Cocaine Seeking And Taking Are Oppositely Regulated By Dopamine.

In some individuals, drug-associated cues subsume potent control of behavior, such as the elicitation of drug craving1-3 and automatized drug use4. The intensity of this cue reactivity is highly predictive of relapse and other clinical outcomes in substance use disorders5,6. It has been postulated that this cue reactivity is driven by augmentation of dopamine release over the course of chronic drug use7. Here we carried out longitudinal recording and manipulation of cue-evoked dopamine signaling across phases of substance-use related behavior in rats. We observed a subset of individuals that exhibited increased cue reactivity and escalated drug consumption, two cardinal features of substance use disorders. In these individuals, cue-evoked phasic dopamine release underwent diametrically opposed changes in amplitude, determined by the context in which the cue is presented. Dopamine evoked by non-contingent cue presentation increased over drug use, producing greater cue reactivity; whereas dopamine evoked by contingent cue presentation decreased over drug use, producing escalation of drug consumption. Therefore, despite being in opposite directions, these dopamine trajectories each promote core symptoms of substance use disorders.

Absence of NMDA receptors in dopamine neurons attenuates dopamine release but not conditioned approach during Pavlovian conditioning.

During Pavlovian conditioning, phasic dopamine (DA) responses emerge to reward-predictive stimuli as the subject learns to anticipate reward delivery. This observation has led to the hypothesis that phasic dopamine signaling is important for learning. To assess the ability of mice to develop anticipatory behavior and to characterize the contribution of dopamine, we used a food-reinforced Pavlovian conditioning paradigm. As mice learned the cue-reward association, they increased their head entries to the food receptacle in a pattern that was consistent with conditioned anticipatory behavior. D1-receptor knockout (D1R-KO) mice had impaired acquisition, and systemic administration of a D1R antagonist blocked both the acquisition and expression of conditioned approach in wild-type mice. To assess the specific contribution of phasic dopamine transmission, we tested mice lacking NMDA-type glutamate receptors (NMDARs) exclusively in dopamine neurons (NR1-KO mice). Surprisingly, NR1-KO mice learned at the same rate as their littermate controls. To evaluate the contribution of NMDARs to phasic dopamine release in this paradigm, we performed fast-scan cyclic voltammetry in the nucleus accumbens of awake mice. Despite having significantly attenuated phasic dopamine release following reward delivery, KO mice developed cue-evoked dopamine release at the same rate as controls. We conclude that NMDARs in dopamine neurons enhance but are not critical for phasic dopamine release to behaviorally relevant stimuli; furthermore, their contribution to phasic dopamine signaling is not necessary for the development of cue-evoked dopamine or anticipatory activity in a D1R-dependent Pavlovian conditioning paradigm.

Chronic microsensors for longitudinal, subsecond dopamine detection in behaving animals.

Neurotransmission operates on a millisecond timescale but is changed by normal experience or neuropathology over days to months. Despite the importance of long-term neurotransmitter dynamics, no technique exists to track these changes in a subject from day to day over extended periods of time. Here we describe and characterize a microsensor that can detect the neurotransmitter dopamine with subsecond temporal resolution over months in vivo in rats and mice.

Intraventricular insulin and leptin reverse place preference conditioned with high-fat diet in rats.

The authors hypothesized that insulin and leptin, hormones that convey metabolic and energy balance status to the central nervous system (CNS), decrease the reward value of food, as assessed by conditioned place preference (CPP). CPP to high-fat diet was blocked in ad-lib fed rats given intraventricular insulin or leptin throughout training and test or acutely before the test. Insulin or leptin given only during the training period did not block CPP. Thus, elevated insulin and leptin do not prevent learning a food's reward value, but instead block its retrieval. Food-restricted rats receiving cerebrospinal fluid, insulin, or leptin had comparable CPPs. Results indicate that the CNS roles of insulin and leptin may include processes involving memory and reward.

Inactivation of the DMH selectively inhibits the ACTH and corticosterone responses to hypoglycemia.

