Linked Control of Syllable Sequence and Phonology in Birdsong

Wohlgemuth, Melville J.; Sober, Samuel J.; Brainard, Michael S.

doi:10.1523/jneurosci.2690-10.2010

Cited by 67 publications

(57 citation statements)

References 42 publications

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“…The presence of such a core representation is consistent with recordings in the motor pathway nucleus RA showing that similar populations of neurons are active during the production of a given syllable regardless of the sequence in which it is sung (Leonardo and Fee, 2005; Wohlgemuth et al, 2010). We hypothesize that this motor pathway representation is gradually modified in response to biasing signals from the AFP in a process of systems consolidation (Andalman and Fee, 2009; Fee and Goldberg, 2011; Warren et al, 2011).…”

Section: Discussionsupporting

confidence: 83%

“…Our results indicate that when it is optimal to generalize modifications across contexts - for example, during initial learning or in response to weakening of musculature or other perturbations that affect control of a syllable regardless of context - consistent biasing signals from the AFP will promote an updating of the core MP representation. In contrast, when context-specificity is appropriate - for example, to modify central commands in a manner that accounts for context-dependent dynamics of the musculoskeletal system (Bouchard and Chang, 2014; Ostry et al, 1996; Schmidt and Wild, 2014; Wohlgemuth et al, 2010) - conflicting biasing signals will interfere with consolidation, and learning will continue to rely on moment-by-moment modulation by the AFP. Such a dependence of consolidation on the coherence of AFP bias may therefore be a natural way for the nervous system to transfer modifications that are generally appropriate to primary motor circuitry, while reserving frontal, “executive” circuitry for dynamically adjusting performance in response to context-specific requirements (Duan et al, 2015; Hilario et al, 2012; Kim and Hikosaka, 2013; Miller and Cohen, 2001; Narayanan and Laubach, 2006).…”

Section: Discussionmentioning

confidence: 99%

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Discrete Circuits Support Generalized versus Context-Specific Vocal Learning in the Songbird

Tian

Brainard

2017

Neuron

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SUMMARY Motor skills depend on the reuse of individual gestures in multiple sequential contexts (e.g., a single phoneme in different words). Yet optimal performance requires that a given gesture be modified appropriately depending on the sequence in which it occurs. To investigate the neural architecture underlying such context-dependent modifications, we studied Bengalese finch song, a skill that, like speech, consists of variable sequences of “syllables.” We found that when birds are instructed to modify a syllable in one sequential context, learning generalizes across contexts; however, if unique instruction is provided in different contexts, learning is specific for each context. Using localized inactivation of a cortical-basal ganglia circuit specialized for song, we show this balance between generalization and specificity reflects a hierarchical organization of neural substrates. Primary motor circuitry encodes a “core” syllable representation that contributes to generalization, while top-down input from cortical-basal ganglia circuitry biases this representation to enable context-specific learning.

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Section: Discussionsupporting

confidence: 83%

Section: Discussionmentioning

confidence: 99%

Discrete Circuits Support Generalized versus Context-Specific Vocal Learning in the Songbird

Tian

Brainard

2017

Neuron

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“…Variable song sequences of the individual birds, composed according to finite-state type syntax (Okanoya, 2004), can be described using transition diagrams (Okanoya and Yamaguchi, 1997;Sakata and Brainard, 2006;Wohlgemuth et al, 2010). As illustrated in Figure 1 A, a transition diagram consists of a finite number of nodes (circles A-J) and node-connecting arrows that indicate the identities of syllables and the possible transition directions between syllables, respectively.…”

