An Associational Model of Birdsong Sensorimotor Learning II. Temporal Hierarchies and the Learning of Song Sequence

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An Associational Model of Birdsong Sensorimotor Learning II. Temporal Hierarchies and the Learning of Song Sequence

Todd W. Troyer¹^,³ and Allison J. Doupe¹^,²^,³^,⁴

¹Department of Psychiatry, ²Department of Physiology, ³W. M. Keck Center for Integrative Neuroscience, and ⁴Sloan Center for Theoretical Neurobiology at UCSF, University of California, San Francisco, California 94143-0444

Troyer, Todd W. and Allison J. Doupe. An Associational Model of Birdsong Sensorimotor Learning II. Temporal Hierarchies and the Learning of Song Sequence. J. Neurophysiol. 84: 1224-1239, 2000. Understanding the neural mechanisms underlying serially ordered behavior is a fundamental problem in motor learning. We presenta computational model of sensorimotor learning in songbirds thatis constrained by the known functional anatomy of the song circuit.The model subsumes our companion model for learning individualsong "syllables" and relies on the same underlying assumptions.The extended model addresses the problem of learning to producesyllables in the correct sequence. Central to our approach isthe hypothesis that the Anterior Forebrain Pathway (AFP) producessignals related to the comparison of the bird's own vocalizationsand a previously memorized "template." This "AFP comparison hypothesis"is challenged by the lack of a direct projection from the AFPto the song nucleus HVc, a candidate site for the generator ofsong sequence. We propose that sequence generation in HVc resultsfrom an associative chain of motor and sensory representations(motor $right-arrow$ sensory $right-arrow$ next motor ... ) encoded within the two knownpopulations of HVc projection neurons. The sensory link in thechain is provided, not by auditory feedback, but by a centrallygenerated efference copy that serves as an internal predictionof this feedback. The use of efference copy as a substitute forthe sensory signal explains the ability of adult birds to producenormal song immediately after deafening. We also predict thatthe AFP guides sequence learning by biasing motor activity innucleus RA, the premotor nucleus downstream of HVc. Associativelearning then remaps the output of the HVc sequence generator.By altering the motor pathway in RA, the AFP alters the correspondencebetween HVc motor commands and the resulting sensory feedbackand triggers renewed efference copy learning in HVc. Thus, auditoryfeedback-mediated efference copy learning provides an indirectpathway by which the AFP can influence sequence generation inHVc. The model makes predictions concerning the role played byspecific neural populations during the sensorimotor phase of songlearning and demonstrates how simple rules of associational plasticitycan contribute to the learning of a complex behavior on multipletimescales.

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