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Cited 8 time in webofscience Cited 9 time in scopus
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Corticobasal ganglia projecting neurons are required for juvenile vocal learning but not for adult vocal plasticity in songbirds

Authors
Sanchez-Valpuesta, MiguelSuzuki, YumenoShibata, YukinoToji, NoriyukiJi, YuAfrin, NasibaAsogwa, Chinweike NormanKojima, IppeiMizuguchi, DaisukeKojima, SatoshiOkanoya, KazuoOkado, HaruoKobayashi, KentaWada, Kazuhiro
Issue Date
Nov-2019
Publisher
NATL ACAD SCIENCES
Keywords
critical period; sensorimotor learning; time-locked firing; zebra finch; sensory feedback
Citation
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA, v.116, no.45, pp.22833 - 22843
Journal Title
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA
Volume
116
Number
45
Start Page
22833
End Page
22843
URI
http://scholarworks.bwise.kr/kbri/handle/2023.sw.kbri/661
DOI
10.1073/pnas.1913575116
ISSN
0027-8424
Abstract
Birdsong, like human speech, consists of a sequence of temporally precise movements acquired through vocal learning. The learning of such sequential vocalizations depends on the neural function of the motor cortex and basal ganglia. However, it is unknown how the connections between cortical and basal ganglia components contribute to vocal motor skill learning, as mammalian motor cortices serve multiple types of motor action and most experimentally tractable animals do not exhibit vocal learning. Here, we leveraged the zebra finch, a songbird, as an animal model to explore the function of the connectivity between cortex-like (HVC) and basal ganglia (area X), connected by HVC(x) projection neurons with temporally precise firing during singing. By specifically ablating HVC(x) neurons, juvenile zebra finches failed to copy tutored syllable acoustics and developed temporally unstable songs with less sequence consistency. In contrast, HVC(x) -ablated adults did not alter their learned song structure, but generated acoustic fluctuations and responded to auditory feedback disruption by the introduction of song deterioration, as did normal adults. These results indicate that the corticobasal ganglia input is important for learning the acoustic and temporal aspects of song structure, but not for generating vocal fluctuations that contribute to the maintenance of an already learned vocal pattern.
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연구본부 (감각·운동시스템 연구그룹)
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