Contributions of COMT and DAT to regulation of phasic dopamine release and reward-guided behaviour

Fine temporal regulation of dopamine transmission is critical to its effects on behaviour. Dopamine can be cleared from the synapse either by recycling via the dopamine transporter (DAT) or by enzymatic degradation involving catechol-O-methyltransferase (COMT). DAT recycling predominates in striatum and contributes to dopaminergic regulation of reward-guided behaviour, while COMT degradation predominates in cortex and modulates executive functions. However, human functional imaging studies demonstrate interactive effects of DAT and COMT genotype, suggesting that the traditional division between DAT and COMT is not so clear-cut. Given the interdependence of mesolimbic and mesocortical circuitry and the presence of COMT in the striatum, it is possible that DAT and COMT interact to a greater extent than previously thought. We investigated the contributions of DAT and COMT to regulation of dopamine transmission and reward-guided behaviour by combining in vivo electrochemical recording, pharmacology, and behavioural testing in mice. Using fast scan cyclic voltammetry to record evoked dopamine release in anaesthetised animals, we found that systemic DAT blockade increased the size of dopamine transients in the nucleus accumbens (NAc) but not in the medial frontal cortex (MFC), demonstrating that DAT regulates phasic striatal dopamine release and confirming that DAT makes little contribution to regulation of cortical dopamine transmission. Unexpectedly, COMT inhibition did not affect evoked dopamine transients in either the NAc or the MFC. In agreement with these findings, systemic administration of a DAT blocker, but not of a COMT inhibitor, increased motivation to work for reward in a progressive ratio paradigm. COMT inhibition also had little effect on reinforcement learning (RL) strategies during reward-guided decision making. Intriguingly, however, we found that DAT blockade both decreased the influence of model-free RL and increased the influence of model-based RL on behaviour. Our study confirms that DAT regulates dopamine transmission in striatum but not in cortex and indicates that sub-second changes in dopamine transmission in both regions are largely insensitive to COMT. However, our behavioural data reveal the importance of striatal dopamine in multiple components of reward-guided behaviour, including both motivational aspects traditionally associated with striatum as well as cognitive aspects heretofore mainly associated with cortical function. Together, these findings emphasise that reward processing occurs across corticostriatal circuits and contribute to our understanding of how striatal dopamine transmission regulates reward-guided behaviours.</p

Mimicking synaptic effects of addictive drugs with selective dopamine neuron stimulation

The synaptic changes induced by initial drug exposure leave a trace on neural systems that can eventually manifest in compulsive drug-seeking behavior. A single injection of cocaine has been shown to induce a change in the AMPA receptor (AMPAR) subunit composition at glutamatergic synapses onto ventral tegmental area (VTA) dopamine (DA) neurons. This change is long-lasting (up to months following self-administration) and represents an important functional change at the synaptic level following cocaine use. We recently published findings that cocaine's action at the DA transporter (DAT) is necessary for the induction of AMPAR redistribution and that this can also be mimicked by selective DA neuron stimulation. The stimulation effect is dependent on D1 receptors within the VTA. Furthermore other addictive drugs, although they act through distinct mechanisms, also induce this synaptic change. Here we discuss literature that expands on these observations in an attempt to further clarify the synaptic changes following early drug use

Distinct roles for dopamine clearance mechanisms in regulating behavioral flexibility

Dopamine plays a crucial role in adaptive behavior, and dysfunctional dopamine is implicated in multiple psychiatric conditions characterized by inflexible or inconsistent choices. However, the precise relationship between dopamine and flexible decision making remains unclear. One reason is that, while many studies have focused on the activity of dopamine neurons, efficient dopamine signaling also relies on clearance mechanisms, notably the dopamine transporter (DAT), which predominates in striatum, and catechol-O-methyltransferase (COMT), which predominates in cortex. The exact locus, extent, and timescale of the effects of DAT and COMT are uncertain. Moreover, there is limited data on how acute disruption of either mechanism affects flexible decision making strategies mediated by cortico-striatal networks. To address these issues, we combined pharmacological modulation of DAT and COMT with electrochemistry and behavior in mice. DAT blockade, but not COMT inhibition, regulated sub-second dopamine release in the nucleus accumbens core, but surprisingly neither clearance mechanism affected evoked release in prelimbic cortex. This was not due to a lack of sensitivity, as both amphetamine and atomoxetine changed the kinetics of sub-second release. In a multi-step decision making task where mice had to respond to reversals in either reward probabilities or the choice sequence to reach the goal, DAT blockade selectively impaired, and COMT inhibition improved, performance after reward reversals, but neither manipulation affected the adaptation of choices after action-state transition reversals. Together, our data suggest that DAT and COMT shape specific aspects of behavioral flexibility by regulating different aspects of the kinetics of striatal and cortical dopamine, respectively

Silencing cortical activity during sound-localization training impairs auditory perceptual learning

The brain has a remarkable capacity to adapt to changes in sensory inputs and to learn from experience. However, the neural circuits responsible for this flexible processing remain poorly understood. Using optogenetic silencing of ArchT-expressing neurons in adult ferrets, we show that within-trial activity in primary auditory cortex (A1) is required for training-dependent recovery in sound-localization accuracy following monaural deprivation. Because localization accuracy under normal-hearing conditions was unaffected, this highlights a specific role for cortical activity in learning. A1-dependent plasticity appears to leave a memory trace that can be retrieved, facilitating adaptation during a second period of monaural deprivation. However, in ferrets in which learning was initially disrupted by perturbing A1 activity, subsequent optogenetic suppression during training no longer affected localization accuracy when one ear was occluded. After the initial learning phase, the reweighting of spatial cues that primarily underpins this plasticity may therefore occur in A1 target neurons

Data from: D2 dopamine receptor activation induces female preference for male song in the monogamous zebra finch

The evolutionary conservation of neural mechanisms for forming and maintaining pair bonds is unclear. Oxytocin, vasopressin, and dopamine (DA) transmitter systems have been shown to be important in pair-bond formation and maintenance in several vertebrate species. We examined the role of dopamine in formation of song preference in zebra finches, a monogamous bird. Male courtship song is an honest signal of sexual fitness; thus we measured female song preference to evaluate the role of DA in mate selection and pair-bond formation, using an operant conditioning paradigm. We found that DA acting through the D2 receptor, but not the D1 receptor, can induce a song preference in unpaired female finches and that blocking the D2 receptor abolished song preference in paired females. These results suggest that similar neural mechanisms for pair-bond formation are evolutionarily conserved in rodents and birds

Time-dependent assessment of stimulus-evoked regional dopamine release

To date, the spatiotemporal release of specific neurotransmitters at physiological levels in the human brain cannot be detected. Here, we present a method that relates minute-by-minute fluctuations of the positron emission tomography (PET) radioligand [11C]raclopride directly to subsecond dopamine release events. We show theoretically that synaptic dopamine release induces low frequency temporal variations of extrasynaptic extracellular dopamine levels, at time scales of one minute, that can evoke detectable temporal variations in the [11C] raclopride signal. Hence, dopaminergic activity can be monitored via temporal fluctuations in the [11C] raclopride PET signal. We validate this theory using fast-scan cyclic voltammetry and [11C] raclopride PET in mice during chemogenetic activation of dopaminergic neurons. We then apply the method to data from human subjects given a palatable milkshake and discover immediate and-for the first time-delayed food-induced dopamine release. This method enables time-dependent regional monitoring of stimulus-evoked dopamine release at physiological levels