Primary food reward and reward‐predictive stimuli evoke different patterns of phasic dopamine signaling throughout the striatum
Phasic changes in dopamine activity play a critical role in learning and goal-directed behavior. Unpredicted reward and reward predictive cues evoke phasic increases in the firing rate of the majority of midbrain dopamine neurons – results that predict uniformly broadcast increases in dopamine concentration throughout the striatum. However, measurement of dopamine concentration changes during reward has cast doubt on this prediction. We systematically measured phasic changes in dopamine in four striatal subregions (nucleus accumbens shell (Shell) and core (Core), dorsomedial (DMS) and dorsolateral striatum (DLS)) in response to stimuli known to activate a majority of dopamine neurons. We used fast-scan cyclic voltammetry in awake and behaving rats, which measures changes in dopamine on a similar timescale to the electrophysiological recordings that established a relationship between phasic dopamine activity and reward. Unlike the responses of midbrain dopamine neurons, unpredicted food reward and reward-predictive cues evoked a phasic increase in dopamine that was subregion specific. In rats with limited experience, unpredicted food reward evoked an increase exclusively in the Core. In rats trained on a discriminative stimulus paradigm, both unpredicted reward and reward-predictive cues evoked robust phasic dopamine in the Core and DMS. Thus, phasic dopamine release in select target structures is dynamic and dependent on context and experience. Since the four subregions assayed receive different inputs and have differential projection targets, the regional selectivity of phasic changes in dopamine has important implications for information flow through the striatum and plasticity that underlies learning and goal-directed behavior.
Brief, high-concentration (phasic) spikes in nucleus accumbens dopamine critically participate in aspects of food reward. Although physiological state (e.g., hunger, satiety) and associated hormones are known to affect dopamine tone in general, whether they modulate food-evoked, phasic dopamine specifically is unknown. Here, we used fast-scan cyclic voltammetry in awake, behaving rats to record dopamine spikes evoked by delivery of sugar pellets while pharmacologically manipulating central receptors for the gut "hunger" hormone ghrelin. Lateral ventricular (LV) ghrelin increased, while LV ghrelin receptor antagonism suppressed the magnitude of dopamine spikes evoked by food. Ghrelin was effective when infused directly into the lateral hypothalamus (LH), but not the ventral tegmental area (VTA). LH infusions were made in close proximity to orexin neurons, which are regulated by ghrelin and project to the VTA. Thus, we also investigated and found potentiation of food-evoked dopamine spikes by intra-VTA orexin-A. Importantly, intra-VTA blockade of orexin receptors attenuated food intake induced by LV ghrelin, thus establishing a behaviorally relevant connection between central ghrelin and VTA orexin. Further analysis revealed that food restriction increased the magnitude of dopamine spikes evoked by food independent of any pharmacological manipulations. The results support the regulation of food-evoked dopamine spikes by physiological state with endogenous fluctuations in ghrelin as a key contributor. Our data highlight a novel mechanism by which signals relating physiological state could influence food reinforcement and food-directed behavior.
Dopamine neurons are classically known to modulate locomotion indirectly through ascending projections to the basal ganglia that project down to brainstem locomotor networks. Their loss in Parkinson's disease is devastating. In lampreys, we recently showed that brainstem networks also receive direct descending dopaminergic inputs that potentiate locomotor output. Here, we provide evidence that this descending dopaminergic pathway is conserved to higher vertebrates, including mammals. In salamanders, dopamine neurons projecting to the striatum or brainstem locomotor networks were partly intermingled. Stimulation of the dopaminergic region evoked dopamine release in brainstem locomotor networks and concurrent reticulospinal activity. In rats, some dopamine neurons projecting to the striatum also innervated the pedunculopontine nucleus, a known locomotor center, and stimulation of the dopaminergic region evoked pedunculopontine dopamine release in vivo. Finally, we found dopaminergic fibers in the human pedunculopontine nucleus. The conservation of a descending dopaminergic pathway across vertebrates warrants re-evaluating dopamine's role in locomotion.D opaminergic neurons represent a vital neuromodulatory component essential for vertebrate motor control, and their loss in neurodegenerative disease is devastating. The meso-diencephalic dopamine (DA) neurons are known to provide ascending projections to the basal ganglia, which, in turn, provide input to cortical structure in mammals but also project caudally to the mesencephalic locomotor region (MLR), a highly conserved structure that controls locomotion in all vertebrates investigated to date (1-7; for review, see ref. 8). A growing body of evidence supports the view that basal ganglia connectivity is highly conserved among vertebrates, from lampreys to mammals (9-11; for review, see ref. 12), with some interspecies differences recently highlighted (13). As such, the homology between DA cell populations remains to be resolved in vertebrates. As a general rule, DA neurons from the meso-diencephalon send projections to the striatum in all vertebrates. In lampreys and teleosts, those neurons are located only in the diencephalon (posterior tuberculum), but in tetrapods and cartilaginous fishes (14) they are located in both the diencephalon and the mesencephalon. An increasing number of authors seem to agree with the hypothesis that at least some of the mesodiencephalic DA neurons located in the diencephalon are homologous in all vertebrates, and thus, homologous to at least a portion of the mammalian substantia nigra pars compacta (SNc)/ ventral tegmental area (VTA) (13, 15-19; for review, see ref. 20). Alternatively, it was suggested that the posterior tuberculum DA neurons projecting to the striatum in zebrafish are homologs of the mammalian DA neurons of the A11 group (21). This will be discussed below in light of the results of the present study.In lampreys, only a few meso-diencephalic DA neurons send ascending projections to the striatum (9, 22); the majority ...
