Metastable attractors explain the variable timing of stable behavioral action sequences
Natural animal behavior displays rich lexical and temporal dynamics, even in a stable environment. This implies that behavioral variability arises from sources within the brain, but the origin and mechanics of these processes remain largely unknown. Here, we focus on the observation that the timing...
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| creator | Recanatesi, Stefano Pereira, Ulises Murakami, Masayoshi Mainen, Zachary Mazzucato, Luca |
| description | Natural animal behavior displays rich lexical and temporal dynamics, even in
a stable environment. This implies that behavioral variability arises from
sources within the brain, but the origin and mechanics of these processes
remain largely unknown. Here, we focus on the observation that the timing of
self-initiated actions shows large variability even when they are executed in
stable, well-learned sequences. Could this mix of reliability and stochasticity
arise within the same circuit? We trained rats to perform a stereotyped
sequence of self-initiated actions and recorded neural ensemble activity in
secondary motor cortex (M2), which is known to reflect trial-by-trial action
timing fluctuations. Using hidden Markov models we established a robust and
accurate dictionary between ensemble activity patterns and actions. We then
showed that metastable attractors, representing activity patterns with the
requisite combination of reliable sequential structure and high transition
timing variability, could be produced by reciprocally coupling a high
dimensional recurrent network and a low dimensional feedforward one.
Transitions between attractors were generated by correlated variability arising
from the feedback loop between the two networks. This mechanism predicted a
specific structure of low-dimensional noise correlations that were empirically
verified in M2 ensemble dynamics. This work suggests a robust network motif as
a novel mechanism to support critical aspects of animal behavior and
establishes a framework for investigating its circuit origins via correlated
variability. |
| doi_str_mv | 10.48550/arxiv.2001.09600 |
| format | Article |
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a stable environment. This implies that behavioral variability arises from
sources within the brain, but the origin and mechanics of these processes
remain largely unknown. Here, we focus on the observation that the timing of
self-initiated actions shows large variability even when they are executed in
stable, well-learned sequences. Could this mix of reliability and stochasticity
arise within the same circuit? We trained rats to perform a stereotyped
sequence of self-initiated actions and recorded neural ensemble activity in
secondary motor cortex (M2), which is known to reflect trial-by-trial action
timing fluctuations. Using hidden Markov models we established a robust and
accurate dictionary between ensemble activity patterns and actions. We then
showed that metastable attractors, representing activity patterns with the
requisite combination of reliable sequential structure and high transition
timing variability, could be produced by reciprocally coupling a high
dimensional recurrent network and a low dimensional feedforward one.
Transitions between attractors were generated by correlated variability arising
from the feedback loop between the two networks. This mechanism predicted a
specific structure of low-dimensional noise correlations that were empirically
verified in M2 ensemble dynamics. This work suggests a robust network motif as
a novel mechanism to support critical aspects of animal behavior and
establishes a framework for investigating its circuit origins via correlated
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a stable environment. This implies that behavioral variability arises from
sources within the brain, but the origin and mechanics of these processes
remain largely unknown. Here, we focus on the observation that the timing of
self-initiated actions shows large variability even when they are executed in
stable, well-learned sequences. Could this mix of reliability and stochasticity
arise within the same circuit? We trained rats to perform a stereotyped
sequence of self-initiated actions and recorded neural ensemble activity in
secondary motor cortex (M2), which is known to reflect trial-by-trial action
timing fluctuations. Using hidden Markov models we established a robust and
accurate dictionary between ensemble activity patterns and actions. We then
showed that metastable attractors, representing activity patterns with the
requisite combination of reliable sequential structure and high transition
timing variability, could be produced by reciprocally coupling a high
dimensional recurrent network and a low dimensional feedforward one.
Transitions between attractors were generated by correlated variability arising
from the feedback loop between the two networks. This mechanism predicted a
specific structure of low-dimensional noise correlations that were empirically
verified in M2 ensemble dynamics. This work suggests a robust network motif as
a novel mechanism to support critical aspects of animal behavior and
establishes a framework for investigating its circuit origins via correlated
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a stable environment. This implies that behavioral variability arises from
sources within the brain, but the origin and mechanics of these processes
remain largely unknown. Here, we focus on the observation that the timing of
self-initiated actions shows large variability even when they are executed in
stable, well-learned sequences. Could this mix of reliability and stochasticity
arise within the same circuit? We trained rats to perform a stereotyped
sequence of self-initiated actions and recorded neural ensemble activity in
secondary motor cortex (M2), which is known to reflect trial-by-trial action
timing fluctuations. Using hidden Markov models we established a robust and
accurate dictionary between ensemble activity patterns and actions. We then
showed that metastable attractors, representing activity patterns with the
requisite combination of reliable sequential structure and high transition
timing variability, could be produced by reciprocally coupling a high
dimensional recurrent network and a low dimensional feedforward one.
Transitions between attractors were generated by correlated variability arising
from the feedback loop between the two networks. This mechanism predicted a
specific structure of low-dimensional noise correlations that were empirically
verified in M2 ensemble dynamics. This work suggests a robust network motif as
a novel mechanism to support critical aspects of animal behavior and
establishes a framework for investigating its circuit origins via correlated
variability.</abstract><doi>10.48550/arxiv.2001.09600</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Physics - Biological Physics Quantitative Biology - Neurons and Cognition |
| title | Metastable attractors explain the variable timing of stable behavioral action sequences |
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