Disengagement of motor cortex from movement control during long-term learning

Hwang, Eun Jung; Dahlen, Jeffrey E.; Hu, Yvonne Yuling; Aguilar, Karina; Yu, Bin; Mukundan, Madan; Mitani, Akinori; Komiyama, Takaki

doi:10.1126/sciadv.aay0001

Cited by 75 publications

(103 citation statements)

References 40 publications

(59 reference statements)

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“…Second, because motor cortex plays less of a role in driving striatum as behaviors become highly practiced, lesioning, inactivating, or randomly perturbing activity in motor cortex during behavior should have a decreasingly small effect on the behavior the more that it has been trained (Figure 7b). This effect has in fact already been observed in very recent experiments using optogenetic inactivation throughout learning of a targeted forelimb task [48].…”

Section: Input Alignment and Control Transfer In The Two-pathway Modelsupporting

confidence: 53%

“…As described in the previous section, the transfer of control from corticostriatal to thalamostriatal inputs would suggest that motor cortex should be necessary for the initial learning of a behavior, but not for the production of the behavior after a sufficient amount of practice. Evidence for this has recently been found in studies using lesions [47] or inactivations [48] to test the involvement of motor cortex in rodents performing skilled forelimb tasks. In addition, studies of learned motor behaviors in humans have suggested that motor cortex becomes less involved in driving behaviors with practice [49,50], consistent with the proposed sensorimotor implementation of the two-pathway model.…”

Section: Input Alignment and Control Transfer In The Two-pathway Modelmentioning

confidence: 91%

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Remembrance of things practiced: Fast and slow learning in cortical and subcortical pathways

Murray

Escola

2019

Preprint

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The intertwined effects of recency and practice on memory and learned behavior have long been studied in psychology and neuroscience. We develop a bottom-up, mechanistic theory addressing the combined effects of recency and practice, beginning with a classical single-neuron model, then applying insights from this model to the network level. Combining error-based and associative learning, we mathematically derive the forgetting curve for a single neuron and its dependence on practiced repetition, showing how highly practiced memories or behaviors can become far more resistant to being overwritten by later learning. At the network level, error-based learning is responsible for initial gains in performance, while associative learning gradually transfers control of the downstream population from one input pathway to the other. We interpret the model neurobiologically by identifying the inputs as cortex and thalamus, and the downstream population as striatum, providing a framework for understanding the neural basis of habit formation and the automatization of behavior through practice.

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Section: Input Alignment and Control Transfer In The Two-pathway Modelsupporting

confidence: 53%

Section: Input Alignment and Control Transfer In The Two-pathway Modelmentioning

confidence: 91%

Remembrance of things practiced: Fast and slow learning in cortical and subcortical pathways

Murray

Escola

2019

Preprint

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“…For instance, skill learning, disease or trauma can induce experiencedependent changes in motor cortical representations, including expansions of motor maps that may reflect functional reorganization to support newly learned movements (Sanes and Donoghue, 2000;Li et al, 2001;Conner et al, 2005;Xu et al, 2009;Makino et al, 2016;Peters et al, 2017;Papale and Hooks, 2018). Moreover, while the necessity of motor cortex for performance of learned skills can vary depending on factors such as the level of dexterity required or the amount of time spent training, motor cortex is required for the acquisition of new motor skills across a variety of movements and training paradigms (Whishaw et al, 1991;Whishaw, 2000;Darling et al, 2011;Guo et al, 2015;Kawai et al, 2015;Hwang et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Multi-dimensional tuning in motor cortical neurons during active behavior