We have previously reported that repeated bouts of insulin-induced hypoglycemia (IIH) in the rat result in blunted activation of the paraventricular, arcuate, and dorsomedial hypothalamic (DMH) nuclei. Because DMH activation has been implicated in the sympathoadrenal and hypothalamic-pituitary-adrenal (HPA) responses to stressors, we hypothesized that its blunted activation may play a role in the impaired counterregulatory response that is also observed with repeated bouts of IIH. In the present study, we evaluated the role of normal DMH activation in the counterregulatory response to a single bout of IIH. Local infusion of lidocaine (n = 8) to inactivate the DMH during a 2-h bout of IIH resulted in a significant overall decrease of the ACTH response and a delay of onset of the corticosterone response compared with vehicle-infused controls (n = 9). We observed suppression of the ACTH response at time (t) = 90 and 120 min (50 +/- 12 and 63 +/- 6%, respectively, of control levels) and early suppression of the corticosterone response at t = 30 min (59 +/- 13% of the control level). The epinephrine, norepinephrine, and glucagon responses were not altered by DMH inactivation. Our finding suggests that DMH inactivation may play a specific role in decreasing the HPA axis response after repeated bouts of IIH.

Inactivation of the PVN during hypoglycemia partially simulates hypoglycemia-associated autonomic failure.

The anatomic connections of the paraventricular nucleus of the hypothalamus (PVN) are such that it is ideally situated to modulate and/or control autonomic responses to a variety of stressors, including hypoglycemia. In our experimental model of hypoglycemia-associated autonomic failure (HAAF), a syndrome in which the counterregulatory response to hypoglycemia is partially compromised via unknown mechanisms, activation of the PVN is blunted (15). We hypothesized that this blunted PVN activation during HAAF may be sufficient to cause the impaired counterregulatory response. To test this hypothesis, we anesthetized the PVN with lidocaine during insulin-induced hypoglycemia in rats and measured counterregulatory hormone levels. PVN inactivation decreased indexes of the sympathoadrenal response (plasma epinephrine and norepinephrine) and the hypothalamic-pituitary axis response (ACTH). Inactivation decreased the peak epinephrine response to hypoglycemia by almost half (-42 +/- 6% from control; P = 0.04) and the peak norepinephrine response by 34 +/- 5% (P = 0.01). The peak plasma ACTH levels attained were suppressed by 35 +/- 6% (P = 0.02). Adrenal corticosterone and pancreatic glucagon responses were not impaired. This pattern of neuroendocrine response is unlike that previously seen with our HAAF model. Control infusions of lidocaine >or=1 mm anterior or posterior to the PVN did not simulate this neuroendocrine pattern. Thus it appears that decreased PVN activation, as occurs with HAAF, may be involved in specific components of HAAF (i.e., blunting the sympathoadrenal and hypothalamic-pituitary-adrenocortical axis response), but not in others (i.e., blunting the glucagon response).

Food restriction modulates amphetamine-conditioned place preference and nucleus accumbens dopamine release in the rat.

Food restriction has been shown to increase self-administration of psychostimulants, including cocaine and amphetamine (AMPH). Consistent with this, food-restricted rats are more sensitized to the rewarding effects of cocaine as measured by conditioned place preference (CPP). This study investigated whether moderate food restriction in rats (15 g/day) results in an increased CPP, relative to ad libitum-fed controls, to a second psychostimulant, AMPH. Conditioning trials consisted of six alternating injections of i.p. AMPH (0.425-6.8 mg/kg) and i.p. saline, paired with distinct environments. On Day 7, a drug-free 20-min choice test for environment was carried out to assess CPP. 0.85 mg/kg AMPH significantly increased CPP in food-restricted vs. ad libitum-fed rats. At 1.7 and 3.4 mg/kg AMPH, food-restricted rats showed decreased CPP, but increased locomotor activity, relative to ad libitum fed controls. To evaluate whether an alteration in extracellular fluid DA levels in the nucleus accumbens (NAc) core could account for these behavioral alterations, DA release was measured by microdialysis. DA release to a single acute i.p. injection of either 0.85 or 1.7 mg/kg AMPH was comparable in food-restricted and ad libitum fed rats. However, ad libitum fed rats demonstrated conditioned DA release after an AMPH conditioning paradigm analogous to the CPP paradigm, whereas food-restricted rats demonstrated no conditioned DA release. In conclusion, altered DA release in the nucleus accumbens core is not a primary effect of moderate food restriction and cannot completely account for either the altered CPP behavior or enhanced locomotor activity observed in this study.