Midbrain dopamine (DA) neurons fire in 2 characteristic modes, tonic and phasic, which are thought to modulate distinct aspects of behavior. However, the inability to selectively disrupt these patterns of activity has hampered the precise definition of the function of these modes of signaling. Here, we addressed the role of phasic DA in learning and other DA-dependent behaviors by attenuating DA neuron burst firing and subsequent DA release, without altering tonic neural activity. Disruption of phasic DA was achieved by selective genetic inactivation of NMDA-type, ionotropic glutamate receptors in DA neurons. Disruption of phasic DA neuron activity impaired the acquisition of numerous conditioned behavioral responses, and dramatically attenuated learning about cues that predicted rewarding and aversive events while leaving many other DA-dependent behaviors unaffected.cue-dependent learning ͉ mouse behavior ͉ electrophysiology ͉ cyclic voltammetry D opamine (DA) neurons of the ventral midbrain project to the dorsal and ventral striatum, as well as to other corticolimbic structures such as the hippocampus, amygdala, and prefrontal cortex. Differential DA release (tonic or phasic) is thought to activate distinct signal transduction cascades through the activation of postsynaptic inhibitory and excitatory G protein coupled receptors. Phasic DA is proposed to activate excitatory, low-affinity DA D1-like receptors (Rs) (1, 2) to facilitate long-term potentiation of excitatory synaptic transmission and enhance activity of the basal ganglia direct pathway facilitating appropriate action selection during goal-directed behavior. Conversely, tonic DA release is proposed to act on inhibitory, high-affinity DA D2Rs to facilitate long-term depression of cortico-striatal synapses and suppress activity of medium spiny neurons (MSNs) of the basal ganglia indirect pathway (1, 3-5). Thus, coordinate D1R and D2R activation modulates motor and cognitive function, and facilitates behavioral flexibility by a dichotomous control of striatal plasticity (5).During reinforcement learning shifts in phasic DA neuron responses from primary rewards, to reward predicting, stimuli are thought to reflect the acquisition of incentive salience for the predictive conditioned stimuli (6-10). Coincident DA and glutamate release onto MSNs during conditioned-stimulus response learning facilitates long-term potentiation of excitatory synapses that is thought to underlie reinforcement learning (1, 2, 11). Pharmacological or genetic disruption of D1R signaling impairs learning in numerous behavioral paradigms (2, 11); thus, phasic DA acting through D1R is thought to facilitate memory acquisition by ''stamping-in'' stimulus-response associations.Although considerable correlative electrophysiological evidence, as well as pharmacological and genetic evidence, supports an important role of phasic DA in stamping-in cue-reward associations, other evidence suggests that DA is not necessary for learning conditioned-stimulus responses. Mice genetically modified to...
Dopaminergic neurons of the ventral midbrain fire high frequency bursts when animals are presented with unexpected rewards, or stimuli that predict reward. To identify the afferents that can initiate bursting and establish therapeutic strategies for diseases affected by altered bursting, a mechanistic understanding of bursting is essential. Our results show that bursting is initiated by a specific interaction between the voltage sensitivity of NMDA receptors and voltage-gated ion channels, which result in the activation of an intrinsic, action potential-independent, high-frequency membrane potential oscillation. We further show that the NMDA receptor is uniquely suited for this because of the rapid kinetics and voltage dependence imparted to it by Mg2+ ion block and unblock. This mechanism explains the discrete nature of bursting in dopaminergic cells, and demonstrates how synaptic signals may be reshaped by local intrinsic properties of a neuron before influencing action potential generation.
SUMMARY Dorsal raphe (DR) serotonin neurons provide a major input to the ventral tegmental area (VTA). Here, we show that DR serotonin transporter (SERT) neurons establish both asymmetric and symmetric synapses on VTA dopamine neurons, but most of these synapses are asymmetric. Moreover, the DR-SERT terminals making asymmetric synapses on VTA dopamine neurons coexpress vesicular glutamate transporter 3 (VGluT3; transporter for accumulation of glutamate for its synaptic release), suggesting the excitatory nature of these synapses. VTA photoactivation of DR-SERT fibers promotes conditioned place preference, elicits excitatory currents on mesoaccumbens dopamine neurons, increases their firing, and evokes dopamine release in nucleus accumbens. These effects are blocked by VTA inactivation of glutamate and serotonin receptors, supporting the idea of glutamate release in VTA from dual DR SERT-VGluT3 inputs. Our findings suggest a path-specific input from DR serotonergic neurons to VTA that promotes reward by the release of glutamate and activation of mesoaccumbens dopamine neurons.
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