Yuan

Bottjer

2020

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A region within songbird cortex, AId (dorsal intermediate arcopallium), is functionally analogous to motor cortex in mammals and has been implicated in vocal learning during development. AId thus serves as a powerful model for investigating motor cortical contributions to developmental skill learning. We made extracellular recordings in AId of freely behaving juvenile zebra finches and evaluated neural activity during diverse motor behaviors throughout entire recording sessions, including song production as well as hopping, pecking, preening, fluffups, beak interactions with cage objects, scratching, and stretching. A large population of single neurons showed significant modulation of activity during singing relative to quiescence. In addition, AId neurons demonstrated heterogeneous response patterns that were evoked during multiple movements, with single neurons often demonstrating excitation during one movement type and suppression during another. Lesions of AId do not disrupt vocal motor output or impair generic movements, suggesting that the responses observed during active behavior do not reflect direct motor drive. Consistent with this idea, we found that some AId neurons showed differential activity during pecking movements depending on the context in which pecks occurred, suggesting that AId circuitry encodes diverse inputs beyond generic motor parameters.Moreover, we found evidence of neurons that did not respond during discrete movements but were nonetheless modulated during active behavioral states compared to quiescence. Taken together, our results support the idea that AId neurons are involved in sensorimotor integration of external sensory inputs and/or internal feedback cues to help modulate goal-directed behaviors. SIGNIFICANCE STATEMENTMotor cortex across taxa receives highly integrated, multi-modal information and has been implicated in both execution and acquisition of complex motor skills, yet studies of motor cortex typically employ restricted behavioral paradigms that target select movement parameters, preventing wider assessment of the diverse sensorimotor factors that can affect motor cortical activity. Recording in AId of freely behaving juvenile songbirds that are actively engaged in sensorimotor learning offers unique advantages for elucidating the functional role of motor cortical neurons. The results demonstrate that a diverse array of factors modulate motor cortical activity and lay important groundwork for future investigations of how multi-modal information is integrated in motor cortical regions to contribute to learning and execution of complex motor skills.3

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“…Within the context of motor control, our findings also encourage to study the role of areas found to be active during movement (such as the visual areas) commonly disregarded in the association to forelimb movement, at the cellular-level (Galiñanes et al, 2018, Karandell and Huber, 2017, Ebina et al, 2018). In the future, it would also be relevant to assess the neocortical dynamics during RtG in a freely moving condition or during performance refinement, considering that cortical areas undergo functional reorganization during learning (Makino et al, 2017; Whishaw et al, 2017; Bollu et al, 2019; Hwang et al, 2019). In sum, our investigation identified a global network of neocortical area associated to successful RtG execution.…”

Section: Discussionmentioning

confidence: 99%

A distributed neocortical action map associated with reach-to-grasp

Quarta

Scaglione

Lucchesi

et al. 2020

Preprint

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Reach-to-Grasp (RtG) is known to be dependent upon neocortical circuits and extensive research has provided insights into how selected neocortical areas contribute to control dexterous movements. Surprisingly, little infor-mation is available on the global neocortical computations underlying RtG in the mouse. Here, we characterized, employing fluorescence wide-field cal-cium imaging, the neocortex-wide dynamics from mice engaging in a RtG task. We demonstrate that, beyond canonical motor regions, several areas, such as the visual and the retrosplenial cortices, also increase their activ-ity levels during successful RtGs. Intriguingly, homologous regions across the ipsilateral hemisphere are also involved. Functional connectivity among areas increases transiently from rest to planning, and decreases during move-ment. Two anti-correlated neocortical networks emerged during movement. At variance, neural activity levels scale linearly with kinematics measures of successful RtGs in secondary motor areas. Our findings establish the coex-istence of distributed and localized neocortical dynamics for efficient control of complex movements.SIGNIFICANCE STATEMENTIn mammals, including humans, the cerebral cortex is known to be critical for the correct execution of dexterous movements. Despite the importance of the mouse for elucidating the neural circuitry for motor control, its neocortex-wide dynamics during RtG are largely unexplored. We used in-vivo fluores-cence microscopy to characterize the neural activity across the neocortex as mice performed a reach-to-grasp task. We show that for such complex movements, a large network of neocortical areas gets involved, while movement kinematics correlates with neural activity in secondary motor areas. These findings indicate the coexistence, at the mesoscale level, of distributed and localized neocortical dynamics for the execution of fine movements. This study offers a novel view on the neocortical correlates of motor control, with potential implications for neural repair.

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Disengagement of motor cortex from movement control during long-term learning

Cited by 75 publications

References 40 publications

Remembrance of things practiced: Fast and slow learning in cortical and subcortical pathways

Remembrance of things practiced: Fast and slow learning in cortical and subcortical pathways

Multi-dimensional tuning in motor cortical neurons during active behavior

A distributed neocortical action map associated with reach-to-grasp

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