Phasic dopamine signaling participates in associative learning by reinforcing associations between outcomes (unconditioned stimulus; US) and their predictors (conditioned stimulus; CS). However, prior work has always engendered these associations with innately rewarding stimuli. Thus, whether dopamine neurons can acquire prediction signals in the absence of appetitive experience and update them when the value of the outcome changes remains unknown. Here, we used sodium depletion to reversibly manipulate the appetitive value of a hypertonic sodium solution while measuring phasic dopamine signaling in rat nucleus accumbens. Dopamine responses to the NaCl US following sodium depletion updated independent of prior experience. In contrast, prediction signals were only acquired through extensive experience with a US that had positive affective value. Once learned, dopamine prediction signals were flexibly expressed in a state-dependent manner. Our results reveal striking differences with respect to how physiological state shapes dopamine signals evoked by outcomes and their predictors.nucleus accumbens | dopamine | voltammetry | learning | motivation R econciling differences between anticipated and experienced outcomes is fundamental for how an organism learns about the world. A key component of temporal difference (TD) learning models is the reward prediction error (RPE) term (1, 2), which is thought to be represented by phasic activity of midbrain dopamine neurons (3-5). Indeed, conditioned stimulus (CS)-related dopamine activity correlates with multiple behavioral indices of learning (6-8), and phasic dopamine signaling is sufficient to drive CSunconditioned stimulus (US) learning (9).In much of the supportive empirical work, food-or fluidrestricted animals first experience and then learn to anticipate an innately appetitive US (e.g., sucrose, juice, water). Thus, the US always has an inherent caloric, nutritive, or positive affective value to the organism. Consequently, it is uncertain whether dopamine neurons can acquire CS-US associations without first experiencing the US as a reward. Resolving this question is critical, because the striatal underpinnings of goal-directed behavior may encompass both RPE and experience-independent, model-based strategies (10, 11). One way to delineate dopamine's role in these different learning strategies would be to promote associations between a CS and a neutral or normally avoided US whose affective value could be manipulated and then determine the experience dependency of dopamine CS responses.Sodium appetite is an ideal platform on which to address this question. Sodium depletion induces a powerful sodium hunger and radically but reversibly alters the rewarding value of hypertonic NaCl solutions (12, 13). The appetite is highly selective for sodium and manifests independent of prior experience with either sodium solutions or sodium deficiency (14, 15). Therefore, sodium appetite facilitates the delivery of a US (hypertonic NaCl) that is rewarding only in a specific physiolog...
Amylin acts in the CNS to reduce feeding and body weight. Recently, the ventral tegmental area (VTA), a mesolimbic nucleus important for food intake and reward, was identified as a site-of-action mediating the anorectic effects of amylin. However, the long-term physiological relevance and mechanisms mediating the intake-suppressive effects of VTA amylin receptor (AmyR) activation are unknown. Data show that the core component of the AmyR, the calcitonin receptor (CTR), is expressed on VTA dopamine (DA) neurons and that activation of VTA AmyRs reduces phasic DA in the nucleus accumbens core (NAcC). Suppression in NAcC DA mediates VTA amylin-induced hypophagia, as combined NAcC D1/D2 receptor agonists block the intake-suppressive effects of VTA AmyR activation. Knockdown of VTA CTR via adeno-associated virus short hairpin RNA resulted in hyperphagia and exacerbated body weight gain in rats maintained on high-fat diet. Collectively, these findings show that VTA AmyR signaling controls energy balance by modulating mesolimbic DA signaling.