Section: Resultsmentioning

confidence: 99%

Neural Coding of Syntactic Structure in Learned Vocalizations in the Songbird

Fujimoto¹,

Hasegawa

Watanabe

2011

Journal of Neuroscience

113

116

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Although vocal signals including human languages are composed of a finite number of acoustic elements, complex and diverse vocal patterns can be created from combinations of these elements, linked together by syntactic rules. To enable such syntactic vocal behaviors, neural systems must extract the sequence patterns from auditory information and establish syntactic rules to generate motor commands for vocal organs. However, the neural basis of syntactic processing of learned vocal signals remains largely unknown. Here we report that the basal ganglia projecting premotor neurons (HVC X neurons) in Bengalese finches represent syntactic rules that generate variable song sequences. When vocalizing an alternative transition segment between song elements called syllables, sparse burst spikes of HVC X neurons code the identity of a specific syllable type or a specific transition direction among the alternative trajectories. When vocalizing a variable repetition sequence of the same syllable, HVC X neurons not only signal the initiation and termination of the repetition sequence but also indicate the progress and state-of-completeness of the repetition. These different types of syntactic information are frequently integrated within the activity of single HVC X neurons, suggesting that syntactic attributes of the individual neurons are not programmed as a basic cellular subtype in advance but acquired in the course of vocal learning and maturation. Furthermore, some auditory-vocal mirroring type HVC X neurons display transition selectivity in the auditory phase, much as they do in the vocal phase, suggesting that these songbirds may extract syntactic rules from auditory experience and apply them to form their own vocal behaviors.

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“…Neurons in HVC and RA show patterned activity during song production (reviewed in Fee et al, 2004;Hahnloser et al, 2002;McCasland, 1987;Ölveczky et al, 2011;Prather et al, 2008;Sober et al, 2008;Yu and Margoliash, 1996), and perturbations of activity in HVC and RA lead to acute vocal motor changes (Ashmore et al, 2005;Long et al, 2010;Vu et al, 1994;Wang et al, 2008). Of particular interest here is the finding that the activity of RA neurons, which project to brainstem nuclei that control vocal and respiratory musculature, encodes and controls the spectral composition of syllables (Ashmore et al, 2005;Leonardo and Fee, 2005;Sober et al, 2008;Vu et al, 1994;Wohlgemuth et al, 2010;Yu and Margoliash, 1996). For example, in adult Bengalese finches, variation in the premotor activity of RA neurons correlates with variation in the fundamental frequency of syllables (Sober et al, 2008).…”

Section: Mechanistic (Neurophysiological) Studies Of Vocal Consistencymentioning

confidence: 99%

Integrating perspectives on vocal performance and consistency

Sakata

Vehrencamp

2012

Journal of Experimental Biology

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SUMMARY Recent experiments in divergent fields of birdsong have revealed that vocal performance is important for reproductive success and under active control by distinct neural circuits. Vocal consistency, the degree to which the spectral properties (e.g. dominant or fundamental frequency) of song elements are produced consistently from rendition to rendition, has been highlighted as a biologically important aspect of vocal performance. Here, we synthesize functional, developmental and mechanistic (neurophysiological) perspectives to generate an integrated understanding of this facet of vocal performance. Behavioral studies in the field and laboratory have found that vocal consistency is affected by social context, season and development, and, moreover, positively correlated with reproductive success. Mechanistic investigations have revealed a contribution of forebrain and basal ganglia circuits and sex steroid hormones to the control of vocal consistency. Across behavioral, developmental and mechanistic studies, a convergent theme regarding the importance of vocal practice in juvenile and adult songbirds emerges, providing a basis for linking these levels of analysis. By understanding vocal consistency at these levels, we gain an appreciation for the various dimensions of song control and plasticity and argue that genes regulating the function of basal ganglia circuits and sex steroid hormones could be sculpted by sexual selection.

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Linked Control of Syllable Sequence and Phonology in Birdsong

Cited by 67 publications

References 42 publications

Discrete Circuits Support Generalized versus Context-Specific Vocal Learning in the Songbird

Discrete Circuits Support Generalized versus Context-Specific Vocal Learning in the Songbird

Neural Coding of Syntactic Structure in Learned Vocalizations in the Songbird

Integrating perspectives on vocal performance and consistency

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