Nucleus Accumbens Neurons Are Innately Tuned for Rewarding and Aversive Taste Stimuli, Encode Their Predictors, and Are Linked to Motor Output

Rat nucleus accumbens neurons predominantly respond to the outcome-related properties of conditioned stimuli rather than their behavioral-switching properties.

It has been proposed that nucleus accumbens neurons respond to outcome (reward and punishment) and outcome-predictive information. Alternatively, it has been suggested that these neurons respond to salient stimuli, regardless of their outcome-predictive properties, to facilitate a switch in ongoing behavior. We recorded the activity of 82 single-nucleus accumbens neurons in thirsty rats respond...

Activation of nucleus accumbens NMDA receptors differentially affects appetitive or aversive taste learning and memory

Taste memory depends on motivational and post-ingestional consequences; thus, it can be aversive (e.g., conditioned taste aversion, CTA) if a novel, palatable taste is paired with visceral malaise, or it can be appetitive if no intoxication appears after novel taste consumption, and a taste preference is developed.The nucleus accumbens (NAc) plays a role in hedonic reactivity to taste stimuli, ...

Projection-Specific Modulation of Dopamine Neuron Synapses by Aversive and Rewarding Stimuli

Midbrain dopamine (DA) neurons are not homogeneous but differ in their molecular properties and responses to external stimuli. We examined whether the modulation of excitatory synapses on DA neurons by rewarding or aversive stimuli depends on the brain area to which these DA neurons project. We identified DA neuron subpopulations in slices after injection of "Retrobeads" into single target area...

Nucleus Accumbens Neurons Differentially Encode Information about Aversive Cues That Predict Cocaine Availability and Cocaine Self-administration following Extended Taste-drug Pairings

Aversive behavior induced by optogenetic inactivation of ventral tegmental area dopamine neurons is mediated by dopamine D2 receptors in the nucleus accumbens.

Dopamine (DA) transmission from the ventral tegmental area (VTA) is critical for controlling both rewarding and aversive behaviors. The transient silencing of DA neurons is one of the responses to aversive stimuli, but its consequences and neural mechanisms regarding aversive responses and learning have largely remained elusive. Here, we report that optogenetic inactivation of VTA DA neurons pr...