The reinstatement of ethanol (EtOH)-seeking induced by an EtOH-predictive light-tone stimulus is enhanced in an environment associated with prior EtOH self-administration (SA) compared with a context associated with EtOH unavailability (Tsiang & Janak, 2006). Here we hypothesized that EtOH-seeking would be elicited by the conditioned sensory stimulus properties of EtOH and that this reinstatement would be similarly modulated by context. We also determined whether pharmacologically inactivating the nucleus accumbens (NAc), a key structure in relapse circuitry, would attenuate reinstated EtOH-seeking. Rats lever-pressed for oral EtOH (10% v/v) in operant conditioning chambers distinguished by specific visual, olfactory and tactile stimuli. Responding was then extinguished by withholding EtOH in a different context. EtOH-seeking, expressed as elevated responding without EtOH delivery, was subsequently tested by presenting an oral EtOH prime (two aliquots of 0.1 mL EtOH) in either the extinction or the prior EtOH-SA context. Rats received a microinfusion (0.3 μL/hemisphere) of saline or GABA agonists (muscimol/baclofen) into the NAc core or shell immediately before the reinstatement test. Robust EtOH-seeking was observed in the prior EtOH-SA but not the extinction context in saline-pretreated rats. This effect was significantly attenuated by inactivating the NAc core but not shell. Conversely, NAc shell inactivation significantly elevated lever-pressing in the extinction context. These data suggest that the sensory stimulus properties of oral EtOH can reinstate EtOH-seeking when experienced in the appropriate context and that functional activity in the NAc core is required for this effect. In contrast, the shell may normally inhibit incorrect behavioral responses.
The development of diet-induced obesity (DIO) can potently alter multiple aspects of dopamine signaling, including dopamine transporter (DAT) expression and dopamine reuptake. However, the time-course of diet-induced changes in DAT expression and function and whether such changes are dependent upon the development of DIO remains unresolved. Here, we fed rats a high (HFD) or low (LFD) fat diet for 2 or 6 weeks. Following diet exposure, rats were anesthetized with urethane and striatal DAT function was assessed by electrically stimulating the dopamine cell bodies in the ventral tegmental area (VTA) and recording resultant changes in dopamine concentration in the ventral striatum using fast-scan cyclic voltammetry. We also quantified the effect of HFD on membrane associated DAT in striatal cell fractions from a separate group of rats following exposure to the same diet protocol. Notably, none of our treatment groups differed in body weight. We found a deficit in the rate of dopamine reuptake in HFD rats relative to LFD rats after 6 but not 2 weeks of diet exposure. Additionally, the increase in evoked dopamine following a pharmacological challenge of cocaine was significantly attenuated in HFD relative to LFD rats. Western blot analysis revealed that there was no effect of diet on total DAT protein. However, 6 weeks of HFD exposure significantly reduced the 50 kDa DAT isoform in a synaptosomal membrane-associated fraction, but not in a fraction associated with recycling endosomes. Our data provide further evidence for diet-induced alterations in dopamine reuptake independent of changes in DAT production and demonstrates that such changes can manifest without the development of DIO.
The contribution of dopamine (DA) to locomotor control is traditionally attributed to ascending dopaminergic projections from the substantia nigra pars compacta and the ventral tegmental area to the basal ganglia, which in turn project down to the mesencephalic locomotor region (MLR), a brainstem region controlling locomotion in vertebrates. However, a dopaminergic innervation of the pedunculopontine nucleus, considered part of the MLR, was recently identified in the monkey. The origin and role of this dopaminergic input are unknown. We addressed these questions in a basal vertebrate, the lamprey. Here we report a functional descending dopaminergic pathway from the posterior tuberculum (PT; homologous to the substantia nigra pars compacta and/or ventral tegmental area of mammals) to the MLR. By using triple labeling, we found that dopaminergic cells from the PT not only project an ascending pathway to the striatum, but send a descending projection to the MLR. In an isolated brain preparation, PT stimulation elicited excitatory synaptic inputs into patch-clamped MLR cells, accompanied by activity in reticulospinal cells. By using voltammetry coupled with electrophysiological recordings, we demonstrate that PT stimulation evoked DA release in the MLR, together with the activation of reticulospinal cells. In a semi-intact preparation, stimulation of the PT elicited reticulospinal activity together with locomotor movements. Microinjections of a D1 antagonist in the MLR decreased the locomotor output elicited by PT stimulation, whereas injection of DA had an opposite effect. It appears that this descending dopaminergic pathway has a modulatory role on MLR cells that are known to receive glutamatergic projections and promotes locomotor output.motor system | Parkinson disease D opamine (DA) neurons of the substantia nigra pars compacta (SNc) and ventral tegmental area (VTA) modulate motor behaviors, including locomotion, through ascending projections to the basal ganglia, the output of which projects to the mesencephalic locomotor region (MLR) (1-3), a brainstem region known to control locomotion in all vertebrate species tested to date (reviewed in ref. 4). DA is known to control the excitability of striatal cells, and a dysfunction of the ascending DA pathway to the striatum is considered to be the main cause for the motor deficits in Parkinson disease (1). However, there have been hints of descending DA projections that would be in position to directly modulate the MLR and hence locomotor activity. In monkeys, DA terminals of unknown origin were observed in the pedunculopontine nucleus (PPN) (5), considered part of the MLR (reviewed in ref. 4). In addition, there is an axonal projection from the SNc to the PPN in rats, but the transmitter system is unknown (6).We examined the DA system in a basal vertebrate, the lamprey, and found a previously unknown descending DA pathway from the posterior tuberculum (PT) to the MLR, which comprises the PPN and the laterodorsal tegmental nucleus (LDT) in lampreys (ref. 7; reviewed...
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