Tao Yang scite author profile

The basolateral amygdala (BLA) plays essential roles in behaviors motivated by stimuli with either positive or negative valence, but how it processes motivationally opposing information and participates in establishing valence-specific behaviors remains unclear. Here, by targeting Fezf2 -expressing neurons in the BLA, we identify and characterize two functionally distinct classes in behaving mice, the negative-valence neurons and positive-valence neurons, which innately represent aversive and rewarding stimuli, respectively, and through learning acquire predictive responses that are essential for punishment avoidance or reward seeking. Notably, these two classes of neurons receive inputs from separate sets of sensory and limbic areas, and convey punishment and reward information through projections to the nucleus accumbens and olfactory tubercle, respectively, to drive negative and positive reinforcement. Thus, valence-specific BLA neurons are wired with distinctive input/output structures, forming a circuit framework that supports BLA’s roles in encoding, learning and executing valence-specific motivated behaviors.

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A Genetically Defined Compartmentalized Striatal Direct Pathway for Negative Reinforcement

Xiao

Deng

Furlan

et al. 2020

Cell

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A genetically defined insula-brainstem circuit selectively controls motivational vigor

Deng¹,

Xiao²,

Yang³

et al. 2021

Cell

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Plastic and stimulus-specific coding of salient events in the central amygdala

Yang

Zhang

et al. 2023

Nature

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Prefrontal top-down projections control context-dependent strategy selection

Gschwend

Yang

Lisdonk

et al. 2021

Preprint

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The rules governing behavior often vary with behavioral contexts. As a consequence, an action rewarded in one context may be discouraged in another. Animals and humans are capable of switching between behavioral strategies under different contexts and acting adaptively according to the variable rules, a flexibility that is thought to be mediated by the prefrontal cortex (PFC)1–4. However, how the PFC orchestrates context-dependent switch of strategies remains unclear. Here we show that pathway-specific projection neurons in the medial PFC (mPFC) differentially contribute to context-instructed strategy selection. In a decision-making task in which mice have been trained to flexibly switch between a previously established rule and a newly learned rule in a context-dependent manner, the activity of mPFC neurons projecting to the dorsomedial striatum encodes the contexts, and further represents decision strategies conforming to the old and new rules. Moreover, the activity of these neuron is required for context-instructed strategy selection. In contrast, the activity of mPFC neurons projecting to the ventral midline thalamus does not discriminate between the contexts, and represents the old rule even if mice have adopted the new one; furthermore, these neurons act to prevent the strategy switch under the new rule. Our results suggest that the mPFC→striatum pathway promotes flexible strategy selection guided by contexts, whereas the mPFC→thalamus pathway favors fixed strategy selection by preserving old rules. Balanced activity between the two pathways may be critical for adaptive behaviors.

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Tao Yang

Genetically identified amygdala–striatal circuits for valence-specific behaviors

A Genetically Defined Compartmentalized Striatal Direct Pathway for Negative Reinforcement

A genetically defined insula-brainstem circuit selectively controls motivational vigor

Plastic and stimulus-specific coding of salient events in the central amygdala

Prefrontal top-down projections control context-dependent strategy selection

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