsfrom the three major classes of neurons in HVC: RA-projectingneurons, Area X-projecting neurons, and interneurons. We alsorecord LMAN neurons that project to RA. In paired recordings,spike trains from identified HVC neuron types are strongly coherentwith spike trains in RA neurons, whereas LMAN projection neuronson average exhibit only a weak coherency with neurons in HVCand RA. We further examine the relative roles of HVC and LMANin generating RA burst sequences with reversible inactivation.Lidocaine inactivation of HVC completely abolishes burstingin RA, whereas inactivation of LMAN has no effect on burst ratesin RA. In combination, our data suggest that in adult birds,RA burst sequences in sleep are driven via the premotor pathwayfrom HVC. We present a simple generative model of spike trainsin HVC, RA, and LMAN neurons that is able to qualitatively reproduceobserved coherency functions. We propose that commonly observedcoherency peaks at positive and negative time lags are causedby sequentially correlated HVC activity.

Address for reprint requests and other correspondence: R.H.R. Hahnloser, Institute for Neuroinformatics UNIZH/ETHZ, Winterthurerstrasse 190, 8057 Zurich, Switzerland (E-mail: rich{at}ini.phys.ethz.ch)

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